Plant for producing end products by cutting flat blocks, in particular flat and hollow waffle blocks

专利摘要:
Plant for producing end products by cutting flat blocks, in particular flat and hollow waffle blocks. The system (1) provides a main cutting station (3) in which a contour cutting device (12) cutting the blocks (B) by contour cuts is arranged transversely to a rectilinear transport path which extends in the longitudinal direction of the installation. A main conveying device (6) arranged along the transport path conveys the blocks (B) through the contour cutting device (12). This provides at least one contour cutting module (13) which is provided with at least one cutting tool (14a) which can be moved back and forth in the transverse direction of the installation and which generates a contour cut in the blocks (B) passing through the contour cutting device (12) in the longitudinal direction of the installation.
公开号:AT513260A4
申请号:T891/2012
申请日:2012-08-16
公开日:2014-03-15
发明作者:Norbert Drapela；Johannes Haas；Josef Haas；Stefan Jiraschek；Erich Koletnik
申请人:Haas Food Equipment Gmbh；
IPC主号:

专利说明:

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1 49 546 Pe / GA
Plant for producing end products by cutting flat blocks, in particular flat and hollow waffle blocks
The invention relates to a system for producing end products by cutting flat blocks, in particular of flat and hollow waffle blocks.
In known systems known as wafer block cutters, large rectangular rectangular wafers (for example L x B equal to 730 x 380 mm) are cut in two mutually perpendicular directions into many small wafers, most of which are bite size (for example L x B x H = 49 x 17) x 17 mm). The small waffle pieces are referred to in practice as cuts or whale cuts. Such systems are z. From documents AT 363 413 B, AT 412 250 B, GB 2 047 647 A, GB 2 348 356 A, GB 2 348 356 B, US 4,359,920 A, US 4,579,030 A, US 6,415,698 B1. In the known systems only rectangular end products can be produced, which are bounded by flat surfaces laterally.
The invention proposes a new plant for the production of end products, which result from the cutting of flat blocks, in particular of flat and hollow waffle blocks. In the plant, an input station for the blocks, at least one cutting station for cutting the blocks and an output station for the end products are provided. In the plant, a main cutting station is provided, in which a contour cutting device which cuts the blocks by contour cuts is arranged transversely to a rectilinear transport path which extends in the longitudinal direction of the installation through the main cutting station. Along the transport path a main conveyor is arranged, from which the blocks are conveyed along the transport path through the contour cutting device. The contour cutting device provides at least one contour cutting module which is provided with at least one cutting tool which can be moved back and forth in the transverse direction of the installation and which generates a contour cut in the blocks passing the contour cutting device in the longitudinal direction of the installation.
When generating the contour sections, those of the main conveyor f • · 2 * ♦ ·· ·· · «· M» * ··
49 546 Pe / GA generated longitudinal movements of the blocks combined with the transverse movements of the cutting tool generated by the contour cutting device. The combination of these movements is transmitted to the cutting tool of the contour cutting device and the cutting tool generates in the blocks contour cuts, the course of which results from this combination of motions.
In the system, the longitudinal movements of the blocks and the transverse movements of the cutting tool can be varied differently during the production of the contour cuts. Each change in one of these two movements results in a new course of the contour cut produced by the motion combination. Through different variations of these two movements contour cuts can be generated, which have more or less deviating sections from the longitudinal direction of the system. The sections may have a rectilinear contour or an arcuately curved contour or a free-formed contour. The sections can be arranged parallel to the longitudinal direction of the system or obliquely thereto.
The blocks are moved longitudinally through the contour cutter as it reciprocates its cutting tool or tools transversely. In this way, the new system can produce in the blocks very differently extending contour cuts. The contour sections are adapted with their differently extending sections to the outlines of the final products to be produced. The blocks are cut through the contour cuts and thereby divided into end products and any block remnants.
The plant according to the invention makes it possible to produce end products with very differently shaped outlines. From the mostly rectangular blocks end products can be cut out by the contour cuts, in which the outline z. B. a piece of cake, a circular disk, a flat figure, a 3-leaf clover, a 4-leaf clover or a symbol corresponds. In the system according to the invention also rectangular or fan-shaped end products can be produced and also end products, in which the outline has rectilinear, circular arc or wavy sections. • · · · «* * * * * * * * * * *» »» »» »» »» »» »» »» »» »» »» · · · · · · · ·. »» »·
3 49 546 Pe / GA
The contour cutting module! The contour cutting device may also have two or more cutting tools arranged side by side in the transverse direction, which cut out of a block two or more end products arranged side by side in the transverse direction.
According to a further feature of the invention, it can be provided that the contour cutting device has two contour cutting modules which are arranged one behind the other in the longitudinal direction of the installation and produce two different contour sections.
This design makes it possible to cut the blocks with two contour sections running differently within the blocks, wherein mutually opposite sections of the two contour sections complement each other to the outline of a complete end product. Each of the two contour cutting modules generates with its transversely moved cutting tool a half outline of the desired end product. The final products can be circular discs. The one contour cutting module generates with its cutting tool a contour cut in which a partial section corresponds to the left half of the circular outline. The other contour cutting module generates with its cutting tool a contour section in which a partial section corresponds to the right half of the circular outline. The end products can also be diamonds, in which case the contour cut produced by the one contour cutting module contains two rectilinear sections which correspond to the left half rhombus and the contour section produced by the second contour cutting module contains two rectilinear sections corresponding to the right half rhomb.
According to a further feature of the invention, it can be provided that the contour cutting device has three contour cutting modules which are arranged one behind the other in the longitudinal direction of the installation and produce three different contour sections.
This design makes it possible to produce end products in the system according to the invention, in which the outline consists of three sections which are each produced by one of the three contour cutting modules of the contour cutting device. It is possible to produce end products in which the outline of two slants obliquely ·· Μ · Μ • * ···· ·· Μ · Μ • * ···· 4
49 546 Pe / GA extending, rectilinear sections and an arcuate section consists.
According to the invention may further be provided in the contour cutting device following.
The contour cutting module may be a cutting head, which is movable in the transverse direction of the system and carries at least one vertically arranged cutting tool, which passes through the transport path of the blocks in the vertical direction.
In this embodiment, the cutting head is driven according to the course of the contour section in the transverse direction of the system back and forth, while a block is pushed in the longitudinal direction of the system by the contour cutting device. The cutting tool of the cutting head generates in the block a contour cut resulting from the combination of the longitudinal movements of the block with the transverse movements of the cutting head.
The cutting head can be arranged above the transport path of the blocks and carry at least one cutting tool which projects downwardly from it and passes through the transport path of the blocks arranged below it in the vertical direction.
The cutting head can be arranged below the transport path of the blocks and carry at least one cutting tool which projects upwardly from it and passes through the transport path of the blocks arranged above it in the vertical direction.
The cutting head may also have two or more laterally juxtaposed cutting tools that cut out of a block two or more transversely juxtaposed end products.
According to the invention, the contour cutting module may comprise a drive module which is connected to the cutting head and which generates during the contour cutting in the transverse direction of the system movements of the cutting head. φ φφ · φφ φ * φφ φφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφφ
5 49 546 Pe / GA
The drive module can be arranged above the cutting head or laterally next to the cutting head at a cutting head arranged above the transport path of the blocks. The drive module can be arranged below the cutting head or laterally next to the cutting head at a cutting head arranged below the transport path of the blocks.
The drive module connected to the cutting head may include a contour template, from which the movements of the cutting head extending in the transverse direction of the contour during the contour cutting are removed. This design allows a rapid change of the contour cut generated by the cutting head by replacing the contour template.
The drive module connected to the cutting head can be coupled to a copying device which decreases the contour of the end product from a contour template or an original model. In this embodiment, the course of the contour section determining, running in the transverse direction of the system movements of the cutting head can be removed directly from the contour template or from the original model.
In the drive module, a movement device which reciprocates the cutting head in the transverse direction of the installation can be provided, which is coupled to a drive motor, in which the generation of the movements of the cutting head in the transverse direction of the installation during the contour cutting is integrated into the control program of the drive motor.
As the drive module, a linear motor moving back and forth in the transverse direction of the cutting head can be provided, in which the generation of the movements of the cutting head during the contour cutting in the transverse direction is integrated into the control program of the linear motor.
According to the invention may further be provided in the contour cutting device following.
The contour cutting module can move in the transverse direction of the system • t t · · «Φ · I ·»
· # ······· I ······················
6 49 546 Pe / GA
Contour cutting frame having at least one vertically arranged cutting wire and a connected to the contour cutting frame drive module that generates the running during contour cutting in the transverse direction of the system movements of the contour cutting frame.
In this embodiment, the contour cutting frame is driven by the associated with him drive module the course of the contour section in the transverse direction of the system back and forth, while a block is pushed by the main conveyor in the longitudinal direction of the system by the contour cutting device. The contour cutting frame generates with its cutting wire in the block a contour cut, which results from the combination of running in the transverse direction of the system movements of the contour cutting frame with the running in the longitudinal direction of the system movements of the block.
The frame connected to the contour cutting and this in the transverse direction of the system moving back and forth drive module can be arranged above the contour cutting frame. The drive module can also be arranged below the Koniurschneidrahmen or laterally next to this.
The drive module connected to the contour cutting frame may include a contour template, from which the movements of the contour cutting frame extending in the transverse direction of the system during the contour cutting are removed. This design allows a rapid change of the contour cut generated by the contour cutting frame by replacing the contour template.
The drive module connected to the contour cutting frame can be coupled to a copying device which decreases the contour of the end product from a contour template or an original model. In this embodiment, the course of the contour section determining, running in the transverse direction of the system movements of the contour cutting frame can be removed directly from the contour template or from the original model.
In the drive module, a movement device coupled to a drive motor can be provided, which moves the contour cutting frame into .times..times..times..times..times..times..times..times..times..times. Fr x fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr fr the fr i fr "··
7 49 546 Pe / GA
Transverse direction of the system moves back and forth, and the generation of the running during contour cutting in the transverse direction of the system movements of the contour cutting frame can be integrated into the control program of the drive motor. The drive motor can be designed as a servomotor and the movement device can be designed as a ball screw spindle drive extending in the transverse direction of the installation.
The drive module may be a linear motor which moves the contour cutting frame in the transverse direction of the installation and in which the generation of the movements of the contour cutting frame during the contour cutting in the transverse direction of the installation is integrated into the control program of the linear motor.
The contour cutting frame may include two or more vertically disposed cutting wires spaced transversely of the installation.
According to a further feature of the invention can be provided that the contour cutting device provides at least one additional cutting module, which is provided with at least one stationary cutting tool, which generates in the blocks parallel to the longitudinal direction of the plant, straight cut. The additional cutting module may be provided with a stationary cutting frame containing at least one substantially vertical cutting wire.
According to the invention, the following may further be provided in the main cutting station.
The contour cutting device may be directly upstream of a rear support plate. About the rear platen, a transport path upwardly limiting, optionally adjustable in height, upper plate may be provided. This plate prevents the blocks lying on the rear platen from tipping as they are pushed by the contour cutter. At least one guide rail bordering the transport path can be provided over the rear support plate. Optionally, at least one guide strip can be arranged on both sides of the transport path. In this case, I ····································································································. μμ
8 49 546 Pe / GA
Training, the blocks can be supported laterally when passing the contour cutting device on a guide rail.
The contour cutting device may be directly downstream of a front support plate. About the front platen, a transport path upwardly limiting, optionally adjustable in height, upper plate may be provided. This plate prevents tipping of emerging from the contour cutting end products and block residues. At least one guide rail bordering the transport path can be provided above the front support plate. Optionally, at least one guide strip can be arranged on both sides of the transport path. In this embodiment, the blocks emerging from the contour cutting device can be laterally supported on a guide strip.
In a further embodiment of the invention, the following may be provided.
The system is provided with a linear transport path extending in the longitudinal direction of the installation, which extends from the input station through the main cutting station to the delivery station. The contour cutting device is arranged in the main cutting station transversely to the rectilinear transport path. The contour cutting device is arranged downstream of an endless product conveyor belt, which heats the end products and extends along the rectilinear transport path into the delivery station of the system.
This training provides an in-line version of the system according to the invention. Input station, main cutting station and output station are arranged in the longitudinal direction of the system in a straight line one behind the other. The blocks are conveyed along the rectilinear transport path from the input station to the output station. As the main cutting station passes, the blocks are cut by the contour cuts produced by the contour cutting device and cut into final products and block remnants. The end products and block residues are picked up by the product conveyor and transported to the output station. Due to the in-line design of the system, a relatively small overall width of the entire system can be realized, which in limited space at the site of i
♦ · »* ·» · • * ♦ ·· ·
* ♦ · «« · * * * M «· · · 49 546 Pe / GA
Plant is beneficial.
In the case of the in-line version of the system, the following may further be provided. About the product conveyor belt, the transport path upwardly limiting, optionally adjustable in height, upper plate may be provided. The upper plate prevents the end products and block remnants emerging from the contour cutter from tipping over. Over the product conveyor belt, at least one guide rail laterally delimiting the transport path can be provided. Optionally, at least one guide strip can be arranged on both sides of the transport path. In this embodiment, the blocks emerging from the contour cutting device can be laterally supported on a guide strip.
Even with the in-line version of the system, the contour cutting device may be located directly in front of a rear support plate. About the rear platen, a transport path of the blocks upwardly limiting, optionally be adjusted in height hold-down can be arranged. The hold-down prevents the blocks lying on the rear platen from tipping as they are pushed through the contour cutter. About the rear Aufiageplatte can be provided at least one laterally limiting the transport path guide rail. Optionally, at least one guide strip can be arranged on both sides of the transport path. In this embodiment, the blocks can be supported laterally when passing the contour cutting device on a guide rail.
In the in-line version of the plant, the main cutting station may be preceded by a first cutting station which cuts the blocks in the transverse direction of the plant, in which a first cutting device with knives movable back and forth across the transport path is provided.
In this embodiment, the blocks are conveyed along the linear transport path from the input station through the first cutting station to the main cutting station. In the first cutting station, those lying on the transport path,
V • · · # 4 · «· · t ♦ * · · · · · · f
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10 49 546 Pe / GA non-moving blocks are cut into strips in the transverse direction of the system by the blades of the first cutting device that can be moved back and forth transversely to the transport path.
This results in the transverse direction of the plant elongated strips, which are arranged one behind the other in the longitudinal direction of the system. The strips are transported along the straight-line transport path to the main cutting station. There, the strips are cut by the contour cuts generated by the contour cutting device. The course of the contour cuts is adapted to the outline of the end products to be produced. When cutting the strips, therefore, end products arise with an outline generated by the contour cuts. The end products and vulnerable cutting residues of the strips are removed along the straight transport path from the main cutting station. In this way, rectangular blocks can be cut into small end products, which can be arranged side by side and in several transverse rows one behind the other due to their small size within a rectangular block to several in a transverse row. The rectangular blocks are cut in the first cutting station in the transverse direction of the system in strips, each corresponding to a transverse row of end products. The strips are conveyed in the longitudinal direction of the plant through the main cutting station and there cut by the contour cuts produced by the contour cutting device in the individual end products.
According to the invention, the following may be provided in the main cutting station.
There may be provided a main cutting station in which a rear platen and a transport unit are upstream of the main conveyor of the contour cutting apparatus, the transport unit advancing the blocks along the rectilinear transport path in the longitudinal direction of the installation and a rearwardly displaceable along the rear platen in the longitudinal direction of the installation Block slide has.
In this embodiment, the blocks of the main cutting station are fed in the transverse direction of the system. In the main cutting station, the blocks rest on the rear platen between the rear block slide and the contour cutter. The blocks are driven by the transport unit with the aid of the rear block slide along the rectilinear transport path through the contour cutting device
'V • · · · ι · # * «« · · ι ·· * * · «« · · · · · * * * * < ························································
11 49 546 Pe / GA pushed. When passing the contour cutting device, the blocks are cut by the contour cuts generated by the contour cutting device. The end products are cut out of the blocks. The end products resulting from the cutting of the blocks have an outline generated by the contour cuts and corresponding to the course of the contour cuts. The end products exit the contour cutter at the front of the contour cutter.
According to the contour cutting device can be arranged downstream of an endless product conveyor belt, which receives the end products and extends into the output station of the system. In this embodiment, the end products emerging from the contour cutting device in the longitudinal direction of the installation are transported away in the longitudinal direction of the installation.
According to the invention, one of the contour cutting device downstream, front support plate and along the front Auflagepiatte be provided in the transverse direction of the system displaceable cross slide. In this embodiment, the end products exiting from the contour cutting device in the longitudinal direction of the installation are transported away in the transverse direction of the installation.
According to the invention, the following may be provided in the main cutting station.
The contour cutting device is disposed between a rear platen and a front platen. The main conveyor device provides a first transport unit upstream of the rear support plate and a second transport unit downstream of the front support plate. The first transport unit advances the blocks in the longitudinal direction of the plant and is provided with a rear block slide which is displaceable along the rear support plate in the longitudinal direction of the installation. The second transport unit moves the blocks backwards in the longitudinal direction of the installation and is provided with a front block slide which is displaceable along the front support plate in the longitudinal direction of the installation.
This design of the main cutting station makes it possible to produce contour cuts in the blocks, in which the blocks pass through the contour cutting device by .times..phi..sub.p .phi. Phi..phi..sub.phi. Phi. Phi. Phi. Phi. Phi. Phi. Phi. Phi • φ φφ φφ φ · φφφφ
12 49 546 Pe / GA the two transport units of the main conveyor can only be moved forwards or forwards and backwards in the longitudinal direction of the system. As the contour cutting device passes, the blocks are cut into the individual end products by at least one cutting tool of the contour cutting device moved back and forth in the transverse direction of the installation.
The main cutting station equipped with two transport units may be equipped with a contour cutting device having only a single contour cutting module having only a single cutting tool reciprocated by the contour cutting module in the transverse direction of the installation.
This configuration of the main cutting station makes it possible to cut end products out of the blocks with a single contour cut. The contour of the contour cut produced by the cutting tool of the contour cutting device is adapted to the outline of the final product to be produced. The cutting tool is moved back and forth by the contour cutting module in the transverse direction of the installation, while a block is moved forwards and backwards in the longitudinal direction of the installation by the two transport units of the main conveyor , One half of the contour cut is generated during the forward movement of the block, the other half during the backward movement of the block. The block is pushed forward from the rear platen to the front platen and from the front platen back to the rear platen. For generating a contour cut corresponding to the circumference of a circular disk, the block is moved only once forward and once backward. For generating a contour cut corresponding to the irregular circumference of a 4-leaf clover, the block is repeatedly advanced and retreated during the generation of the first half of the contour cut and also during the generation of the second half of the contour cut. After execution of the contour cut of the cut block including the final product on the rear platen. Feeds Removal of the cut blocks and the end products from the main cutting station may be provided along the rear platen in the transverse direction of the plant displaceable cross slide. In the case of the contour cutting device, the contour cutting module can have two or more cutting tools which are arranged side by side in the transverse direction of the installation and which are separated from the contour cutting module in »
13 49 546 Pe / GA
Transverse direction of the system are moved back and forth. The cutting tools cut from a block two or more in the transverse direction of the system juxtaposed end products such. B. 4-leaf clover or circular discs, from.
The main cutting station equipped with two transport units can be equipped with a contour cutting device which contains two contour cutting modules arranged one behind the other in the longitudinal direction of the installation, each having only a single cutting tool which is moved back and forth by the respective contour cutting module in the transverse direction of the installation.
This configuration of the main cutting station makes it possible to cut end products out of the blocks with two simultaneously executed contour cuts. The contour cuts are generated by the contour cutting modules, which are moved back and forth independently of each other in the transverse direction of the system. The two contour cutting modules generate two separate contour cuts in each block. Both contour cuts start at the front edge of the block and end at the back edge of the block. The two contour cuts contain sections which oppose each other within the block and complement each other to the complete outline of the final product. One contour cut creates the left half of the outline of the final product and the other contour cut creates the right half of the outline of the final product. When creating the outline of a circular disk of the block of the two transport units of the main conveyor in the longitudinal direction of the system is only moved forward. In forming the outline of a 4-leaf clover, the block is moved forward and backward in the longitudinal direction of the plant by the two transport units of the main conveyor. During the backward movement of the block those subsections of the cloverleaf outline are generated which have a reverse direction opposite to the feed direction of the blocks contour. After the execution of the two contour cuts of the cut block including the final product on the front platen. For the removal of the cut blocks and end products can be provided along the front support plate in the transverse direction of the system displaceable cross slide. «♦ · · · · · · · · · · # · · · * * ··············
14 49 546 Pe / GA
According to the invention, the following may be provided in the main conveyor.
In the first transport unit, a drive module connected to the rear block slide can be provided, which generates the movements of the rear block slide extending in the longitudinal direction of the system during the contour cut.
In the drive module of the first transport unit may be provided coupled to a drive motor movement means which moves the rear block slide in the longitudinal direction of the system back and forth, and the generation of the running during the contour section in the longitudinal direction of the system movements of the rear block slide can in the control program of the drive motor be integrated.
In the drive module of the first transport unit, the drive motor can be designed as a servomotor and a movement device can be provided, which is designed as a ball screw spin drive which extends in the longitudinal direction of the installation.
The first transport unit may be provided with a linear motor coupled to the rear block pusher, moving the rear block pusher in the longitudinal direction of the installation, in which the generation of the rear block pusher movements during the contour cutting in the longitudinal direction of the installation is integrated into the linear motor control program is.
In the second transport unit may be provided connected to the front block slider drive module which generates the running during the contour section in the longitudinal direction of the system movements of the front block slide.
In the drive module of the second transport unit may be provided coupled to a drive motor movement means which moves the front block slide in the longitudinal direction of the system back and forth, and the generation of the running during the contour section in the longitudinal direction of the system movements of the front block slide can in the control program of the drive motor be integrated.
In the drive module of the second transport unit can be designed as a servomotor
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15 49 546 Pe / GA
Drive motor and a movement device may be provided, which is designed as a ball screw spindle drive, which extends in the longitudinal direction of the system.
The second transport unit may be provided with a coupled to the front block slide, the front block slide in the longitudinal direction of the plant reciprocating linear motor, in which the generation of the running during the contour section in the longitudinal direction of the system movements of the front block slide integrated into the control program of the linear motor is.
In a further embodiment of the invention, the following may be provided.
According to the invention, a feed device feeding the blocks of the rear platen of the main cutting station in the transverse direction of the installation may be provided.
A first cutting station which cuts the blocks in the transverse direction of the installation may be provided in which the blocks are pushed in the transverse direction of the installation by means of a stationarily arranged cutting device. The first cutting station is upstream of the main cutting station in the transverse direction of the plant. The blocks leaving the first cutting station in the transverse direction of the installation are fed to the main cutting station in the transverse direction of the installation.
The first cutting station may be provided with a cutting device which is arranged transversely to the direction of movement of the blocks and extends in the longitudinal direction of the plant. The cutting device may have two or more, spaced apart in the longitudinal direction of the system cutting tools.
In the cutting device of the first cutting station may be provided as a cutting tool, a stationary arranged circular saw, which has a circular saw blade rotating about a horizontal axis.
The cutting device of the first cutting station can be provided with a stationary arranged cutting frame, which extends in the longitudinal direction of the plant 16 16 16
· # ΙΜΙ 49 546 Pe / GA and includes two or more substantially vertically disposed cutting wires.
The cutting device of the first cutting station can be provided with two longitudinally of the system at a greater distance from each other arranged cutting tools that cut in the cutting device passing blocks only in the transverse direction of the plant edges, or there cut a narrow edge strip from the block.
The cutting device of the first cutting station can be provided with a plurality of cutting tools arranged at regular intervals in the longitudinal direction of the installation. These cutting tools cut the blocks into individual strips, which extend in the transverse direction of the system and are arranged one behind the other in the longitudinal direction of the system.
The first cutting station can be provided with a cross-sectional movable block slide, which conveys lying on a horizontal transport plane blocks in the transverse direction of the system by the stationary arranged cutting device.
The invention will be explained in more detail with reference to some embodiments.
In the accompanying drawings, some embodiments are shown. The drawings show:
Fig. 1 shows a first variant of the plant in longitudinal section
FIG. 2 shows a plan view of the system of FIG. 1
Fig. 3 shows a first detail of the system of Fig. 1 in cross section
Fig. 4 shows a second detail of the system of Fig. 1 in cross section
Fig. 5 shows a second variant of the system in longitudinal section
Fig. 6 shows a third variant of the system in plan view
Fig. 7 shows a detail of the system of Fig. 6 in plan view
Fig. 8 shows a detail of the system of Fig. 6 in longitudinal section
Fig. 9 shows a detail of the system of Fig. 6 in cross-section • »··················································································· »♦ * i | ♦♦ ·· t «t ·· ·· ♦«
17 49 546 Pe / GA
Fig. 10 shows a detail of the system of Fig. 6 in cross section
Fig. 11 shows a fourth variant of the system in plan view
Fig. 12 shows a detail of the system of Fig. 11 in plan view
Fig. 13 shows a detail of the system of Fig. 11 in longitudinal section
Fig. 14 shows a detail of the system of Fig. 11 in cross section
Fig. 15 shows a detail of the system of Fig. 11 in cross section
Fig. 16 shows the plant of Fig. 11 in a 3-dimensional representation
Fig. 17 shows a detail of the system of Fig. 11 in elevation
Fig. 18 shows a detail of the system of Fig. 11 in elevation
Fig. 19 shows a fifth variant of the system in plan view
Fig. 20 shows a sixth plant variant in plan view
Fig. 21 shows a seventh plant variant in plan view
Fig. 22 shows details of the system of Fig. 21 in an enlarged view
Fig. 23 shows a variant of the main cutting station in plan view
Fig. 24 shows a variant of the main cutting station in plan view
Fig. 25 shows a sectioned block in plan view
Fig. 26 shows a sectioned block in plan view
Fig. 27 shows a variant of the contour cutting device in elevation
Fig. 28 shows a variant of the contour cutting device in elevation
Fig. 29 shows a variant of a cross-cutting station in plan view
Fig. 30 shows a variant of a cross-cutting station in longitudinal section
Fig. 31 shows a variant of a cross-cutting station in longitudinal section, and
Fig. 32 shows a variant of the main cutting station in longitudinal section
The invention provides a system in which flat blocks, such. B. flat or hollow waffle blocks are cut by contour cuts. By means of the contour cuts end products are cut out of the blocks, in which the shape of the contours is determined by the course of the contour cuts. The course of the contour cuts is adapted at least in sections to the outline contour of the end products.
The contour cuts are made by cutting tools, which are moved back and forth in the transverse direction of the system, while the blocks are moved in the longitudinal direction of the system. When generating the contour cuts, the transverse movements of the cutting tools are combined with the longitudinal movements of the blocks. The respective combination of the transverse movements of the cutting tools with the longitudinal movements of the blocks determines the course of the contour cuts produced by the cutting tools in the blocks. The transverse movements of the cutting tools are generated separately from the longitudinal movements of the blocks. The separate generation of the two movements allows the production of differently shaped contour sections. Contour cuts can be made which have rectilinear, circular arc or wavy sections. Contour cuts can be made which are adapted to the outline contours of differently designed end products. These end products can, for. B. have the shape of a pie slice, a circular disk, a 3-leaf clover, a 4-leaf clover.
The contour cuts are made in the main cutting station of the system. In the main cutting station, a straight-line transport path is provided for the blocks. The transport path extends in the longitudinal direction of the system. Along the transport path a main conveyor is arranged. This transports the blocks on the transport path in the longitudinal direction of the plant. Transverse to the transport path a contour cutting device is arranged. This provides at least one contour cutting module, which has at least one movable in the transverse direction of the system cutting tool.
The blocks are pushed by the main conveyor along the transport path through the contour cutting device. When passing the contour cutting device, the blocks are cut by the cutting tool moved back and forth in the transverse direction of the contour cutting module. The cutting tool moved back and forth in the transverse direction of the installation produces in a block moving in the longitudinal direction of the installation a section or contour section which has a profile which has been produced by the combination of the transverse movements of the cutting tool with the longitudinal movements of the block.
The blocks are fed to the plant at the input station and transported within the plant to the main cutting station. In the main cutting station, the blocks are cut into final products and any cutting residues. The final products and * * · Φ 1 Φ ·· φ · * • * Φ Φ Φ Φ Φ Μ »* Φ Φ Φ Φ · φ ·» φ • · * Φ * · Φ I φ φ ·· φ φ φ · Φ · Φ ΦΦΦΙ
19 49 546 Pe / GA
Cuttings are transported to the output station of the system and output there from the system.
The plant is intended for processing waffle blocks. Waffle blocks are rectangular, dimensionally stable, plate-like structures with a sandwich structure, in which wafer sheets and cream layers are arranged alternately one above the other. The top layer of the sandwich construction can be a waffle leaf or a cream layer. The waffle leaves are flat, or partially flat baked wafer sheets, which are provided on the top and bottom with a waffle pattern and have a crispy brittle consistency. The cream layers usually contain a whipped cream. Instead of the cream layers, other Füllmasseschichten may be included in the waffle blocks. In hollow waffle blocks, the wafer sheets or the respective outer wafer sheet may be partially arched out of the plane of the wafer sheet, resulting e.g. cream-filled hollow wafers can be produced.
Figs. 1 and 2 show schematically a plant 1 according to the invention in in-line design. The Appendix 1 provides a straight-line transport path. Along this, an input station 2, a main cutting station 3 and an output station 4 are arranged in a line one behind the other. The input station 2 and the output station 4 are shown in FIGS. 1 and 2 only schematically.
In the Appendix 1, a horizontal support plate 5 is provided, which is arranged on the underside of the transport path and extends from the input station 2 to the main cutting station 3. In Appendix 1, a main conveyor 6 is provided, which is arranged above the support plate 5 and extends along the transport path from the input station 2 to the main cutting station 3. The main conveyor 6 conveys the blocks lying on the platen 5 from the input station 2 to the main cutting station 3.
The main conveyor 6 is provided with arranged transversely to the longitudinal direction of the system printing plates 7. The pressure plates 7 are attached to two, extending in the longitudinal direction of the system, endless chains 8,9, in each of which the horizontal, lower chain center is arranged above the support plate 5. The
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20 49 546 Pe / GA
Printing plates 7 are each pivotable about a horizontal axis from an oblique rest position to a vertical working position. The waste into their vertical working position printing plates 7 are moved from the lower chain of the two endless chains chains 8, 9 in the longitudinal direction of the plant forward. In this case, each pressure plate 7 detects a lying on the support plate 5 block (B) at the rear end and pushes the block (B) to the front end of the support plate. 5
At the front end of the support plate 5, the transport path laterally limiting guide rails 10,11 are arranged above the support plate 5 Fig. 3 shows a lying on the Aufiageplatte 5 between the two guide rails 10,11 block (B).
In the main cutting station 3, a contour cutting device 12 is provided, which is arranged transversely to the transport path. The contour cutting device 12 is arranged after the support plate 5. It provides a contour cutting module 13 which has a contour cutting frame 14 which can be moved in the transverse direction of the installation and which contains at least one vertically arranged cutting wire 14a. The contour cutting frame 14 is reciprocated by the contour cutting module 13 in the transverse direction of the plant, while a block is conveyed by the main conveyor 6 in the longitudinal direction of the plant by the contour cutting device 12. The cutting wire 14a produces in the advancing block an outline cut in which the longitudinal movements of the block are combined with the transverse movements of the contour cutting frame 14. The combination of the two movements determines the course of the contour cut generated by the cutting wire 14a.
The blocks (B) are divided when passing the contour cutting device 12 by the contour cuts generated by the cutting wire 14a of the contour cutting module 13.
This produces the desired end products and any cutting residues. Both emerge at the front of the contour cutting device 12. The end products have an outline generated by the contour cuts.
The contour cutting device 12 is arranged downstream of an endless conveyor belt 15, which receives the end products and transported away from the plant 1. The conveyor belt 15 extends along the transport path to the output station 4. The conveyor belt 15 has a rear immediately behind the contour cutting device 12, rear • ····················································································· ···· · * ** · · · · · · ·········································
21 4Θ546 Pe / GA
End, which is provided with a knife edge deflection, which is formed by a thin guide roller 16. At the rear end of the conveyor belt 15, the conveying path 15 laterally limiting guide rails 17,18 are arranged. Fig. 4 shows a lying on the conveyor belt 15 between the guide rails 17,18 block. The block has passed the contour cutter 12 and has already been cut.
FIG. 5 shows a further system 20 according to the invention in in-line design. This comprises an input station 21, a stacking station 22, a first cutting station 23, a main cutting station 24 and an output station 25. The stations are arranged in the longitudinal direction of the system in a line one behind the other.
The blocks are fed to the system 20 in the input station 21. A feeding device 26 extends in the longitudinal direction of the system from the input station 21 through the stacking station 22 to a horizontal support plate 27 which extends in the longitudinal direction of the system through the first cutting station 23 into the main cutting station 24. The feed device 26 has juxtaposed transport belts 28, which extend in the longitudinal direction of the system from the input station 21 through the stacking station 22 to the horizontal support plate 27. The support plate 27 is attached to the top of a machine frame 29, which is supported by feet 30 on the bottom 31. The support plate 27 is provided in the rear half with longitudinal slots in which the front end portions 28a of the transport belt 28 are received. The feeder 26 conveys the blocks from the input station 21 through the stacking station 22 to the platen 27. On the rear half of the platen 27, the blocks are deposited by lowering the front end portions 28a of the transport belts 28.
In the stacking station 23, two or three blocks may be stacked to form a block stack. The block stack is placed on the conveyor belt 28. On the conveyor belt 28, the blocks or block stack are at a distance one behind the other. The blocks or block stacks are conveyed by the transport belts 28 of the feed device 26 to the support plate 27 and deposited on the rear half of the support plate 27. • ♦ · · · · · · · 4 «•« »·« «·« «« 4 4 · 4 · »f 4 · · < ··· · * Μ «ΦΜ
22 49 546 Pe / GA
The system 20 has a main conveyor 32, which is arranged above the support plate 27 and extends in the longitudinal direction of the system into the main cutting station 24. In the support frame 33 of the main conveyor 32, two endless transport chains 34 are arranged side by side, in which the horizontal, lower chain spans are arranged over the support plate 27. At the transport chains 34 arranged pressure plates 35 are arranged transversely to the longitudinal direction of the system. The pressure plates 35 are arranged at a distance one behind the other and pivotable from an oblique rest position into a vertical working position. The transport chains 34 convey the pressure plates 35 pivoted into their vertical working position along the upper side of the support plate 27 in the longitudinal direction of the installation to the front. Each pressure plate 35 detects a lying on the support plate 27 block or block stack on the rear end side and pushes it in the longitudinal direction of the system forward to the front end of the support plate 27th
Under the support frame 33 of the main conveyor 32, an elongate beam 36 is arranged, which extends in the longitudinal direction of the system into the main cutting station 24. The bar 36 serves as a hold-down for lying on the support plate 27 blocks or block stack. The distance of the beam 36 from the support plate 27 is adjustable. The beam 36 prevents tipping of lying on the platen 27 blocks or block stack while they are pushed by the main conveyor 32 on the platen 27 forward.
The first cutting station 23 of the system 20 is arranged in the region of the front half of the support plate 27. The first cutting station 23 provides a below the platen 27 arranged cutting device 37 which has in the transverse direction of the system rotating cutting blade 38 which project through the arranged in the platen 27 transverse slots 39 during the cutting process upwards and lying on the platen 27 blocks or Cut block pile. The cutting blades 38 are attached to two endless chains 40, which rotate in the transverse direction of the plant. The cutting blades 38 are lifted by the circulating chains 40 before the cutting process through the transverse slots 39 through the support plate 28 and lowered after the cutting operation under the support plate 28. The cutting blades 38 generate in the lying on the platen 27 blocks or block stack straight cuts that extend in the transverse direction of the system. The * * * φ ΦΦ ·· I I · φφφφφφφφφφφφφφφφφφφ ·φφφφφφφφφ * * φφφφφφφφφφφφ
23 49 546 Pe / GA straight cuts cut the blocks or block stacks into strips or strip stacks arranged one behind the other in the longitudinal direction of the system.
The main cutting station 24 is disposed downstream of the first cutting station 23. In the main cutting station 24, a contour cutting device 41 is provided, which cuts the strips or strip pile with the contour cuts generated by it, while they are pushed by the main conveyor 32 in the longitudinal direction of the system by the contour cutting device 41. The contour cutting device 41 is arranged transversely to the transport path. It provides a contour cutting module in which at least one vertically arranged cutting wire is arranged in a contour cutting frame movable in the transverse direction of the system, which is moved back and forth by the contour cutting module for generating the contour cuts in the transverse direction of the installation. The contour cuts cut the strips or last pile into the final products. The end products exit at the front of the contour cutter 41. The contour cutting device 41 is followed by a conveyor belt 42, which removes the end products from the system 20. The conveyor belt 42 extends into the output station 25. It has a rear end arranged immediately after the contour cutting device 41, which is provided with a knife edge deflection, which is formed by a thin deflection roller 43. The main cutting station 24 essentially corresponds to the main cutting station 3 of the system 1 of FIGS. 1 and 2.
FIGS. 6 to 10 show a further system 45 according to the invention. FIG. 6 shows the system 45 in plan view.
The installation 45 provides an input station 46, which is adjoined by a conveyor belt 47 extending in the longitudinal direction of the installation, which conveys the blocks into the interior of the installation 45. Inside the plant 45, a main cutting station 48 is provided, in which the blocks are cut and the end products are produced.
The final products are transferred to an output device 49. The dispensing device 49 extends in the transverse direction of the system from the main cutting station 48 to the output station 50. The dispensing station 50 is arranged at the front edge of the system 45 in FIG.
The main cutting station 48 provides a straightforward transport path for the blocks. * «
24 49 546 Pe / GA
The transport path extends in the longitudinal direction of the system. At the transport path a contour cutting device 51 which cuts the blocks by means of contour cuts is arranged. The contour cutting device 51 is arranged transversely to the transport path of the blocks. The contour cutting device 51 is a rear support plate 52 upstream in the longitudinal direction of the system and downstream of a front support plate 53 in the longitudinal direction of the system.
The contour cutting device 51 comprises two in the longitudinal direction of the system successively arranged contour cutting modules 51a, 51b with displaceable in the transverse direction of the plant contour cutting frame 54, 55. The rear contour cutting module 51 a of the front edge of the rear platen 52 is adjacent and provides a rear contour cutting frame 54, which is close the back of the contour cutting device 51 is arranged. The front contour cutting module 51b is disposed adjacent to the trailing edge of the front platen 53 and provides a front contour cutting frame 55 located near the front of the contour cutter 51. In both contour cutting modules 51a, 51b, the contour cutting frame 54, 55 is connected to a drive module 56, 57, which moves the contour cutting frame 54, 55 back and forth in the transverse direction of the system. The drive module 56, 57 includes a moving means, which is coupled to a drive motor and the contour cutting frame 54, 55 moves back and forth in the transverse direction of the system. FIG. 7 shows an embodiment of the drive modules 56, 57.
In the rear contour cutting module 51a, the rear contour cutting frame 54 is connected to a drive module 56 arranged below it. The drive module 56 provides a horizontal, transversely extending ball screw spindle drive 56a in which the ball screw nut is rigidly connected to the rear contour cutting frame 54. The ball screw is driven by a drive motor 56b via a toothed belt drive 56c. The ball screw is rotated by the drive motor 56b in a clockwise or counterclockwise direction to move the rear contour cutting frame 54 in the transverse direction of the system from left to right or from right to left.
In the rear contour cutting module 51a, below the rear ♦ ······················································································································································ · I ················································
25 49 546 Pe / GA
Contour cutting frame 54 may also be provided in the transverse direction of the system arranged chain drive, in which the circumferential in the transverse direction of the system, endless chain with the rear contour cutting frame 54 is mechanically coupled. The chain drive is driven by a drive motor. The endless chain of the chain drive is moved forward and backward in the transverse direction of the plant to move the rear contour cutting frame 54 in the transverse direction of the plant from left to right or from right to left.
In the front contour cutting module 51b, the front contour cutting frame 55 is connected to a drive module 57 arranged below it. The drive module 57 provides a horizontal, transversely extending ball screw spindle drive 57a, in which the ball screw nut is rigidly connected to the front contour cutting frame 55. The ball screw is driven by a drive motor 57b via a toothed belt drive 57c. The ball screw is rotated by the drive motor 57b clockwise or counterclockwise to move the front contour cutting frame 55 in the transverse direction of the system from left to right or from right to left.
In the case of the front contour cutting module 51b, a chain drive arranged in the transverse direction of the installation can also be provided below the front contour cutting frame 55, in which the endless chain circulating in the transverse direction of the installation is mechanically coupled to the front contour cutting frame 55. The chain drive is driven by a drive motor. The endless chain of the chain drive is moved forward and backward in the transverse direction of the plant to move the front contour cutting frame 55 in the transverse direction of the plant from left to right or from right to left.
In the main cutting station 48, a main conveyor 58 for the blocks is provided. The main conveyor device provides a transport unit 58a upstream of the contour cutting device 51. The transport unit 58a is provided with a rear block slider 59, which is displaceable along the transport path of the blocks in the longitudinal direction of the system. The block slide 59 is displaceable from the rear end position to a front end position along the transport path of the blocks, in which
• »« «· I * ♦♦ Μ ** ·«
26 49 546 Pe / GA rear end position of the block slide 59 of the rear support plate 52 is upstream. The block slider 59 is pushed by the transport unit 58a from the rear end position on the rear Aufiageplatte 52 across the front end position. Characterized a lying on the rear platen 52 block along the transport path of the blocks is pushed forward in the longitudinal direction of the system. The block is slid along the transport path of the blocks through the contour cutting device 51 onto the front support plate 53.
The block slide 59 of the transport unit 58a is connected to a drive module 60 which generates the longitudinal movements of the block slide 59. The drive module 60 is disposed below the transport path of the blocks. The drive module 60 provides a horizontal, in the longitudinal direction of the system extending ball screw drive 61. The ball screw spindle drive 61 includes a ball screw 61a and a ball screw nut 61b. The block slider 59 of the transport unit 58a is rigidly connected to the ball screw nut 61b. The ball screw spindle 61a is driven at the rear end by a drive motor 62 which is coupled to the ball screw 61a via a toothed belt drive 63. The ball screw 61a is rotated by the drive motor 62 clockwise or counterclockwise to move the block slider 59 in the longitudinal direction of the system forward or backward.
The block slide 59 of the transport unit 58a may also be mounted on a carriage which sits on rails extending in the longitudinal direction of the installation and which is displaceable along these rails in the longitudinal direction of the installation. As a drive module for the block slide 59 may be provided a chain drive, which is arranged in the longitudinal direction of the system and has a circumferential in the longitudinal direction of the system, endless chain which is mechanically coupled to the carriage. The chain drive is driven by a drive motor. The endless chain of the chain drive is moved in the longitudinal direction of the system forward and backward to move the block slider 59 of the transport unit 58 in the longitudinal direction of the system forward or backward.
The system 45, the blocks are fed to the input station 46 and stored there on the conveyor belt 47. · · «· · · · · • • • • • • • • • • • • • • • • •. * * * • • • • • • • * * * * * * * * * * *
27 49 546 Pe / GA
The conveyor belt 47 conveys the blocks into the interior of the plant 45. At the front end of the conveyor belt 47, a support plate 64 is arranged for the blocks. The support plate 64 is associated with a cross slide 65. The cross slide 65 is displaceable along the support plate 64 in the transverse direction of the system. The cross slide 65 is moved by a working cylinder 71 in the transverse direction of the system back and forth.
The lying on the support plate 64 blocks are pushed by the cross slide 65 in the transverse direction of the system on the rear support plate 52 of the main cutting station 48.
In the main cutting station 48, the blocks are pushed by the block slider 59 of the transport unit 58a along the transport path of the blocks in the longitudinal direction of the plant by the contour cutting device 51. The blocks pass through the two contour cutting modules of the contour cutting device 51, while in the latter the contour cutting frames 54, 55 are moved back and forth by the drive modules 56, 57 in the transverse direction of the installation. The rear contour cutting module 51a generates with the rear contour cutting frame 54 a first set of contour cuts in which the course is created by the combination of the longitudinal movements of the blocks with the transverse movements of the rear contour cutting frame 54. The front contour cutting module 51b generates, with the front contour cutting frame 55, a second family of contour cuts in which the profile is created by combining the longitudinal movements of the blocks with the transverse movements of the front contour cutting frame 55. The two sets of contour cuts contain opposing sections that complement each other to a complete outline of the final products to be produced.
FIG. 26 shows an example of a rectangular block cut by two sets of contour cuts, in which the opposite sections of the two sets of contour cuts complement each other to form complete circles. One set of contour sections is shown in solid lines, the second set of contour sections is shown in dotted lines. The block contains 15 pieces, designed as circular discs end products, which are arranged in the block in 3 longitudinal rows. The block contains the remainders left over when the block is cut, these are the two edge strips and the two between the two sidewalls. * · · * V + · t * · · f · + · + | | * · ·· * ·· ++ + · + +
28 49 546 Pe / GA 3 Longitudinal rows of end products arranged on remaining pieces.
When passing the two contour cutting modules, the blocks are cut by the two sets of contour cuts produced by the contour cutting modules into final products and block remnants. The end products and block remnants exit at the front side of the contour cutting device 51 in the longitudinal direction of the installation 45 and are received by the front support plate 53 of the main cutting station 48.
Fig. 8 shows a longitudinal section through the main cutting station 48. Fig. 8 shows a block (B) when passing the contour cutting device 51. The block (B) is located on the rear platen 52 of the main cutting station 48. The block is from the block slider 59 of the transport unit 58a pushed in the longitudinal direction of the system by the contour cutting device 51. A front portion of the block (B) has already passed the contour cutting frames 54, 55 of the two contour cutting modules 51a, 51b and lies on the front support plate 53 of the main cutting station 48.
In the main cutting station 48, an upper plate 66 is disposed over the rear platen 52. This serves as hold-down for lying on the rear platen 52 blocks. The distance of the upper plate 66 from the rear platen 52 is adjustable. The upper plate 66 prevents the blocks lying on the rear support plate 52 from tipping over as they are pushed by the block slider 59 of the transport unit 58 through the contour cutting device 51. About the rear support plate 52, the transport path of the blocks laterally limiting guide rails 67 are arranged. FIG. 10 shows a block lying on the rear support plate 52 between the two guide strips 67 in a vertical section along the line B-B in FIG. 8.
In the main cutting station 48, an upper plate 68 is disposed above the front platen 53. This serves as hold-down for the emerging from the contour cutting device 51, cut blocks. The distance of the upper plate 68 from the front support plate 53 is adjustable. The upper plate 68 prevents tipping of the cut-out blocks emerging from the contour cutter 51.
29 49 546 Pe / GA Over the front support plate 53, the transport path of the blocks laterally limiting guide rails 69 are arranged. FIG. 9 shows a sectioned block lying on the front support plate 53 between the two guide strips 69 in a vertical section along the line A-A in FIG. 8.
In the main cutting station 48, a cross slide 70 is provided in the front support plate 53, which pushes the end products and block remnants received from the front support plate 53 in the transverse direction of the installation from the main cutting station 48. The cross slide 70 is moved by a working cylinder 71 along the front support plate 53 in the transverse direction of the system back and forth. To the front support plate 53 of the main cutting station 48 includes in the transverse direction of the system, the output device 49, which extends into the dispensing station 50. In the output device 49, a horizontal support plate 72 is provided for the cut blocks. The cross slide 70 pushes a cut block after the other on the support plate 72. Each cut block pushes the lying before him on the support plate 72, cut block in the transverse direction of the system on. Along the support plate 72 lateral guide rails 73 are arranged, along which slide the cut blocks along. Instead of the support plate 72 may be provided a conveyor belt which extends in the transverse direction of the plant and the cut blocks to the discharge station 50 transported.
FIGS. 11-18 show a further system 75 according to the invention. FIG. 11 shows the system 75 in plan view. The installation 75 comprises an input station 76, a main cutting station 77 and an output station 78. The input station 76 is arranged on the right-hand edge of the installation 75 in FIG. The main cutting station 77 is disposed inside the plant 75. The dispensing station 78 is disposed on the front edge of the system 75 in FIG.
From the input station 76 performs a running in the longitudinal direction of the system conveyor belt 79 into the interior of the system 75. At the front end of the conveyor belt 79, a support plate 80 is arranged for the blocks. The support plate 80 is associated with a transverse slide 81. The cross slide 81 is displaceable along the support plate 80 in the transverse direction of the system. The cross slide 81 is moved by a working cylinder 82 in the transverse direction of the system back and forth.
The blocks are conveyed by the conveyor belt 79 in the longitudinal direction of the system to the support plate 80 and fed by the cross slide 81 in the transverse direction of the system of the main cutting station 77.
In the main cutting station 77, a rear platen 83, a contour cutter 84, and a front platen 85 are arranged in line with each other in the longitudinal direction of the plant. In the main cutting station 77, a straight-line transport path for the blocks is provided. The transport path extends in the longitudinal direction of the system from the rear support plate 83 through the contour cutting device 84 to the front support plate 85. Between the rear support plate 83 and the front support plate 85, the contour cutting device 84 is arranged. The contour cutting device 84 is arranged transversely to the transport path. Contour cutting device 84 includes two corrugated cutting modules 86, 87. These are provided in the longitudinal direction of the system one behind the other and can be moved in the transverse direction of the plant cutting tools. Each contour cutting module 86, 87 contains a contour cutting frame 86a, 87a movable in the transverse direction of the installation and a drive module 86c, 87c connected thereto, which generates the transverse movements of the contour cutting frame 86a, 87a. Each contour cutting frame 86a, 87a includes at least one vertical cutting wire 86b, 87b (Figures 17 and 18).
In the main cutting station 77, a main conveyor 88 is provided for the blocks. The main conveyor 88 extends longitudinally of the plant and includes a first transport unit 88a advancing the blocks and a second transport unit 88b moving the blocks rearwardly.
The first transport unit 88a is disposed in front of the rear support plate 83 in the longitudinal direction of the installation. The first transport unit 88a provides a rear block pusher 89 which is reciprocable along the rear platen 83 longitudinally of the plant. The first transport unit 88a provides a drive module 90 connected to the rear block spool 89 which generates the longitudinal movements of the rear block spool 89. The drive module 90 is arranged below the rectilinear transport path. The drive module 90 provides a ball screw spindle drive 91 arranged in the longitudinal direction of the system. The ball screw spindle drive 91 comprises a ball screw 91a and a shaft * 9 9 999 9
31 49 546 Pe / GA
Ball screw nut 91 b. The block slider 89 of the first transport unit 88a is rigidly connected to the ball screw nut 91b. The ball screw 91a is driven at the rear end by a drive motor 92 coupled to the ball screw 91a via a toothed belt drive 93. The ball screw 91a is rotated by the drive motor 92 in a clockwise or counterclockwise direction to move the block slider 89 forward and backward in the longitudinal direction of the plant.
The second transport unit 88b is arranged downstream of the front support plate 85 in the longitudinal direction of the system. The second transport unit 88b provides a front block slide 94 which is reciprocable along the front platen 85 longitudinally of the plant. The second transport unit 88b provides a drive module 95 connected to the front block spool 94, which generates the longitudinal movements of the front block spool 94. The drive module 95 is arranged below the rectilinear transport path. The drive module 95 provides a ball screw spindle drive 96 arranged longitudinally of the installation. The ball screw spindle drive 96 comprises a ball screw spindle 96a and a ball screw spindle nut 96b. The block slider 94 of the second transport unit 88 is rigidly connected to the ball screw spindle nut 96b. The ball screw 96a is driven at the rear end by a drive motor 97 which is coupled to the ball screw 96a via a toothed belt drive 98. The Kugelgewindespindei 96 a is rotated by the drive motor 97 in a clockwise or counterclockwise direction to move the block slide 94 in the longitudinal direction of the system forward or backward.
In the system 75, the blocks are fed from the cross slide 81 associated with the support plate 80 in the transverse direction of the system of the main cutting station 77 and pushed onto the rear support plate 83 of the main cutting station 77.
In the main cutting station 77, the blocks lying on the rear support plate 83 are detected by the two transport units 88a, 88b of the main conveyor 88. The two transport units 88a, 88b push the blocks along the rectilinear transport path into the contour cutting device 84 and therethrough on the front support plate 85 of the main cutting station 77. As the blocks pass the Koniurschneidvorrichtung 84, the two Konturschneidmodule 86,87 are operated at this. The two contour cutting modules 86, 87 move their cutting contour frames 86a, 87a, which are provided with cutting wires 86b, 87b, back and forth independently of one another in the transverse direction of the installation. At the same time, the blocks are moved by the two transport units 88a, 88b in the longitudinal direction of the system only forward or forward and backward.
The rear contour cutting module 86 generates in the blocks contour sections, the course of which results from the combination of the transverse movements of the contour cutting frame 86a of the rear contour cutting module 86 with the longitudinal movements of the blocks. The contour cuts produced in the blocks by the front contour cutting module 87 have a different course. This results from the combination of the transverse movements generated by the contour cutting frame 87a of the front contour cutting module 87 with the longitudinal movements of the blocks. The contour cuts generated by the two contour cutting modules 86, 87 each contain subsections adapted to the contours of the end products to be produced. Opposing sections of the two contour sections complement each other to the outline of an end product.
The two contour cutting modules 86, 87, with their cutting wires 86b, 87b moved back and forth in the transverse direction of the installation, produce two differently extending contour cuts in the blocks moved forward only by the transport units 88a, 88b in the longitudinal direction of the installation, in which there is no section has a contrary to the feed direction of the blocks backward contour.
The two contour cutting modules 86, 87, with their cutting wires 86b, 87b moved back and forth in the transverse direction of the installation, produce two differently extending contour cuts in the blocks moved forwards and backwards by the transport units 88a, 88b in the longitudinal direction of the installation, in which there is at least one partial section , which has a reverse direction of the feed direction of the blocks backward contour. The contour cuts produced by the contour cutting modules 86, 87 in the blocks moving forwards and backwards may also have two or more subsections, each of which has a contour running backwards against the feed direction of the blocks. The two contour cutting modules 86, 87 • * φ φ · · · φφ ΦΦΦ ·
33 49 546 Pe / GA can create contour cuts in the forward and backward moving blocks that are fitted with their sections to the irregular outline of a 4-leaf clover, with the rear contour cutting module 86 creating a contour cut whose course is the irregular outline of the left clover leaf corresponds, and the front contour cutting module 87 generates a contour section, the course of which corresponds to the irregular outline of the right cloverleaf half.
In the main cutting station 77, the cut blocks exiting from the contour cutter 84 at the front are picked up by the front support plate 85. The front support plate 85 is associated with a cross slide 99 which is reciprocated by a power cylinder 100 along the front support plate 85 in the transverse direction of the system. The cut blocks lying on the front support plate 85 are pushed out of the main cutting station 77 by the cross slide 99 in the transverse direction of the installation. To the front support plate 85 of the main cutting station 77 includes in the transverse direction of the system an output device 101, which extends into the output station 78. In the output device 101, a horizontal support plate 102 is provided for the cut blocks. The cross slide 99 pushes a cut block after the other on the support plate 102. Each cut block pushes the lying before him on the support plate 102, cut block in the transverse direction of the system on. Along the support plate 102 lateral guide rails 103 are arranged, along which slide the cut blocks along. Instead of the support plate 102 may be provided a conveyor belt which extends in the transverse direction of the plant and the cut blocks to the discharge station 78 transported.
In Fig. 12, the main conveyor 88 and the contour cutting device 84 of the main cutting station 77 of the system 75 are shown. In the middle of Fig. 12, the contour cutting device 84 is shown. The rear contour cutting module 86 is right in FIG. 12 and the front contour cutting module 87 is shown on the left in FIG. FIG. 12 shows, from the rear contour cutting module 86, the contour cutting frame 86a arranged transversely to the transport path of the blocks and the drive module 86c generating the transverse movements of the contour cutting frame 86a.
The drive module 86c is identical to the drive module 56, which is provided at the rear contour cutting module of the contour cutting device 51 of the system 45. * * · «·· 4 4 Φ i ·
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34 49 546 Pe / GA
FIG. 12 shows, from the front contour cutting module 87, the contour cutting frame 87a arranged transversely to the transport path of the blocks, and the drive module 87c generating the transverse movements of the contour cutting frame 87a. The drive module 87c is identical to the drive module 57, which is provided in the front contour cutting module of the contour cutting device 51 of the system 45.
12 shows the two transport units 88a and 88b of the main conveyor 88 arranged along the transport path of the blocks. The first transport unit 88a upstream of the contour cutting device 84 is shown on the right in FIG. The contour of the contour cutting device 84 downstream, second transport unit 88b is dargestelit left in Fig. 12. 12 shows, from the first transport unit 88a, the rear block slide 89 and the drive module 90 with the ball screw spindle drive 91 together with the drive motor 92 arranged in the longitudinal direction of the installation 75. FIG. 12 shows the front block slide 94 and the drive module 95 of the second transport unit 88b with the ball screw spindle drive 96, which is arranged in the longitudinal direction of the installation, together with the drive motor 97.
13 shows a longitudinal section through the main cutting station 77. FIG. 13 shows a block (B) pushed into the contour cutting device 84 one piece at a time. The block (B) lies with its larger part on the rear support plate 83 and in front of the rear block slide 89 of the first transport unit 88a. A small, already cut-up part of the block (B) rests on the front support plate 85 and in front of the front block slide 94 of the second transport unit 88b. Above the rear platen 83, an upper plate 83a is disposed. This serves as a hold-down for lying on the rear support plate 83 block. About the rear support plate 83, the transport path of the blocks laterally limiting guide rails 83b are arranged. Fig. 14 shows a block lying on the rear support plate 83 between the two guide rails 83b in a vertical section along the line A-A in Fig. 13. Above the front support plate 85, an upper plate 85a is arranged. This serves as hold-down for the emerging from the contour cutting device 84, cut blocks. About the front support plate 85, the transport path of
Blocks laterally limiting guide strips 85b arranged. FIG. 15 shows a sectioned block lying on the front support plate 85 between the two guide strips 85b in a vertical section along the line B-B in FIG. 13.
16 shows an oblique view of the system 75 without the upper plate 83a arranged above the rear support plate 83 and without the upper plate 85a arranged above the front support plate 85. FIG. 16 shows the vertical walls 104 arranged along the rear side of the installation 75, which delimit the interior of the installation 75 to the outside. At the left in Fig. 16 edge of the system 75 belonging to the system 75 control cabinet 105 is shown.
FIGS. 17 and 18 show the contour cutting modules 87 of the contour cutting device 84.
17 shows the front contour cutting module 87 with the contour cutting frame 87a that can be moved in the transverse direction of the installation and with the drive module 87c that generates the transverse movements of the contour cutting frame 87a. Fig. 17 shows the contour cutting frame 87a in its left end position. The contour cutting frame 87a includes an elongate, rectangular window. In the left half of the window four vertical cutting wires 87b are arranged at a distance next to each other. The right half of the window is free of cutting wires and serves for the unhindered passage of the blocks. The drive module 87c is provided with a ball screw drive driven by a drive motor 87d via a toothed belt drive 87e, which extends in the transverse direction of the installation and whose ball screw spindle nut is rigidly connected to the contour cutting frame 87a. In FIG. 17, only the components arranged at the right end of the front contour cutting module 87, drive motor 87d and toothed belt drive 87e, can be seen by the drive module 87c.
18 shows the rear contour cutting module 86 with the contour cutting frame 86a that can be moved in the transverse direction of the installation and the drive module 86c that generates the transverse movements of the contour cutting frame 86a. Fig. 18 shows the contour cutting frame 86a in its right end position. The contour cutting frame 86a includes an elongated rectangular window. In the left half of the window, four vertical cutting wires 86b are spaced apart. The ft ft ft ft ft ft ft ft ft ft ft ft ft ft ftftftftft ftftftft
36 49 546 Pe / GA right half of the window is free of cutting wires and serves for the unhindered passage of the blocks. The drive module 86c is provided with a ball screw drive driven by a drive motor 86d via a toothed belt drive 86e, which extends in the transverse direction of the installation and whose ball screw spindle nut is rigidly connected to the contour cutting frame 86a. In FIG. 18, only the components arranged at the right end of the front contour cutting module 86, drive motor 86d and toothed belt drive 86e, can be seen by the drive module 86c.
19 shows a plan view of a further system 106 according to the invention. In the system 106, the end products are cut out of the blocks with a single contour cut.
The installation 106 provides an input station 107 arranged at the edge of the installation 106 and a main cutting station 108 arranged inside the installation 106.
In the main cutting station 108, a rear platen 109, a contour cutter 110, and a front platen 111 are arranged along a linear transport path in the longitudinal direction of the plant 106 one behind the other. The contour cutting device 110 is arranged transversely to the transport path. Contour cutting device 110 includes at least one contour cutting module that has at least one cutting tool and reciprocates it in the transverse direction of the system. Along the transport path a main conveyor 112 is arranged. This provides a front of the contour cutting device 110, first transport unit 113 and a contour cutting device 110 downstream, second transport unit 114 before. The blocks are reciprocated in the main cutting station 108 by the two transport units 113 and 114 in the longitudinal direction of the installation, while the contour cutting module of the contour cutting apparatus 110 moves its cutting tool back and forth in the transverse direction of the installation.
The contour cutter 110 generates only a single contour cut in each block. One half of the contour cut is generated during the forward movement of the block, the other half during the backward movement of the block. The ···························································
• I ···························· »
37 49 546 Pe / GA
Block is pushed forward from the rear platen 109 onto the front platen 111 and from the front platen 111 rearwardly onto the rear platen 109. For creating a contour cut corresponding to the circumference of a circular disk, the block is advanced once and once only moves backwards. For generating a contour cut corresponding to the irregular circumference of a 4-leaf clover, the block is repeatedly advanced and retreated during the generation of the first half of the contour cut and also during the generation of the second half of the contour cut.
After the execution of the contour section of the cut block including the final product on the rear platen 109. In the system 106 is provided a subsequent to the rear platen 109 in the transverse direction of the plant output device 115 which extends into the output station 116 and the cut blocks along with the end products from the main cutting station 108 to the output station 116.
The contour cutting module of the contour cutting apparatus 110 may also have three or four cutting wires spaced apart from each other in the transverse direction of the installation, which are moved back and forth by the contour cutting module in the transverse direction of the installation, while the blocks are moved forward and backward by the transport units 113, 114 along the rectilinear transport path , In this way, in each block three or who arranged in the transverse direction of the system side by side, designed as a flat plate end products. The cut blocks, each containing three or four in the transverse direction of the system adjacent end products are located on the rear platen 109 and are transported away from there in the transverse direction of the plant.
FIG. 20 shows a plan view of a further system 117 according to the invention. The input station 118 and the output station 119 are arranged on mutually opposite side edges of the system 117. The main cutting station 120 is disposed inside the plant 117. The main cutting station 120 corresponds in its structural design of the main cutting station 48 of the system 45 (Fig. 6-10).
In the plant 117, the blocks of the main cutting station 120 are transversely • t · φ · * · * · ψ ····························································································. | | ΦΦ »Φ Φ · φ ·· φφφφ
38 49 546 Pe / GA supplied to the system. A conveyor belt 121 leads from the input station 118 in the transverse direction of the plant into the plant to the main cutting station 120. The conveyor belt 121 pushes the blocks in the transverse direction of the plant on the rear platen 120a of the main cutting station 120. In the main cutting station 120, the blocks from the block slide 122 of Main conveyor in the longitudinal direction of the system by the contour cutting device 123 of the main cutting station 120 pushed through to the front support plate 124 of the main cutting station 120. The blocks are cut when passing the contour cutting device 123 by the contour cuts generated by the contour cutting device 123. The resulting end products and cutting residues are taken as a cut blocks of the front platen 124.
In the plant 117, there is provided a discrete block discharge means 125, which is connected to the front support plate 124 of the main cutting station 120 in the transverse direction of the plant. The output device 125 extends in the transverse direction of the system to the output station 119. The output device 125 corresponds in its structural design of the output device 49 of the system 45 (Fig. 6-10).
FIG. 21 shows another system 126 according to the invention in plan view. The installation 126 comprises an input station 127 arranged on the left-hand side edge, a first cutting station 128 extending in the transverse direction of the installation, a main cutting station 129 extending in the longitudinal direction of the installation and an output station 130 arranged on the right-hand side edge.
The input station 127 is disposed adjacent to the first cutting station 128. This provides a straightforward, first transport path. The first transport path extends in the transverse direction of the system. A conveyor for the blocks is disposed in the first cutting station 128. The conveyor provides a transport unit which has a first block slide 131 which is displaceable along the first transport path. For better clarity, only the first block slide 131 is shown in Fig. 21 of the conveyor. Fig. 21 shows the first block slide 131 in its rear end position and in a front working position.
39 49 546 Pe / GA
The first block slide 131 pushes the blocks along the first transport path through a first cutting device 132 arranged transversely to the first transport path. The first cutting device 132 includes a stationary, first cutting frame 133, which is arranged transversely to the first transport path and contains ten cutting wires Distance are arranged side by side. The first cutting frame 133 cuts the blocks (B) advanced along the first conveying path into nine strips (L) arranged side by side. The first cutting frame 133 produces straight cuts extending transversely of the plant. The blocks (B) cut into strips (L) are pushed out of the first cutting station 128 in the transverse direction of the installation and pushed into the main cutting station 129.
The main cutting station 129 provides a straight, second transport path. The second transport path extends in the longitudinal direction of the installation 126. A main conveyor device is provided in the main cutting station 129, which has a second block slide 134 displaceable along the second transport path. For better clarity, only the second block slide 134 is shown in Fig. 21 of the main conveyor. Fig. 21 shows the second block slide 134 in its rear end position and in a front operating position.
The second block slider 134 pushes the blocks cut into strips (L) along the second transport path by a contour cutting device 135 arranged transversely to the second transport path. The contour cutting device 135 provides a contour cutting module 136, which has transverse to the second transport path reciprocating cutting tools that produce in the strips (L) contour cuts whose course from the combination of the forward movements of the strips (L) with the transverse movements of the cutting tools of the contour cutting module 136 is created. The strips (L) are cut by the contour cuts produced by the contour cutting module 136. This produces the desired end products. These are picked up by a support plate 137 arranged downstream of the contour cutting device 135. The support plate 137 extends along the second transport path to the output station 130. Instead of the support plate 137 may also be provided an endless conveyor belt which receives the end products and transported out of the plant 126 addition. • * · I ··· * · * «· · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · ··· »
40 49 546 Pe / GA
Contour cutting module 136 provides an elongated contour cutting frame 138 which is disposed transversely of the second transport path and includes eight cutting wires 139 spaced apart along contour cutting frame 138. The contour cutting module 136 provides a drive module 140 that is connected to the contour cutting frame 138 and reciprocates the contour cutting frame 138 transversely of the second transport path while the blocks cut into slats (L) are slid along the second transport path by a contour cutter 135. The contour cutting frame 138 generates eight contour cuts with its eight cutting wires 139 in the strips (L). The profile of the contour sections is produced by the combination of the forward movements of the strips (L) with the transverse movements of the contour cutting frame 138. FIG. 21 shows contour sections with a wave-shaped course. The associated transverse movements of the contour cutting frame 138 are generated by the drive module 140, which is shown in Fig. 22 in an enlarged scale.
The drive module 140 provides a first assembly connected to the main conveyor and a second assembly disposed in the contour cutter 135.
The first module provides a rod 141 arranged along the second transport path, which carries a contour template 142 projecting laterally from it. The contour template 142 is formed as a horizontally arranged, flat plate having a longitudinal edge 143, the course of which corresponds to the contour to be produced. Rod 141 and contour template 142 are arranged below the second transport path. The rod 141 is rigidly connected to the block slider 134 of the main conveyor and is reciprocated therefrom in the longitudinal direction of the second conveying path. The rod 141 and the contour template 142 extend in the longitudinal direction of the second transport path from the block slider 134 forward to the contour cutting device 135 and beyond this one piece in the longitudinal direction.
The second subassembly provides a guide device for the rod 141 arranged in the frame 144 of the contour cutting device 135. The guide device comprises guide rollers 145 which are arranged on both sides of the rod 141 and which are arranged one behind the other in the longitudinal direction of the second transport track and are mounted in the frame t * * * * * * * * * * 4 * ***** *** * * * * * · · I · · · · · · · · · * * · · ««!
41 49 546 Pe / GA 144 of the contour cutting device 135 are rotatably mounted. The second module provides a roller 146 which is rotatably mounted on the contour cutting frame 138 and bears against the contour projection 142. The roller 146 is attached to the arranged below the second transport path, the lower frame portion 138 a of the contour cutting frame 138. The contour cutting frame 138 is held by a spring, not shown, with the roller 146 in contact with the contour template 142.
The contour cutting frame 138 is arranged transversely to the second transport path and guided with its lower frame part 138a in the frame 144 of the contour cutting device 135 transversely to the second transport path slidably. The guide means for the contour cutting frame 138 comprises on both sides of the lower frame part 138a arranged guide rollers 147 which are arranged along the lower frame part 138a at a distance from each other and rotatably supported in the frame 144 of the contour cutting device 135.
In the contour cutting module 136, the drive module 140 derives the transverse movements of the contour cutting frame 138 from the forward movement of the block slide 134 of the main conveyor. With the forward movement of the block slide 134, the rod 141 is pushed in the longitudinal direction of the second transport path through the arranged in the frame 144 of the contour cutting device 135, provided with the guide rollers 145 guide means. The attached to the rod 141 contour template 142 is pushed in the longitudinal direction of the second transport path on the attached to the contour cutting frame 138 Roile 146 along. The roller 146 is reciprocated in the transverse direction by the forwardly moving contour template 142. With the roller 146, the entire contour cutting frame 138 is moved with its cutting wires 139 in the transverse direction back and forth. The transverse movements of the cutting wires 139 follow the course of the contour template 142. The contour cuts generated by the cutting wires 139 in the strips (L) result in a contour which coincides with the contour of the contour template 142.
The drive module shown in FIG. 22 generates contour sections with a wave-shaped course, which is predetermined by the contour template 142. In order to change the contour of the contour cuts, one needs only the rod 141 with the contour template 142 against another rod with another contour template 42% ·······························································.
49 546 Pe / GA.
Fig. 23 shows a main cutting station 148 of another plant according to the invention. The main cutting station 148 provides a straightforward transport path for the blocks. Along the transport path, a rear support plate 149, a contour cutting device 150 arranged transversely to the transport path, and a front support plate 151 are arranged one behind the other. A block slider 152a of the main conveyor 152 pushes the blocks along the transport path from the rear platen 149 through the contour cutter 150 to the front platen 151. The blocks consist of two halves arranged one behind the other. The contour cutting device 150 provides five successively arranged cutting modules 153, 154, 155, 156 and 157. In the blocks passing through the contour cutting device 150, the five cutting modules produce five differently extending cuts S1, S2, S3, S4 and S5. The five cuts divide the two block halves into eight end products and eight edge pieces. The final products correspond to a divided into eight parts, circular cake.
The first cutting module 153 generates in the two block halves a straight cut S1, which is arranged parallel to the longitudinal direction of the transport path. The first cutting module 153 provides a stationary cutting frame arranged transversely to the transport path. The cutting frame includes a vertical cutting wire D1 disposed in the center of the transport path.
The second cutting module 154 is designed as a contour cutting module. It provides a transverse to the transport path arranged cutting frame, which is provided with a cutting wire D2. The cutting frame is moved transversely to the transport path from left to right by a drive module, not shown in FIG. 23, while the two block halves are pushed longitudinally through the contour cutting device 150. The cutting frame generates with its cutting wire D2 in the two block halves a left to right oblique contour cut S2.
The third cutting module 155 is designed as a contour cutting module. It provides a transverse to the transport path arranged cutting frame, which is provided with a cutting wire D3. The cutting frame is of a not shown in Fig. 23
Drive module transversely to the transport path moves from right to left, while the two block halves are pushed in the longitudinal direction by the contour cutting device 150. The cutting frame generates with its cutting wire D3 in the two block halves from right to left obliquely extending contour section S3.
The fourth cutting module 156 is designed as a contour cutting module. It provides a transversely arranged to the transport path cutting frame, which is provided with a cutting wire D4. The cutting wire D4 is arranged at the beginning of the contour cut in the middle of the transport path. The cutting frame is pushed by a drive module not shown in FIG. 23 when passing the first half of the block transversely to the transport path to the right and when passing the second half of the block transversely to the transport path to the left. At the end of the contour cut, the cutting wire D4 is again arranged in the middle of the transport path. The cutting frame generates with its cutting wire D4 a contour cut, which corresponds to a semicircle and forms the left half of the circular outline in the circular cake.
The fifth cutting module 157 is designed as a contour cutting module. It provides a transverse to the transport path arranged cutting frame, which is provided with a cutting wire D5. The cutting wire D5 is arranged at the beginning of the contour cut in the middle of the transport path. The cutting frame is pushed by a drive module not shown in FIG. 23 when passing the first block half transverse to the transport path to the left and when passing the second block half transversely to the transport path to the right. At the end of the contour cut, the cutting wire D5 is again arranged in the middle of the transport path. The cutting frame generates with its cutting wire D5 an outline cut, which corresponds to a semicircle and forms the right half of the circular outline in the circular cake.
Fig. 24 shows another embodiment of the main cutting station 158. This provides a straight-line transport path for the blocks. Along the transport path, a rear support plate 159, a contour cutting device 160 and a front support plate 161 are arranged one behind the other. • · · ········································································································ «
44 49 546 Pe / GA
The contour cutting device 160 is arranged transversely to the transport path and provides two contour cutting module 162,163, which are arranged one behind the other along the transport path. The rear contour cutting module 162 has a contour cutting frame arranged transversely to the transport path with a vertically arranged cutting wire D2. The contour cutting frame is moved back and forth by a drive module, which is arranged below the contour cutting frame and not shown in FIG. 24, transversely to the transport path. The front contour cutting module 163 has a contour cutting frame arranged transversely to the transport path with a vertically arranged cutting wire D3. The contour cutting frame is moved back and forth by a drive module, which is arranged below the contour cutting frame and not shown in FIG. 24, transversely to the transport path.
Along the transport path, a main conveyor is arranged, which provides a the blocks along the transport path forward moving, first transport unit and the blocks along the transport path rearwardly moving, second transport unit. The first transport unit is disposed in front of the contour cutting device 160 and provides a rear block slide 164 which is movable back and forth along the rear support plate 159 in the longitudinal direction of the transport path. The second transport unit is arranged downstream of the contour cutting device 160 and provides a front block slide 165 which can be moved back and forth along the front support plate 161 in the longitudinal direction of the transport path. For better clarity, only the block slides 164 and 165 of the two transport units of the main conveyor are shown in FIG.
In the main cutting station 158, a heart-shaped end product is cut out of a square block (B). In Fig. 24, the block (B) when passing the contour cutting device 160 is shown. The block (B) lies with its rear third on the rear platen 159 and with its two front thirds on the front platen 161. Behind the block (B), the block slide 164 of the first transport unit of the main conveyor is arranged. Before the block (B), the block slide 165 of the second transport unit of the main conveyor is arranged. The block slider 164 of the first transport unit pushes the block (B) forward from the rear platen 159 onto the front platen 161. The second transport unit block slider 165 pushes the block (B) from the front side. · · · · · · · · · · · · · · · · · · · · · · ·
45 49 546 Pe / GA
Platen 161 to the rear on the rear platen 159th
When passing the contour cutting device 160, the contour cutting frames of the two contour cutting modules 162,163 are moved back and forth in the transverse direction. The rear contour cutting module 162 generates with its cutting wire D2 a contour cut S2 that runs along the right half of the end product outline. The front contour cutting module 163 generates with its cutting wire D3 a contour cut S3 running along the left half of the end product outline. In Fig. 24, the already executed sections of the two contour sections S2, $ 3 are shown in thick lines. The remaining sections of the two contour sections S2, S3 are shown in thin lines. During the generation of the two contour cuts S2, S3, the block (B) is moved forward by the block slide 164 of the first transport unit. The forward movement of the block (B) continues until the laterally reciprocating cutting wires D2, D3 of the two contour cutting modules 162, 163 have arrived at the rear end of the heart-shaped end product. When the cutting wires D2, D3 have reached the vertices S2a, S3a of the two arcuate portions of the contour cuts S2, S3, the block (B) is moved backwards by the block slider 165 of the second transport unit. The backward movement of the block (B) continues until the laterally inwardly moved cutting wires D2, D3 have reached the longitudinal center axis of the block (B) and the two arcuate sections of the contour cuts S2, S3 are completed. Subsequently, the block (B) is moved forward again by the block slide 164 of the first transport unit. During the forward movement of the block (B), the cutting wires D2, D3 of the two contour cutting modules 162, 163 arranged on the longitudinal central axis of the block (B) generate the rectilinear end sections of the two contour sections S2, S3. During the further forward movement of the block (B), the cutting wires D2, D3 of the two contour cutting modules 162,163 exit the block (B) at the rear end of the block (B) and are received in the block slide 164 by a longitudinal slot 164a. At the end of the forward movement of the block (B), the cut block (B) lies on the front support plate 161.
FIG. 25 shows a block which is used in a transverse system according to the invention and
46 49 546 Pe / GA longitudinal section was cut. The block is divided by transversely extending, straight cuts into several strips (L), which are arranged one behind the other in the longitudinal direction. The block is additionally divided by longitudinally extending contour cuts S1, S2, S3. The contour cuts S1, S2, S3 divide the strips (L) into fan-shaped end products, which are arranged in three longitudinal rows of 20 pieces each. The contour sections S1 are shown in dashed lines with long dashes. The contour sections S2 are shown in dashed lines with short dashes. The contour sections S3 are shown in solid lines.
Fig. 26 shows a rectangular block which has been cut longitudinally in a plant according to the invention. In the block fifteen formed as circular discs end products are included, which are arranged in three longitudinal rows. The block was cut by two sets of contour cuts, each containing several sections whose contour corresponds to a semicircle. In Fig. 26 is a Konturschnittschar in solid lines and the other Konturschnittschar is shown in dashed lines. Fig. 26 also shows the four strips left over when the block was cut, extending in the longitudinal direction of the block. The longitudinal edges of the strips each contain a plurality of subsections whose contour corresponds to a semicircle.
Fig. 27 shows a contour cutting device 166 arranged transversely to the transport path of the blocks. Fig. 27 shows the contour cutting device 166 upstream, rear support plate 167 a main cutting station of a system according to the invention. Fig. 27 shows the platen 167 in a vertical section through the transport path of the blocks. The support plate 167 is arranged on the underside of the transport path. On the support plate 167 is a block (B) between two guide rails 168,169. Above the block (B) is disposed a horizontal upper plate 170 which serves as a hold-down for the block. The contour cutting device 166 is equipped with a contour cutting module 171 which provides a cutting head 173 provided with a vertically arranged cutting tool 172. The cutting head 173 is arranged above the transport path. The cutting tool 172 passes through the transport path in the vertical direction. To produce the contour cuts, the cutting head 173 is moved back and forth transversely to the transport path, while a block along the transport path only moves forwards, or forwards and backwards. * * · # · · ························ φ * φ φ · φ φ φ φ • t # · · § ··· ····
47 49 546 Pe / GA is moved. The course of the contour cuts produced by the cutting head 173 results from the combination of the longitudinal movements of the block (B) with the transverse movements of the cutting head 173. The cutting head 173 may be connected to a drive module which generates the transverse movement of the cutting head corresponding to the profile of the contour cut. The drive module may be a chain drive arranged transversely to the transport path. The drive module may be a ball screw spindle drive arranged transversely to the transport path.
Fig. 28 shows a further contour cutting device 174, which is arranged transversely to the transport path of the blocks. Fig. 28 shows the contour cutting device 174 upstream, rear support plate 175 a main cutting station of a system according to the invention. Fig. 28 shows the support plate 175 in a vertical section through the transport path of the blocks. The support plate 175 is arranged on the underside of the transport path. On the support plate 175 is a block (B) between two guide rails 176.177. Above the block (B) a horizontal, upper plate 178 is arranged, which serves as a hold-down for the block. The contour cutting device 174 is equipped with a contour cutting module 179 which provides a cutting head 181 provided with a vertically disposed cutting tool 180. The cutting head 181 is arranged above the transport path. The cutting tool 180 passes through the transport path in the vertical direction. The cutting head 181 is coupled to a linear motor 182, shown schematically in FIG. 28, which reciprocates the cutting head 181 transversely of the transport path.
Fig. 29 shows schematically a first cutting station 183 in plan view. The first cutting station 183 is arranged upstream of the main cutting station in a system according to the invention. The first cutting station 183 provides a conveyor 184 for the blocks, which is arranged along a rectilinear transport path, along which a support plate 185 for the blocks and a transversely arranged to the transport path cutting device 186 are arranged one behind the other. The conveying device 184 provides a block slide 187, which is displaceable in the longitudinal direction of the transport path, and which pushes the blocks lying on the support plate 185 through the cutting device 186. The blocks are cut into strips (L) as the cutting device 186 passes. 48
♦ ♦ · · · · · · · · · · · · · · ·······
49 546 Pe / GA
Fig. 30 shows a variant of the first cutting station 188. This provides a disposed between a first support plate 189 and a second support plate 190 cutting device 191, which has a transversely to the transport path arranged cutting frame 192, which includes obliquely arranged to the transport path cutting wires 193.
31 shows a further variant of the first cutting station 194. This provides a arranged between a first Auflagepiatte 195 and a second platen 196 cutting device 197, which is equipped with transverse to the transport path adjacent cutting tools formed as circular saws with vertically arranged circular saw blades 198 are.
Fig. 32 shows a longitudinal section through a main cutting station 199. in this, a rear platen 200, a contour cutting device 201 and a front platen 202 along a rectilinear transport path are arranged one behind the other. The contour cutting device 201 is arranged transversely to the transport path and includes a contour cutting frame 203 which is movable transversely to the transport path and contains at least one vertical cutting wire. The contour cutting frame 203 is reciprocated transversely to the transport path by a drive module (not shown in FIG. 32).
Fig. 32 shows a block (B) when passing the contour cutting device 201. The block (B) is partly still on the rear platen 200 and already partially on the front platen 202th
In the main cutting station 199 a arranged along the transport path main conveyor is provided. The main conveyor provides a first transport unit 204 upstream of the rear platen 200, which has a block slider 205 disposed above the rear platen 200, which is located above the rear platen 200 behind the block (B). The block slider 205 is moved forward and backward by a linear motor 206 along the transport path. The main conveyor device provides a second transport unit 207 arranged downstream of the front support plate 202, which has a block slide 208 arranged above the front support plate 202, which moves over the front 49 49. ** ··································································.
49 546 Pe / GA
Platen 202 is arranged in front of the block (B). The block slider 208 is moved forward and backward by a linear motor 209 along the transport path.
In the main cutting station 199, the block (B) is moved forward and backward by the block slides 205, 208 of the two transport units 204, 207 along the transport path, while in the contour cutting device 201, the contour cutting frame 203 containing at least one vertical cutting wire is moved back and forth across the transport path. In the contour cuts generated by the contour cutting device 201, the transverse movements of the contour cutting frame 203 are combined with the longitudinal movements of the block. The combination of the two movements determines the course of the contour cut. In this combination, the transverse movements of the contour cutting frame 203 corresponding to the course of the contour cut are combined with the longitudinal movements of the block corresponding to the course of the contour cut.
The transverse movements of the contour cutting frame 203 corresponding to the course of the contour cut are generated by a drive module connected to the contour cutting frame 203, which contains a drive motor generating the transverse movements of the contour cutting frame 203, in which the generation of the movements of the contour cutting frame during the contour cutting in the transverse direction of the system Control program of the linear motor is integrated.
The longitudinal movements of the block corresponding to the course of the contour cut are generated by the two transport units 204, 207, which move their block slides 205, 208 forwardly and rearwardly along the transport path with the aid of the linear motors 206, 209 in accordance with the profile of the contour cut. The generation of the course of the contour section corresponding forward and backward movements of the block slide 205, 208 is integrated into the control programs of the linear motors 206, 209 of the transport units 204, 207. 49546 Reference number list (freeform cutter) 20-4-2012.rtf Page 1/2
1/49546 Reference number list (freeform cutter) 20-4-2012.rtf page 212
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Q. 3 CO X φ 2 c I, S CM 1 CO &gt; 199 I main cutting station (M ί- CM 00
λ

权利要求:
Claims (47)
[1]
1. Plant for the production of end products by the cutting of flat blocks, in particular of flat or hollow waffle blocks, wherein in the plant an input station for the blocks, at least one cutting station for cutting the blocks and a discharge station for the final products are provided by characterized in that a main cutting station (3, 48, 77, 108, 129, 148, 158, 99) is provided, in which a contour cutting device (12, 51, 84, 110, 135, 150, 160, 166, 174, 201) cutting the blocks is provided, which is arranged transversely to a rectilinear transport path, which is located in Lengthwise of the plant extends that in the main cutting station (3,48,77,108,129,148,158,199) arranged along the transport path main conveyor (6, 58, 88,112, 134,152,164, 165, 204, 207) is provided for the blocks, and that the contour cutting device (12, 51, 84, 110, 123, 135, 150, 160, 166, 174, 201) at least one ko nturschneidmodul (13, 51a, 51b, 86, 87,153,154,155,156, 157,162,163,171,179) provides that with at least one in the transverse direction of the system movable back and forth cutting tool (14a, 86b, 87b, D1, D2, D3, D4, Οδ) ΐ72,180) is provided, which in the contour cutting device (12, 51, 84,110,123,135,150,160, 166,174, 201) in the longitudinal direction of the system passing blocks generates a contour section (S1, S2, S2a, S3, S3a, S4, S5).
[2]
2. Installation according to claim 1, characterized in that the contour cutting device (51,84) has two in the longitudinal direction of the system arranged one behind the other and two different contour sections generating contour cutting modules (51a, 51b, 86, 87).
[3]
3. Installation according to claim 1, characterized in that the contour cutting device (150) three in the longitudinal direction of the system arranged one behind the other and three different contour sections (S1, S2, S3, S4, S5) generating contour cutting modules (153,154,155,156,157).
[4]
4. Installation according to one of claims 1-3, characterized in that as • * * ♦ · «« «··» * «4« ι * ♦ * l «« «« 4 4 • · ♦ · »· * · ··························· 51 49 546 Pe / GA Contour cutting module! (171, 179) a cutting head (173, 181) movable in the transverse direction of the installation is provided, which carries at least one vertically arranged cutting tool (172, 180) passing through the conveying path of the blocks in the vertical direction.
[5]
5. Plant according to claim 4, characterized in that the contour cutting module (171,179) has a with the cutting head (173,181) connected to the drive module, which generates during the contour section in the transverse direction of the system movements of the cutting head (173,181).
[6]
6. Plant according to claim 5, characterized in that the drive module includes a contour template, from which the movements of the cutting head during the contour cutting in the transverse direction of the system are removed.
[7]
7. Plant according to claim 5, characterized in that the drive module is coupled to a contour of the final product of a contour template or an original model decreasing copying device.
[8]
8. Installation according to claim 5, characterized in that the drive module includes a cutting head in the transverse direction of the system reciprocating moving means, which is coupled to a drive motor, wherein the generation of extending during the contour section in the transverse direction of the system movements of the cutting head is integrated in the control program of the drive motor.
[9]
9. Installation according to claim 5, characterized in that as the drive module, a cutting head (181) in the transverse direction of the system reciprocating linear motor (182) is provided, wherein the generation of the running during the contour section in the transverse direction of the system movements of the cutting head (181) is integrated in the control program of the linear motor.
[10]
10. Installation according to one of claims 1-3, characterized in that a contour cutting module (13, 51a, 51b, 86, 87,153, 154,155,156,157, 162, 163) »» * · «» «·· · • * * · I + It is intended that a contour cutting frame (14, 54, 55, 86a, 87a, 138) which can be moved in the transverse direction of the installation be provided with at least one contour cutting frame (14, 54, 55, 86a, 87a, 138) vertically arranged cutting wire (14a, D1, D2, D3, D4, D5) and with a drive module (56, 57, 86c, 87c, 140) is connected, which during the contour cutting in the transverse direction of the system extending movements of the contour cutting frame (14 , 54, 55, 86a, 87a, 138).
[11]
11. Plant according to claim 10, characterized in that the drive module (56, 57, 86c, 87c, 140) includes a contour template, of which during the contour cutting in the transverse direction of the system extending movements of the contour cutting frame (14, 54, 55 , 86a, 87a, 138) are removed.
[12]
12. Plant according to claim 10, characterized in that the drive module (56, 57, 86c, 87c, 140) is coupled to a decreasing the contour of the end product of a contour template or an original model copying device.
[13]
13. Plant according to claim 10, characterized in that the drive module (56, 57) with a drive motor (56b, 57b) coupled movement means (56a, 57a) containing the contour cutting frame (54, 55) in the transverse direction of the system and moved, and that the generation of the running during contour cutting in the transverse direction of the system movements of the Konturschneidrahmens (54, 55) in the control program of the drive motor (56b, 57b) is integrated.
[14]
14. Plant according to claim 10, characterized in that the drive motor is designed as a servomotor (56b, 57b) and the movement device as a transverse to the system extending ball screw spindle drive (56a, 57a).
[15]
15. Plant according to claim 10, characterized in that as a drive module a contour cutting frame (14, 54, 55, 86 a, 87 a, 138) is provided in the transverse direction of the system reciprocating linear motor, wherein the generation of the during the contour section in Transverse direction of the system extending movements of the Konturschneidrahmens (14, 54,55,86a, 87a, 138) in the * e »» ··· »» · μ «· · · ·» Φ * ♦ * «· ι • · · · »ΦΦ ΦΦ» · «« + + + + + + + + + + + f f f f f f f f f f «« «« «« «« 53 53 53 53 53 »» »» »» »» 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53
[16]
16. Plant according to one of claims 10-15, characterized in that the contour cutting frame (86 a, 87 a, 138) two or more, vertically arranged cutting wires (86 b, 87 b, 139), arranged in the transverse direction of the system at a distance from each other are.
[17]
17. Installation according to one of claims 1-16, characterized in that the contour cutting device (150) at least one additional cutting module (153) provides, which is provided with at least one stationary cutting tool (D1) in the blocks one to the longitudinal direction of the plant parallel, straight cut (S1) generated.
[18]
18. Plant according to claim 17, characterized in that the additional cutting module (153) is provided with a stationary cutting frame, which contains at least one, substantially vertically arranged cutting wire (D1).
[19]
19. Plant according to claim 1, characterized in that the contour cutting device (12, 51, 84, 110, 135, 150, 160, 146, 175, 201) has a rear support plate (5, 27, 52, 83, 109, 120a, 149, 159, 167, 175, 200) directly in front of it.
[20]
20. Plant according to claim 19, characterized in that above the rear support plate (27, 52, 83, 167, 175) a transport path upwardly delimiting, optionally adjustable in height, upper plate (36, 66, 68, 170, 178) is provided ,
[21]
21. Plant according to claim 19 or 20, characterized in that on the rear support plate (27, 52, 83, 167, 175) at least one transport path laterally limiting guide rail (17,18, 67, 83b, 168,169,176,177) is provided, and optionally to both Each side of the transport path at least one guide rail (17,18, 67, 83b, 168, 169,176,177) is arranged. • · »*» · · · · · · · · · 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 t t t t t t t t t t t t t t. ··· 54 49 546 Pe / GA
[22]
22. Plant according to claim 1, characterized in that the contour cutting device (51, 84, 110, 135, 150, 160, 201) has a front support plate (53, 85, 111, 137, 151, 161, 202) arranged directly downstream from it.
[23]
23. Plant according to claim 22, characterized in that above the front support plate (53, 85) a transport path upwardly delimiting, optionally adjustable in height, upper plate (68, 85 a) is provided.
[24]
24. Plant according to claim 22 or 23, characterized in that above the front support plate (53,85) at least one transport path laterally limiting guide rail (69,85b) is provided, and that optionally on both sides of the transport path in each case at least one guide rail ( 69, 85b) is arranged.
[25]
25. Plant according to one of claims 1-24, characterized in that the plant (1,20) is provided with a running in the longitudinal direction of the plant, rectilinear transport path extending from the input station (2, 21) by the main cutting station (3 , 24) extends into the dispensing station (4, 25), in that the contour cutting device (12, 51) is arranged in the main cutting station (3, 24) transversely to the rectilinear transport path, and in that the contour cutting device (12, 51) is endless Subordinate product conveyor (15, 42), which receives the end products and extends along the rectilinear transport path to the output station (4, 25) of the system. (Ffg. 1, 5)
[26]
26. Installation according to claim 25, characterized in that above the product conveyor belt (15,42) is provided a transport path upwardly delimiting, optionally adjustable in height, upper plate.
[27]
27. Plant according to claim 25 or 26, characterized in that above the product conveyor belt (15, 42) at least one transport path laterally limiting guide rail is provided, and that optionally at least one guide rail is arranged on both sides of the transport path. 55 49 546 Pe / GA
[28]
28. Plant according to one of claims 25-27, characterized in that the main cutting station (24) is preceded by a blocks in the transverse direction of the plant cutting, first cutting station (23), in which a first cutting device (37) transversely to the transport path and movable blades (38) is provided. (Fig. 5)
[29]
29. Installation according to one of claims 1-18, characterized in that the contour cutting device (51,123) is preceded by a rear support plate (52,121) and a transport unit (58a, 122) of the main conveyor, wherein the transport unit (58a, 122) along the blocks the rectilinear transport path in the longitudinal direction of the system (45,117) moves forward and along the rear support plate (52,121) in the longitudinal direction of the system (45,117) displaceable, rear block slide (59,122) has. (FIGS. 6, 20)
[30]
30. Plant according to claim 29, characterized in that the contour cutting device (51, 123) is followed by an endless product conveyor belt, which receives the end products and extends into the dispensing station (49, 119) of the system (45, 117).
[31]
31. Plant according to claim 29, characterized in that the contour cutting device (51,123) is arranged downstream of a front support plate (53,124) and that along the front support plate (53,124) in the transverse direction of the system (45,117) displaceable cross slide (70) is provided. (FIGS. 6, 20)
[32]
32. Plant according to one of claims 1 -24, characterized in that the contour cutting device (84,110,123,150,160, 201) between a rear support plate (83,109,121, 149,159, 200) and a front support plate (85, 111.151.161, 202) is arranged and that the main conveyor device provides a first transport unit (88a, 113,164, 204) upstream of the rear support plate (83,109,121,149,159, 200) and a second transport unit (88b, 114, 165, 207) arranged downstream of the front support plate (85, 111.151.161, 202) in that the first transport unit (88a, 113, 164, 204) moves the blocks forwards in the longitudinal direction of the installation and with one along the rear. * * ♦ ♦ ι «·« «« «« «• ···················································································································································································································································································· (89, 164, 206), u and that the second transport unit (88b, 114, 165, 207) moves the blocks rearwardly in the longitudinal direction of the installation and is provided with a front block slide (94, 165, 209) displaceable along the front support plate (85, 111, 151, 61, 202) in the longitudinal direction of the installation. (Figures 11-19, 24, 32)
[33]
33. A system according to claim 32, characterized in that along the front support plate (85) in the transverse direction of the system displaceable cross slide (99) is provided. (Fig. 11)
[34]
34. Plant according to claim 32, characterized in that along the rear support plate (82,109) in the transverse direction of the system displaceable cross slide is provided. (FIGS. 11, 19)
[35]
35. Installation according to claim 32, characterized in that in the first transport unit (88 a, 113, 164, 204) with the rear block slide (89, 164, 206) connected to the drive module (90, 205) is provided which during the contour cut in Produced longitudinally of the system extending movements of the rear block slide (89,164, 206). (Figures 12, 13, 32)
[36]
36. A system according to claim 35, characterized in that in the drive module (90) of the first transport unit (88 a) with a drive motor (92) coupled to moving means (91) is provided, the rear block slide (89) in the longitudinal direction of the system and is moved, and that the generation of the running during the contour section in the longitudinal direction of the system movements of the rear block spool (89) in the control program of the drive motor (92) is integrated. (Fig. 12)
[37]
37. Installation according to claim 36, characterized in that in the drive module (90) of the first transport unit (88 a) designed as a servo motor drive motor (92) and a movement device is provided, which is designed as a ball screw spindle drive (91) extending in the longitudinal direction of Plant extends. (Fig. 12) •••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••
[38]
38. Installation according to claim 32, characterized in that the first transport unit (204) with the rear block slide (206) coupled, the rear block slide (206) in the longitudinal direction of the system reciprocating linear motor (205) provides, in which the Generation of the running during the contour section in the longitudinal direction of the system movements of the rear block slide (206) in the control program of the linear motor (205) is integrated. (Fig. 32)
[39]
39. Installation according to claim 32, characterized in that in the second transport unit (88b) with the front block slide (94) connected to the drive module (95) is provided which extends during the contour section in the longitudinal direction of the system movements of the front block slide (94 ) generated. (Fig. 12)
[40]
40. Installation according to claim 39, characterized in that in the drive module (95) of the second transport unit (88 b) with a drive motor (97) coupled to moving means (96) is provided, the front block slide (94) in the longitudinal direction of the system and is moved, and that the generation of the running during the contour section in the longitudinal direction of the system movements of the front block spool (94) in the control program of the drive motor (97) is integrated. (Fig. 12)
[41]
41. A system according to claim 40, characterized in that in the drive module (95) of the second transport unit (88 b) designed as a servo motor drive motor (97) and a movement device is provided, which is designed as a ball screw spindle drive (96) extending in the longitudinal direction of Plant extends. (Fig. 12)
[42]
42. Installation according to claim 32, characterized in that the second transport unit (207) coupled to the front block slide (209), the front block slide (209) in the longitudinal direction of the system reciprocating linear motor (208) provides, in which the Generation of the movements of the front block slide (209) running during the contour cutting in the longitudinal direction of the installation into the control program of the linear motor &lt; p · φ · φ · φ · φ · φφ · φ v φ · φ · φ · φ · φ φ · 4 · φ φ φ * φφ φ · φ φφ # φ · * 58 49 546 Pe / GA (208) is integrated. (Fig. 32)
[43]
43. A system according to any one of claims 29-42, characterized in that one of the blocks of the rear support plate (120 a) of the main cutting station (120) in the transverse direction of the system supplying feeding device (121) is provided.
[44]
44. Installation according to one of claims 29-42, characterized in that the blocks in the transverse direction of the plant cutting, first cutting station (128,183,188,194) is provided, in which the blocks in the transverse direction of the system by a stationary arranged cutting device (132,186,191, 197). that the first cutting station (128,183,188,194) of the plant's main cutting station (129) is upstream of the plant in the transverse direction of the plant and that in the transverse direction of the plant from the first cutting station (128, 183,188,194) leaving blocks of the main cutting station (129) of the plant in the transverse direction be fed to the plant. (FIGS. 21, 29)
[45]
Plant according to claim 44, characterized in that the first cutting station (128, 183) is provided with a cutting device (132, 186) arranged transversely to the direction of movement of the blocks and extending in the longitudinal direction of the plant, and in that the cutting device (132, 186) is two or more, in the longitudinal direction of the system spaced from each other has cutting tools. (Fig. 21,29)
[46]
46. Plant according to claim 44 or 45, characterized in that at the cutting device (197) of the first cutting station (194) as a cutting tool, a stationary arranged circular saw is provided which has a circular axis about a rotating circular saw blade (198). (Fig. 31)
[47]
47. Plant according to claim 44 or 45, characterized in that the cutting device (191) of the first cutting station (188) with a stationary arranged cutting frame (192) is provided, which extends in the longitudinal direction of the plant and two or more, substantially vertically arranged cutting wires (193) contains.

Vienna, on August 16, 2012

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法律状态:
2020-04-15| MM01| Lapse because of not paying annual fees|Effective date: 20190816 |

优先权:

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申请号 | 申请日 | 专利标题

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ATA891/2012A|AT513260B1|2012-08-16|2012-08-16|Plant for producing end products by cutting flat blocks, in particular flat and hollow waffle blocks|ATA891/2012A| AT513260B1|2012-08-16|2012-08-16|Plant for producing end products by cutting flat blocks, in particular flat and hollow waffle blocks|

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US14/421,546| US20150237874A1|2012-08-16|2013-07-22|System for producing end products by cutting flat blocks, in particular flat and hollow wafer blocks|

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RU2015108990/13A| RU2602292C2|2012-08-16|2013-07-22|System for production of end products by cutting flat blocks, in particular, flat and hollow wafer blocks|

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JP2015526916A| JP2015533475A|2012-08-16|2013-07-22|Equipment for producing final products by cutting flat blocks, in particular flat wafer blocks and hollow wafer blocks|

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EP13742420.6A| EP2884845B1|2012-08-16|2013-07-22|System for producing end products by cutting flat and hollow wafer blocks|

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CN201380043745.XA| CN104661530B|2012-08-16|2013-07-22|The equipment of final products is produced by cutting flat block|

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BR112015003001A| BR112015003001A2|2012-08-16|2013-07-22|system for producing end products by cutting flat blocks, in particular flat and hollow waffle blocks|

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PCT/EP2013/065377| WO2014026826A1|2012-08-16|2013-07-22|System for producing end products by cutting flat blocks, in particular flat and hollow wafer blocks|