• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a transport system (1) for transporting ball fragments and dust which is formed upon encounter with a ball catcher (2). The conveyor system comprises a first conveyor unit (3) which transports the ball fragments and dust to a container (4). Transport system (1) comprises a collecting unit (7) and a dispensing unit (9) arranged to dispense a quantity M of ball fragments and dust from the collecting unit (7) and to the first conveyor unit (3). The conveyor system (1) comprises drive means (11) for operating the dispensing unit (9) and the first conveyor unit (3), as well as a control unit for controlling the conveyor system (1).
    公开号:DK201901299A1
    申请号:DKP201901299
    申请日:2019-11-07
    公开日:2021-05-19
    发明作者:Snedker Claus
    申请人:Snedker Solutions Aps;
    IPC主号:
    专利说明:

    The invention relates to a transport system for transporting ball fragments and dust which is formed by meeting with a ball catcher arranged in relation to the transport system, which transport system comprises a first conveyor unit arranged to transport the ball fragments and dust to a container. , which first conveyor unit is arranged in a surrounding housing, which conveyor system comprises a collecting unit with an inlet opening, where the ball fragments and dust are passed through / fall down and the conveyor system comprises an outlet opening for disposing of the ball fragments and the dust. The invention also relates to a method for transporting ball fragments and dust to a container, which ball fragments and dust are formed upon encounter with a ball catcher, which ball fragments and dust are captured by a storage unit and fall onto a first conveyor unit. Finally, the invention relates to the use of the transport system for carrying out the method.
    Various solutions exist for transporting ball fragments and dust that arise at the encounter with a ball catcher, to a container. The problem with the fragments and the dust is that it contains toxic substances and compounds, including lead, which is why it is necessary to safely transport this waste to a landfill / container for final disposal. The problem with many of these solutions is, among other things, that the fragments and dust have a very high temperature up to 1000 C when it falls on the conveyor. There is a great risk that the conveyor gets stuck as a result of the hot fragments / lumps wedging in between the conveyor and
    DK 2019 01299 A1 2 the surrounding house. There is also a risk that the hot waste will melt to the conveyor and impede its function. CH700908 B1, US10240903 B1 and US2005 / 0034594 A1 relate to all transport systems for transporting away ball fragments and dust generated by the encounter with a ball catcher. The solutions all involve a snail, which transports the waste away. The transport can take place by a motorized or manual operation of the auger. | In all cases, there is a risk that the waste will clump together on the auger due to the high temperatures.
    There is also a risk of the waste getting stuck between the auger and the surrounding house, which prevents the auger from transporting the waste.
    Thus, there is a need for a transport system of ball fragments and dust which picks up this waste in a cooled state and where it is possible to transport the waste away without the waste having a risk of getting stuck either to the conveyor itself or between the conveyor and the surrounding house. Likewise, there is a need for the ball fragments and the dust to be handled in a closed system so that no persons come into direct contact with it.
    It is the object of the present invention to improve a transport system in which the disadvantages and shortcomings of the known systems are overcome, or at least a useful alternative is provided.
    According to the invention, there is provided a conveyor system as set out in the preamble, wherein the conveyor system comprises a dispensing unit arranged to dispense a quantity M of ball fragments and stem from the collecting unit to the first conveyor unit, and that - the conveyor system comprises - means for operating the dispensing unit and conveyor unit, as well as a control unit for controlling the transport system.
    DK 2019 01299 A1 3 The temperature of the fragments and the dust when they reach the collection unit is very high - around 1000 C, why it needs to cool down before falling on the first conveyor unit. The waste slides from the ball catcher down into a collecting unit shaped like a funnel, from where it is directed down into a dispensing unit. This is typically shaped like an impeller extending the entire length of the conveyor unit. | the dispensing unit retains the fragments / dust in between two vane blades and after a given time t, the vane wheel will turn, whereby the waste falls onto the underlying conveyor unit. This is an endless conveyor belt. The impeller rotation is controlled by a control unit - a relay control - which controls a motor for rotating the impeller. The impeller is thus rotated at intervals. The same control unit controls the movement of the conveyor unit, which also takes place in intervals and thus is not a continuous propulsion, but takes place in steps.
    From the first conveyor unit, which is located in a tight housing and only with an opening up towards the collection unit, the cooled waste is transported to a container, where it is collected. The container can possibly be equipped with / stand on a scale so that you know when the container is about to be full. Between the first conveyor unit and the container, a second conveyor unit is typically arranged, which in principle is constructed in the same way as the first. There may be even more conveyor units if the transport system is to be able to transport the waste far away. The dispensing unit is thus a separate unit and not built into the conveyor unit itself, ie. that it is arranged at a certain vertical distance from it and is a separate construction part which cooperates with the conveyor belt via a control system. The movements of the conveyor belt and the movements of the dispensing unit are synchronized via the control system. The propellant comprises motors which drive the dispensing unit and the conveyor unit, respectively. The control system that regulates the operation of the motors is typically a PLC control. The dispensing unit is housed in the surrounding housing.
    According to an exemplary embodiment, the first conveyor unit comprises an endless conveyor belt, which is arranged to transport the ball fragments and dust released by the dispensing unit to the container, which belt is mounted around a belt conveyor comprising drive means for propelling the conveyor belt.
    An endless belt is used, which has the advantage over a auger that the risk of the waste getting stuck is considerably reduced. It is also cheaper to use a tape - especially when using a polymer tape - rather than a auger, which is typically made of a metal.
    According to an exemplary embodiment, the first dispensing unit comprises an impeller with a number of vanes arranged on a rotating rod, which impeller extends along the entire length of the first conveyor unit, and that between two adjacent vanes in the impeller the amount M of ball fragments and dust is collected from the collection.
    Typically, the impeller comprises 4-6 blades; preferably 6. At such a number, a sufficient cavity is ensured between two adjacent vanes for storing the mass M before it is released by turning the impeller and falls onto the underlying conveyor belt.
    According to an exemplary embodiment, the drive means are arranged for the impeller to turn a given angle AV and after a given time t, which two parameters are controlled by the control unit, at which the quantity M is released to the conveyor unit, and that the same control unit is arranged to control the transport of ball fragments and dust. in the first conveyor unit towards the container.
    The control unit is typically a PLC unit which is programmed to turn the impeller after a given and programmed time t. Likewise, it is programmed to start the belt, which can run continuously, but where it is most energy efficient to let it run stepwise so that it initiated when a quantity of waste is released from the dispensing unit,
    DK 2019 01299 A1 which must be transported further. The time in which the bullet fragments lie in the dispensing unit varies depending on what is being fired with and how large the firing intensity is. It is programmed into the PLC controller. The time t can be anywhere from 10 sec to 1 min or more. A typical average time is 30- 5 40 sec. If 30 sec is used. is the course that the impeller turns after the mass M has been in a cavity between two vanes for 30 sec. and falls down on the belt, which now sets in motion. The PLC controller is programmed to activate a propellant a motor that drives the belt. The belt then runs for 30 sec while the impeller is stationary. The belt then stands still after the 30 sec and the impeller now rotates, as the mass in the cavity has been the time t to cool down, in the time that the belt is running. When the mass hits the belt, it sets in motion and thus continues. The angle V depends on the number of impellers, but with 6 impellers the wheel will thus turn 60.
    According to an exemplary embodiment, the conveyor system comprises a second conveyor unit connected to the first conveyor unit or integrated therewith and arranged in extension thereof, and that the first and second conveyor units comprise a final conveyor belt, which conveyor belt is passed over a number of rollers and driven by the drive means comprising at least one motor .
    In a preferred exemplary embodiment, the conveyor system comprises at least one further conveyor unit, which in principle is constructed in the same way as the first conveyor unit. The two conveyor units are built together so that the belt extends uninterrupted between the two units and is tensioned by propellants located at each end. The propellants are motors - drum motor or gear motor. | the transition between the two conveyor units, the conveyor belts are typically supported by rollers. The angle between the two conveyor units is typically oblique upstream. The second conveyor unit is thus located obliquely upwards relative to the horizontal plane - where its longitudinal axis forms an acute angle with the horizontal plane - and ends in a funnel from which fragments and dust fall
    DK 2019 01299 A1 6 into a container. According to an exemplary embodiment, the endless conveyor belt comprises ribs laid across the longitudinal direction and the direction of movement, and the conveyor belt is mounted around a belt conveyor comprising at least one motor for operating the conveyor belt. The ribs ensure that the fragments are moved up and / or forward if the friction between the fragments / dust and the surface of the belt is too small. The surface of the belt between the ribs is suitably flat and smooth, so that no fragments / dust adhere to the surface when the belt has reached the container and is emptied. This ensures that all the waste falls into the container. The conveyor belt is typically delimited along the longitudinal sides with sloping, upright beams. The entire transport system is embedded in the surrounding house. Possibly. the collecting unit can be mounted on top of the housing, and where there is then an opening down to the underlying dispensing unit at the top of the housing.
    According to an exemplary embodiment, the conveyor belt is made of a polymer which is heat-resistant at temperatures up to at least 150 ° C and preferably up to 200 ° C.
    Suitable materials for the endless belt are PVC or PU materials. Since the waste which falls on the belt from the dispensing unit is strongly cooled, polymeric conveyor belts can be used which are heat-resistant at the temperatures in question. The belt rests on a number of rollers. It is supported on the underside by longitudinal rails, which are part of the belt conveyor.
    According to an exemplary embodiment, the control unit is arranged to control the movements / propulsion of the belt and the dispensing unit and the release of the mass M, and that movement of the dispensing unit at time t is a function of an expected cooling of ball fragments and dust from a temperature T ° to a temperature of about 70% -130.
    DK 2019 01299 A1 7 A stepwise propulsion of the belt and a stepwise rotation of the dispensing unit are provided. When the belt is stationary, the material located between two blade blades on the belt will be emptied. | the time when the belt is in propulsion, a fragmentation of fragments / dust located in the dispensing unit takes place. When the time t has elapsed, the PLC control will cause the dispensing unit to empty its contents onto the belt, which is now stopped. The belt and the dispensing unit are thus active in time intervals and the respective activities are staggered from each other.
    The invention also relates to a method of the preamble and wherein the ball fragments and dust are collected by a dispensing unit which retains a mass M for a given time t, after which the mass M is released from the dispensing unit and is picked up by the first conveyor unit and passed on to the container.
    According to an exemplary embodiment, the first conveyor unit transports the mass released from the dispensing unit in time t towards the container, while the dispensing unit stands still / is inactive in time t, after which the conveyor unit stops its propulsion and the dispensing unit releases a new mass M and the conveyor unit is started and transports it released mass in time t while the dispensing unit is stationary. according to an exemplary embodiment, the transport comprises that the mass M is transported from the first conveyor unit to a second conveyor unit, from where it is transported to the container.
    According to an exemplary embodiment, the dispensing unit stands still in time t with a mass M located in an area between two impellers, and when the impeller rotates, the mass M is released and falls on the first conveyor belt, which is initiated and transports the cooled ball fragments and dust in time.
    DK 2019 01299 A1 8 h, while the impeller is stationary in time t. According to an exemplary embodiment, the propellants comprise a stepper motor and / or a gear motor and / or a drum motor.
    According to an exemplary embodiment, the belt conveyor comprises longitudinal ribs / rails placed axis parallel and in the same plane and at a distance relative to each other to support the endless conveyor belt.
    According to one embodiment, the ribs / rails are arranged in two sets in each conveyor unit - a first rail set and a second rail set - which upper surface of the first rail set supports the part of the belt - the upper part where the fragments and dust are transported and the second rail set supports the lower part of the band opposite the upper part.
    The ribs are made of a polymer. According to an exemplary embodiment, the first conveyor unit comprises an endless conveyor belt, which conveyor belt is passed over and rests on a number of rollers and is driven by a motor.
    According to an exemplary embodiment, the conveyor belt is delimited along the longitudinal sides by beams and the conveyor belt comprises ribs arranged transversely to the longitudinal direction.
    The invention will now be explained in more detail with reference to the figures, in which: FIG. 1 is a perspective view of a conveyor system according to the invention and with a ball catcher mounted.
    FIG. 2 shows a section through that in fig. 1 with a
    DK 2019 01299 A1 9 mounted ball catcher. FIG. 3 shows a section through the transport system according to the invention shown in figure 2 with mounted ball catcher and along the line I-III.
    FIG. 4 is an enlarged section of FIG. 3 is framed with a circle C. FIG. 5 is a section through the collecting unit.
    FIG. 6 is an exploded view of the first conveyor unit and dispensing unit with the conveyor belt removed. FIG. 7 is an exploded view of the second conveyor unit with the conveyor belt removed.
    FIG. 8 is a stylized exploded view of the first and second conveyor units, showing the relationship of the belt to the rails and to the housing surrounding the belt.
    The invention will now be explained in more detail with reference to fig. 1, 2,3 and
    4. This exemplary embodiment shows a transport system 1 with a ball catcher 2 mounted, which is a commercially available product. The ball catcher 2 is mounted on the transport system 1. When firing shots, the ball catcher will catch the bullets, and at the encounter with this it is fragmented into pieces and dust, whereby a very high temperature arises - around 1000 C. The transport system 1 comprises a housing 5, which in Figure 1 is shown open in the upper surface of the horizontal part of the transport system. During use, this part is also closed. In this exemplary embodiment, the conveyor system 1 consists of a first conveyor unit 3, the longitudinal axis of which is oriented perpendicularly (horizontally located) in relation to the vector of gravity. First conveyor unit 3
    DK 2019 01299 A1 10 is connected to a second conveyor unit 22 via its exit opening 8. The second conveyor unit 22 is inclined upwards oriented and opens into a hopper 25, from which fragments and dust fall into a container 4. The second conveyor unit 22 is also surrounded of a closed housing 5. In this example, first 3 and second 22 conveyor unit are integrated into each other.
    The conveyor units 3,22 comprise at least one endless rotating conveyor belt 17. The system could also consist solely of the first conveyor unit 3, from which fragments and dust fall into a container via the outlet opening 8 of the first conveyor unit 3 | in that case, the first conveyor unit 3 would simply be raised above the ground to make room for a container 4. The conveyor system 1 consists of a dispensing unit 9, which is arranged above the first conveyor unit 3 in its full length. Under each ball catch there is a collecting unit 7 in the form of a funnel - see fig. 5 - where this is described. Since several ball catches are typically arranged next to each other on a shooting range, the collecting unit will thus be extended axis parallel to the first conveyor unit 3 and in its full length. The collecting unit 7 directs the fragments and the dust down into the dispensing unit 9. This is formed as an impeller 12 consisting of a center shaft / rotating rod 14, to which a number of vanes 13 are radially located. The forest surfaces 15 in the example shown are plate-shaped with a surface extension parallel to the center line of the center shaft. The paddle surface 15 could also be shaped as a sub-bowl. The number of vanes 13 is 4-6, preferably 6, as it is quite important that a cavity is created between the vanes 13 for collecting a given amount of fragments and dust for cooling for a given time. The impeller 12 is typically made of stainless steel and must be able to withstand the high temperatures of the dust and fragments, which are in the range 1000 C. The diameter of the impeller 12 is typically about 90 mm. The impeller 12 is moved at intervals by means of a drive means 11 in the form of a motor, for example a drum motor or gear motor, a control unit in the form of a PLC control
    DK 2019 01299 A1 11 is programmed to activate the motor to make a partial rotation of the impeller 12 corresponding to the angular distance AV ”between two adjacent blades 13 after a given time t.
    As a result, the contents of a cavity 29 between the two adjacent vanes 13 fall onto the underlying conveyor belt 17. Due to the residence in the dispensing unit 9, the fragments and dust are cooled - typically to about 100 ° C +/- 10-30 "- and meet the underlying conveyor belt 17. as cooled dust and small fragments.
    This eliminates the risk of the conveyor belt 17, although made of a polymer, being damaged by heat from the fragments, as the fragments have been cooled.
    Thus, the life of the band 17 is not affected by temperature conditions related to the fragments / rod.
    The endless conveyor belt 17 in this case consists of a single endless conveyor belt made of a suitable polymer such as Polyurethane or Polyvinyl chloride.
    At one end of the first conveyor unit 3 it is driven by a drive means 11 such as a drum motor 23 ', and at the opposite end of the second conveyor unit 22 it is driven by a corresponding drive means 11 a drum motor 23'. If the conveyor unit exceeds a length of 7-10 meters, another drum motor is inserted.
    In the transition between the first 3 and the second 22 the conveyor unit are arranged rollers 19 which support the belt.
    The advantage of the conveyor belt 17 being a continuously closed belt extending continuously from the first 3 to the second 22 conveyor unit is that no opening occurs between the two units.
    The fragments and the dust are transported by the movement of the conveyor belt 17 up to an exit opening 26 in the second conveyor unit 22, which opens into a hopper 25. The hopper 25 is located above the collecting container 4, and the fragments and the dust now fall into it.
    A hose is suitably mounted between collection container 4 and funnel 25. The hose ensures that all the toxic material is collected in the barrel and that nothing falls next to it.
    An exhaust valve 27 is located on the hopper 25 so that very fine dust is removed as it will have difficulty falling into the container.
    Exhaust valves can also
    DK 2019 01299 A1 12 is placed in relation to the first conveyor unit 3 either next to the endless conveyor belt 17 or next to the collecting unit 7. The movement of the conveyor belt 17 is controlled by the same control unit which controls the dispensing unit 9, and also the conveyor belt 17 will be moved in time intervals adapted to the dispensing unit. 9 emptying of fragments / dust. The collecting unit 7 is shown as a sectional drawing in fig. 5. It consists of 2 baffles 28 'and 28 "arranged opposite each other - Both plates 28'28" are | direction down towards the dispensing unit 9 bent at an angle to each other in order in this way to create a funnel which directs the fragments and the dust down into a cavity between two vanes 13. The size of the opening 30 between the two baffles corresponds largely to the distance between two adjacent vanes outer free finishing edges. Opposite the opening 30 is an exit opening 6 - for collecting ball fragments and - dust from the ball catcher - located.
    The collecting unit 7 extends in horizontal direction and in the entire length of the dispensing unit 9 axis parallel to this and to the first conveyor unit 3. The length of the first conveyor unit 3 is typically about 2.5-3 meters and the width is typically 0.4-0.5 m The length of the first 3 and second 22 conveyor units is about 5.5-6 meters.
    Figure 6 shows an exploded view of the first conveyor unit 3 as well as of the dispensing unit 9 in the form of an impeller 12. The first conveyor unit 3 comprises 2 sets of parallel rails 31 - a first set 32 and a second set 33 - made of PEHD. The rails 31 support a conveyor belt (not shown), which is laid over the rails 31 when a support frame / belt conveyor 39 comprising the rails 31 etc. is constructed to support them. The first set of rails 32 forms on one surface a support surface for the upper part of the belt, and on the opposite side the rails 31 are adhered to support plates 34 which support and ensure that the rails 31 maintain the same distance from each other. The support plates 34, opposite the surface which supports the first set
    DK 2019 01299 A1 13 rails 32, supports the second set of rails 33, which is built in the same way as the first set of rails 32. The support plates 34 are at a distance of 30 -40 cm and are equipped with recesses in which the rails 31 can be inserted. and maintained. The second set of rails 33 also forms a support surface for the endless belt. The endless belt is passed over two drums / rollers 19 - where one drum is placed so that it abuts against the surface of the upper part of the belt, which faces in the direction of the dispenser 9. The other drum is placed so that it abuts against the part of the surface of the lower band which faces in the direction of the dispenser 9. Vertical holders 35 ensure that the support plates 34 are attached to the surrounding housing 5 (only plate parts of the housing shown in figure). The side plate 36 shown is part of the housing
    A drum motor 23 ', located at the opposite end of where the drums 19 are located, causes the belt to move. The first conveyor unit 3 is equipped with extraction valves which remove the finest dust.
    Figure 7 shows an exploded view of the second conveyor unit 22, which is constructed in the same way as the first conveyor unit 3. The belt and the supporting rails 31, etc. are arranged in the housing, in which a hatch 37 can be conveniently placed for inspection of the belt.
    | one end is the drum motor 23 ”, which ensures that the belt runs in both the first 3 and the second conveyor unit 22, arranged. The outlet opening 26 is connected to a funnel from which the fragments and dust fall into a container.
    Fig. 8 shows a stylized exploded view of the first 3 and second 22 conveyor unit, in which the relation of the belt 17 to the rails 31 and to the housing 5 surrounding the belt 17 is outlined. The belt 17 is typically made of a PU or PVC and is equipped with transverse ribs 38 so that fragments and dust can be transported at an oblique angle upwards, the ribs 38 catching the fragments and the dust in case the frictional resistance between them and the surface of the belt is insufficient.
    DK 2019 01299 A1 14 The embodiment shown thus indicates a conveyor system 1 comprising 2 conveyor units, but depending on where the conveyor system is to be placed, it can only consist of a first conveyor unit.
    Likewise, it may consist of more than one of the two conveyor units if the fragments and dust are to be transported further and by more twisted road.
    However, the system will always include a first conveyor unit.
    The first conveyor unit will be horizontally oriented, but the other conveyor units may be inclined upwards or downwards in relation to this depending on the surroundings.
    The dispensing unit itself is in the example shown manufactured as a longitudinal impeller.
    Other constructions have as an essential feature that there is a controlled and planned release of the mass which is to fall down on the conveyor belt.
    The dispensing unit will continue to move in step to ensure cooling of the ball fragments and dust.
    权利要求:
    Claims (11)
    [1]
    A conveyor system (1) for transporting ball fragments and dust formed by encounter with a ball catcher (2) arranged in relation to the conveyor system (1), which conveyor system (1) comprises a first conveyor unit (3) and arranged to transport the ball fragments and the dust to a container (4), which first conveyor unit (3) is arranged in a surrounding housing (3), which transport system (1) comprises a collecting unit (7) with an inlet opening (6), wherein the ball fragments and the stem are passed through / fall down and the transport system (1) comprises an exit opening (8) for disposing of the ball fragments and the dust characterized in that the transport system (1) further comprises a dispensing unit (9) arranged to dispense an amount M of ball fragments and dust from the collecting unit (7) to the first conveyor unit (3), and that the transport system (1) comprises drive means (11) for operating the dispensing unit (9) and the first conveyor unit (3), as well as a control unit oath for the management of the transport system (1).
    [2]
    A conveyor system (1) according to claim 1, characterized in that the first conveyor unit (3) comprises an endless conveyor belt (17) which is arranged to transport the ball fragments and dust released by the dispensing unit to the container (4), which conveyor belt (17) is mounted around a belt conveyor (39) comprising drive means for propelling the conveyor belt (17).
    [3]
    A transport system (1) according to claim 1 or 2, characterized in that the dispensing unit (9) comprises an impeller (12) with a number of
    DK 2019 01299 A1 2 buckets (13) arranged on a rotating rod (14), which paddle wheel (12) extends along the entire length of the first conveyor unit (3), and that between two adjacent paddles (13) in the paddle wheel (12) the quantity M is captured of ball fragments and dust from the collection unit (7).
    [4]
    A conveyor system (1) according to claim 3, characterized in that the drive means (11) are arranged for the impeller (12) to rotate a given angle AV and after a given time t, which two parameters are controlled by the control unit, at which the quantity M is released to first conveyor unit (3), and that the same control unit is arranged to control the transport of ball fragments and stems in the first conveyor unit (3) in the direction of the container (4).
    [5]
    A conveyor system (1) according to any one of the preceding claims, characterized in that the conveyor system (1) comprises a second conveyor unit (22) connected to the first conveyor unit or integrated therewith and arranged in extension thereof, and that first (3) and second (22) the conveyor unit comprises an endless conveyor belt (17), which conveyor belt (17) is passed over a number of rollers (19) and is driven by the drive means (11) comprising at least one motor (23).
    [6]
    A conveyor system (1) according to claim 2, 3, 4 or 5, characterized in that the endless conveyor belt (17) comprises ribs (38) arranged transversely to the longitudinal direction and the direction of movement, and the conveyor belt (17) is mounted around a belt conveyor ( 39) comprising a motor for operating the conveyor belt (17).
    [7]
    A conveyor system (1) according to any one of claims 2-6, characterized in that the endless conveyor belt (17) is made of a polymer which is heat-resistant at temperatures up to at least 150 ° C and
    DK 2019 01299 A1 3 preferably up to 200 ° C.
    [8]
    A conveyor system (1) according to any one of the preceding claims, characterized in that the control unit is arranged to control the movements / propulsion of the conveyor belt (17) and the dispensing unit (9) and release the mass M, and that movement of the dispensing unit (9) at time t is a function of an expected cooling of spherical fragments and dust from a temperature T ° to a temperature of about 70 ° -130 °.
    [9]
    A method of transporting ball fragments and dust to a container (4), which ball fragments and dust are formed upon encounter with a ball catcher (2), which ball fragments and dust are collected by a collecting unit (7) and fall on. a first conveyor unit (3) characterized in that the ball fragments and dust are collected by a dispensing unit (9) which retains a mass M for a given time t, after which the mass M is released from the dispensing unit (9) and is collected by the first conveyor unit (3) and passed on to the container (4).
    [10]
    Method according to claim 9, characterized in that the first conveyor unit (3) transports the mass released from the dispensing unit (9) in time t towards the container (4), while the dispensing unit (9) stands still / is inactive in time t, after which the first conveyor unit (3) stops its propulsion and that the dispensing unit (9) releases a new mass M, and that the first conveyor unit (3) is started and transports the released mass in time t while the dispensing unit (9) is stationary.
    [11]
    Use of the transport system (1) according to any one of claims 1-8 for carrying out the method according to claims 9-10.
    类似技术:
    公开号 | 公开日 | 专利标题
    US20190072328A1|2019-03-07|Dryer system with improved throughput
    EP3141854B1|2019-07-17|Drier apparatus
    US20050034594A1|2005-02-17|Projectile retrieval system
    BRPI0610987A2|2010-08-10|waste processing apparatus and method
    DK180478B1|2021-05-19|A transport system as well as a method for transporting ball fragments and dust formed upon encounter with a ball catcher and using the transport system to perform the method.
    US3298138A|1967-01-17|Apparatus for deflashing molded resilient pieces
    GB1563928A|1980-04-02|Rotary retort furnaces
    WO2006000703A1|2006-01-05|Device for treating food products in a bath of liquid
    ES2689249T3|2018-11-12|Paper feeder and paper supply method
    RU2478888C2|2013-04-10|Ice lumps store and method of making ice lumps
    WO2009068946A1|2009-06-04|Extraction plant with regular flow
    CN107537643B|2019-03-12|A kind of automatically feed swing shredding machine
    US20120308349A1|2012-12-06|Sewage Silo With Centripetal Action Discharge Arm
    US8292085B2|2012-10-23|Run-of-mine coal separator
    EP0006751A1|1980-01-09|Deflashing apparatus
    US8070083B2|2011-12-06|Method and apparatus for processing logs
    JPH0957085A|1997-03-04|Quantitative delivering method
    US20220053743A1|2022-02-24|System and method for mosquito pupae sorting, counting and packaging
    CN110201982B|2021-02-09|Grading recovery system for waste lead storage batteries
    JP2006239677A|2006-09-14|Method and device of treating shellfish
    JP5472827B2|2014-04-16|Shell processing system and shell processing method
    JP4401793B2|2010-01-20|Ice lump unloading device
    CN107637557A|2018-01-30|A kind of chilled small fish feeding system
    US2260926A|1941-10-28|Measuring materials feeder
    CA1323764C|1993-11-02|Scrap freezing tunnel
    同族专利:
    公开号 | 公开日
    DK180478B1|2021-05-19|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    2021-05-19| PAT| Application published|Effective date: 20210508 |
    2021-05-19| PME| Patent granted|Effective date: 20210519 |
    优先权:
    申请号 | 申请日 | 专利标题
    DKPA201901299A|DK180478B1|2019-11-07|2019-11-07|A transport system as well as a method for transporting ball fragments and dust formed upon encounter with a ball catcher and using the transport system to perform the method.|DKPA201901299A| DK180478B1|2019-11-07|2019-11-07|A transport system as well as a method for transporting ball fragments and dust formed upon encounter with a ball catcher and using the transport system to perform the method.|
    [返回顶部]