• 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 device (1) for at least partially vibration-decoupled connection of a first building part (2) to a second building part (4). The device comprises at least one elongated carrier unit (6), wherein the carrier unit (6) has a first end portion (8) which can be assigned to the first building part (2) and a second end area (12) spaced therefrom which can be assigned to the second building portion (4) the first end region comprises a vibration decoupling means (10). According to the invention, the carrier unit (6) consists of a profile body having in the longitudinal direction (X) at least one longitudinal section with open and a longitudinal section section with closed profile shape and the longitudinal section section with closed profile form cooperates with the vibration decoupling means.
    公开号:CH708383B1
    申请号:CH00929/14
    申请日:2014-06-18
    公开日:2017-11-15
    发明作者:Fritschi Hubert;Bähr Michael;Weber André
    申请人:Schöck Bauteile GmbH;
    IPC主号:
    专利说明:

    Description: [0001] The invention relates to a device for at least partially vibration-decoupled connection of a first building part to a second building part. Furthermore, it relates according to claim 10 to a building part and according to claim 11 to a building, wherein always at least one device for at least partially vibration-decoupled connecting a first part of the building is provided with a second part of the building.
    Such particular sound-absorbing joints between building parts done so far by the fixed installation of a damping element in a building part, which is designed to receive a power transmission means. The power transmission means is always considered as a closed hollow profile or an open profile, such as. a T-beam profile, formed, which is brought with its first end with the damping element installed in the wall in contact and is connected at its second end fixed to the second part of the building. Such a damping element is known for example from DE 19 513 664 A1 and the power transmission means are known from DE 2006 3 747 A1.
    The arrangement described above has, for example, the disadvantage that the carrier units used must be solid in order to permanently hold the loads occurring. However, the massive embodiment requires a high material usage, which sets a large part of the cost of such a carrier unit.
    It is therefore an object of the present invention to provide a device for at least partially decoupled vibration connecting a first part of the building with a second part of the building, in which the material costs are reduced compared to the prior art.
    The solution of the above object is achieved by a device for at least partially decoupled vibration connecting a first building with a second part of the building according to the subject of claim 1. This device comprises at least one elongate support unit, wherein the support unit has a first end portion for connection to a elastic vibration decoupling means for connecting to the first building part and a second end portion spaced therefrom for connection to the second building part. According to the invention, the carrier unit consists of a profile body having in the longitudinal direction at least one longitudinal section section with an open and a longitudinal section section with a closed profile shape, and the longitudinal section section with closed profile form cooperates with the vibration decoupling means.
    As a vibration-decoupled connection is preferably a damping or insulation of the vibrations, in particular impact sound, or a reduced transmission or a complete reduction in a first part, in particular the first part of the building, initiated vibrations with respect to a second with the first Part at least indirectly connected part, in particular the second part of the building to understand.
    An elongated carrier unit preferably describes a carrier unit, whose extension in one direction, in particular the longitudinal direction, is greater than in the width direction and the height direction. Particularly preferably, the extension of the carrier unit in the longitudinal direction corresponds to a multiple of the extension in the width and height direction, in particular substantially or exactly the 2, 3, 4, 5, 6, 7, 8, 9, 10 times, although values between these integer factors are conceivable. The carrier unit or the base body is preferably designed rigid and is particularly preferably made of metal, in particular steel.
    As a profile shape, the outer shape of a component, such as a molded article, is preferred. the shape of the carrier unit or of the carrier unit at least partially with training basic body, in particular a dome to look at. An open profile can be open in the orthogonal direction to the longitudinal axis of the carrier unit, wherein for the purposes of the present invention open or open forms are to be understood as an open profile preferably or exclusively in the direction of the longitudinal axis of the carrier unit. A profile is particularly preferably open along the longitudinal direction of the carrier device if the wall forming the profile is not completely delimited from the environment by a continuous enclosure of an interior, this interior in at least one plane orthogonal to the longitudinal direction.
    It is hereby conceivable that at least the first end portion of the support unit is at least partially or completely formed as an open profile and / or the second end portion of the support unit is at least partially or completely formed as an open profile and / or between the first and the second end region formed central region or connecting region is at least partially or completely formed as an open profile. Preferably, the vibration decoupling means cooperates with a partially closed portion of the sectionally open profile shape of the carrier unit.
    As open profiles, among other U, hat or Ω, T, double T and L profiles are conceivable.
    According to an alternative inventive or further concretizing embodiment, the vibration decoupling means is fixedly arranged at the first end region and this at least partially enclosing.
    As a preferred embodiment of the inventive solution, this embodiment is also advantageous because it provides a simple, safe and easy to install device, especially since the supply unit with the vibra tion provided carrier units vorfertigbar and thus without additional installation effort on the site are used.
    According to a further preferred embodiment of the present invention, the partially closed portion of the profile shape is formed by a base body of the carrier unit and at least one associated, in particular cohesively, positively, field-locking and / or non-positively connected, load distribution plate, wherein the partially closed portion preferred round or square or substantially round or substantially rectangular, in particular square, is formed. An integral connection between the load distribution plate and the base body preferably consists of an adhesive connection, a welded connection or a solder connection.
    The load distribution plate ensures a uniform distribution of the load in the vibration decoupling means and increases the bearing surface, that is, the area, with which the base body without load distribution plate arranged thereon would rest on the vibration decoupling means, would be smaller than with the load distribution plate arranged thereon. Preferably, the bearing surface formed by the load distribution plate is a multiple, in particular 1,1, 1,3, 1,5, 1,7, 1,9, 2, 2,5, 3, 3, 5 or 4 times the area with which the main body without load distribution plate arranged thereon would rest on the vibration decoupling means. As a result, the voltage resulting from the load is reduced and thus a better impact sound insulation is achieved, i. the load is introduced evenly and extensively into the vibration decoupling means.
    Preferably, each carrier unit to exactly one load distribution plate, which is also conceivable that a plurality, in particular, for example, 2, 3 or 4 load distribution plates are arranged on the base body. Furthermore, it is conceivable that a load distribution plate is formed from a plurality of superimposed and / or juxtaposed or arranged elements. The shape of the load distribution plate is preferably substantially or exactly flat, but it is also conceivable that it is formed partially spherical or curved in the region of its boundary edges. Furthermore, the load distribution plate preferably has a rectangular, polygonal, partially spherical, in particular partially round, completely spherical or completely round flat basic shape. Preferably, the load distribution plate of the same material, which also consists of the main body. However, it is also conceivable that the base body and the load distribution plate consist of different materials. The thickness or height of the load distribution plate is preferably substantially or exactly constant over the length and / or width of the plate, but it is also conceivable that the thickness of the load distribution plate changes continuously or discontinuously over the length and / or width of the plate.
    This embodiment is advantageous because the shape of the load distribution plate is selectable depending on the particular installation situation. It is thus possible to arrange different load distribution plates on the same basic bodies. This allows an optimal adaptation of the carrier unit to the loading conditions and / or to the respective vibration decoupling means.
    According to a further preferred embodiment of the present invention, the main body and the load distribution plate via a surface contact or a line contact with each other directly in connection, wherein the contacting surface is preferably at least, exactly or substantially one-tenth, one-eighth, one-fifth, one-fourth , which comprises half or more than half of the top surface of the load distribution plate.
    This embodiment is advantageous because the forces occurring in the installed state permanently and defined by means of the inventive device are transferable. This is preferably due to the fact that in a two-dimensional interaction of the base body and the load distribution plate, the active surface pairs are extremely accurate aligned with each other and are extremely stable connected to each other.
    According to a further preferred embodiment of the present invention, the base body is formed as an at least partially open in the longitudinal direction of the carrier unit profile, in particular U-shaped profile, which is at least partially closed by means of the load distribution plate.
    This embodiment is advantageous because light and cheap open profiles can be used as a body and optimized by the targeted or defined attachment of the load distribution plate for transmitting or directing the forces occurring, in particular stabilized, and with respect to the surface of the Basic body enlarged shape is formed. The main body is thus preferably by means of the load distribution plate load-dependent or load-appropriate areas reinforced, supplemented or expandable, whereby a sufficient dimensioning while avoiding unnecessary Überdimensionierungen is avoidable.
    According to a further preferred embodiment of the present invention, the vibration decoupling means extends substantially from the first end portion in the direction of the second end portion and thereby encases at least a predetermined proportion of the carrier unit in the circumferential direction. As wrapping here is to be understood, inter alia, preferably a detachable or insoluble overlaying, enclosing or covering. The vibration decoupling means enclosing the first end region is preferably elastic or partially elastic and preferably contacts the outer surface of the base body and / or the load distribution plate at least in sections. Preferably, the vibration decoupling means is formed directly on the outer surface of the base body and / or the load distribution plate.
    It is advantageous that the vibration decoupling means is connected to the base body and / or the load distribution plate such that any installation situations can be realized. Thus, the Schwingententkopplungsmit tel, for example, cover more than half, half, a quarter, an eighth or a sixteenth of the length of the body. Preferably, the vibration decoupling means substantially or completely covers the load distribution plate in the longitudinal direction of the carrier unit.
    According to another preferred embodiment of the present invention, the vibration decoupling means comprises a shroud with forming collar for contacting with a joint profile. The collar is preferably formed integrally with the sheath and is particularly preferably made of the same material as the rest of the shroud forming the vibration decoupling means. The collar preferably extends by a multiple, in particular 1.5, 2, 2.5, 3, 3.5, 4 times, the average shell thickness substantially or exactly orthogonal, in particular in width and / or or depth direction, to the longitudinal direction of the carrier unit. In the longitudinal direction towards the middle of the carrier unit, therefore, a collar which is at least partially and particularly preferably completely circumferential is preferably additionally formed from the material forming the vibration damping element.
    Such a collar is advantageous since it serves in particular for sealing a joint profile, by means of which the device according to the invention is preferably installed, against the component to be connected. It is therefore possible to dispense with further sealing means, which in particular the installation cost is significantly reduced.
    According to a further preferred embodiment of the present invention, the vibration decoupling means is produced by foaming the carrier unit elastomeric bearings, ie, that the end of the carrier unit or the carrier unit at least partially forming the dome, in particular steel mandrel, preferably together with load distribution plate is foamed with an elastomer in order to ensure a separation of the impact sound insulation of the two components or building components to be connected.
    The foaming of the carrier unit is advantageous because the elastomer in this way is simple, durable and reliable on the main body and / or the load distribution plate attachable.
    When installing the device with the end foamed with an elastomer in a flight of stairs, the load distribution plate is preferably on the top (i.e.: the U is open at the top). If the device is installed with the elastomerumschäumten side in a pedestal, the load distribution plate is preferably on the bottom (that is, the U is open at the bottom). In principle, a connection of a plate to a wall is conceivable. Here, the load distribution plate in the case of an elastomerumschäumten end in the wall is preferably also on the bottom (ie: the U is open at the bottom) and in the case of an elastomerumschäumtes end in the plate, it is preferably on the top (ie: the U is open at the top).
    Generally, it should be noted here that in the combination of a first part of the building, in particular a staircase, and a second part of the building, in particular a pedestal, or a staircase and a wall always the stairs is the supported component. With the combination of plate and wall, the plate is always the component supported. Depending on the position of the load distribution plate (top or bottom), only the type of load application changes. In order for the power transmission to work from the supported to the structural member without major deformations, it is necessary for one side to be non-elastomeric but cemented in. In principle, however, it is also possible for the second side or the second end region in some form, e.g. in the same way as the first end region or by means of a sleeve receiving the end region to embed in an elastomer.
    According to a further preferred embodiment of the present invention, the vibration decoupling means preferably at least in sections in a contact, connection, overlay or coupling region on a negative mold to the shape or profile of the carrier unit.
    This embodiment is advantageous because optimal support of the carrier unit can be effected by the negative mold in a compact manner.
    The invention is also directed to a building part with at least one connected thereto and previously described device for vibration-decoupled connection of the building part with another part of the building.
    Such building parts are e.g. prefabricated for prefabricated houses and can be fed to a construction site as required. The building parts include not only ceiling parts, shelves or Baikon, but also stairs, such as. Spiral staircases, and other fixable especially on a supporting element building parts. Preferably, the building part has a plurality, in particular 2, 3, 4, 5, 6 or more, preferably in a common plane one above the other and / or juxtaposed devices according to the invention.
    The invention is also directed to a building having at least one supporting part of the building and arranged on the supporting part of the building further part of the building, wherein the building parts are connected by means of at least one device described above for vibration-decoupled connection of the building parts.
    Further advantages, objects and features of the present invention will be explained with reference to the following description of attached figures, in which an example of a device for at least partially decoupled vibration connecting a first part of the building with a second part of the building or its components are shown. Components of the device, which in the figures at least substantially coincide with regard to their function, can hereby be identified by the same reference symbols.
    [0035] FIG.
    1 shows an overview plan with respect to. The views shown in Figures 2 to 4;
    FIG. 2 shows the two-dimensional side view of the device in an installed state, indicated by the section B-B in FIG. 1; FIG.
    3 shows the two-dimensional rear view of the device in an installed state, indicated by the letter C in FIG. 1; and
    Fig. 4 in Fig. 1 by the letter D marked two-dimensional front view of the device in an installed state.
    In Fig. 1, first, a first representation four side by side in a joint profile 24 arranged inventive device 1 shown in a front view and on the other hand, a second representation of the four juxtaposed inventive devices 1 is shown in a rear view below. By the section B-B, the sectional view shown in Fig. 2 along the longitudinal axis of the inventive device 1 is displayed. The circle indicated by the letter C indicates a rear view of a vibration decoupling means 10 required according to the present invention, which is shown in greater detail in FIG. With the circle indicated by the letter D, a front view is displayed on a main body 14, at least partially enclosed by the vibration decoupling element 10, which is connected to a load distribution plate 16, which is described in greater detail in FIG.
    In Fig. 2, a device 1 according to the invention is in an installed state, i. shown in connection with a first and a second schematically indicated building part 2,4. In this case, the device 1 represents an element connecting the building parts 2, 4, which makes it possible to transfer forces, in particular weight forces, from one building part 4 to the other part of the building 2, thereby forming a barrier, through which it enters one of the two building parts 4 Vibrations are prevented from transmitting to the other part of the building 2 or by which the vibrations are reduced or damped.
    The device 1 comprises a support unit 6, which preferably consists of a hollow or open body 14 or profile support, in particular a U-shaped or hat-shaped profile beam or steel mandrel, to which a power transmission means 16, in particular a load distribution plate 16, is attached. The load distribution plate 16 is preferably arranged in a first end region 8 of the elongate base body 14, in particular welded. The load distribution plate 16 extends from a substantially vertical end edge 13 of the main body 14 in the longitudinal direction X in the direction of the second end portion 12 of the base body 14. The load distribution plate 16 extends over at least 10 percent of the length of the base body 14th
    The first end region 8 of the main body 14 and the load distribution plate 16 attached thereto and preferably the end edge 13 of the first end region 8 are surrounded by a vibration decoupling means 10. The vibration decoupling means 10 is contacting or adhering to the first and second end face 16a, 16b and on the bottom 16c of the load distribution plate 16 at. The upper side 16d of the load distribution plate 16 defines a cavity together with the main body 14. It is conceivable for the vibration decoupling means 10 to be detachably arranged on the carrier unit 6, wherein the vibration decoupling means 10 is particularly preferably an elastomer foamed and thus adhering to the carrier unit 6.
    The vibration decoupling means 10 forms in a cladding region 20, which extends in the X direction along the base body 14 and the load distribution plate 16, preferably in the Y direction on the top side and bottom side of the base body 14 different strong or thick trained wall portions 10a, 10b , Preferably, the wall portion 10a formed in the Y direction below the load distribution plate 16 is thicker than the wall portion 10b formed in the Y direction above the base 14.
    Furthermore, the vibration decoupling means 10 has a collar 22 for placement on a joint profile 24. The collar 22 forms a conclusion of the physical expansion of the vibration decoupling means 10 in the X direction. Preferably, the collar 22 is formed circumferentially and is compared to the Wandungsanteilen 10 a, 10 b is a constant elevation or expansion in the Y and / or Z direction. All the vibration decoupling means 10 integrally forming shares, in particular the collar 22, the upper and lower wall portion 10a, 10b and an end-side wall portion 10c, which superimposes the end edge 13, can be arbitrarily adjusted in their spatial extent as needed.
    The joint profile 24 has a first opening 26 for passing the entire vibration decoupling means 10 together with the carrier unit 6 arranged therein in a first wall part 27. Furthermore, the joint profile 24 has a second opening 28 in a second wall part 29 of the joint profile 24 for at least partially passing the sheathed region 20 of the vibration decoupling means 10. The first and second wall portion 27, 29 of the joint profile 24 are spaced from each other by a plurality of spacer elements 30.
    On the side of the joint profile 24, from which the U-shaped steel mandrel 6 protrudes without elastomer, preferably a cover (not shown) to install, which fixes the mandrel 6 in position and the joint profile 24 against the component 4 to be connected this page seals. The first opening 27 may also be referred to as a recess and may be required to secure the lid or cover by means of fasteners (not shown), e.g. Klippsen, in or on the recess limiting wall can fix.
    The second end portion 12 of the support unit 6 is firmly anchored or anchored in the second part of the building 4, in particular cast in concrete or screwed. However, it is also conceivable that the second end region 12 of the carrier unit 6 is arranged in a running sleeve (not shown), whereby e.g. the joint thickness between the building parts 2, 4 is variable.
    In Fig. 3, the back of the vibration decoupling means 10 is shown. It can be seen from this illustration that the vibration decoupling means 10 has an upside-down T-shape. This embodiment is advantageous, since it substantially corresponds to the negative shape of the carrier unit 6 (see FIG. The encircling collar 22 can enclose the jacket surface 10a, 10b in a constant thickness and thus also be formed along the negative mold, but alternatively it can also be designed as a plate-shaped, in particular rectangular, wall component. The reference numeral 29 denotes the second wall part of the joint profile 24 in which the second opening 28 (see Fig. 2) is provided, through which the vibration decoupling means 10 extends.
    In Fig. 4, the carrier unit 6 is shown consisting of the main body 14 and the load distribution plate 16, which, however, is indicated only by the reference numeral 16 designates the surface of the load distribution plate. The main body 14 is formed as a mandrel in the form of a U-profile, in particular in the form of a hat or Ω-profile 32. The hat profile 32 has a first and a second substantially or exactly aligned in the Y direction web 32a, 32b, wherein webs 32a, 32b are connected to each other at a respective upper end by a connecting web 32c. The connecting web 32c oriented in the Z direction. End tabs 32d are formed on the first and second side ridges 32a, 32b at a lower end opposite to the Y direction from the upper end, respectively. More preferably, the direction indicated by the arrow Y is opposite to the direction of gravity. The end tabs 32d preferably extend in the Z direction and form connecting elements for connecting the main body 14 to the surface 16d of the load distribution plate 16.
    The U-shaped or hat-shaped (or omega-shaped) design of the carrier unit 6 or the dome is to be regarded as exemplary. In principle, the mandrel may consist in sections of any open or closed profile shape. It is also possible that the mandrel consists of a solid cross section in principle of any shape. The minimum embedment length of the mandrel in concrete is preferably substantially, exactly or at least 2 times the length of the mandrel diameter, more preferably the minimum embedment length is substantially, exactly or at least 5 times the length of the mandrel diameter.
    The carrier unit 6 is enclosed in the X direction by the vibration decoupling means 10 at least in the first end region 8 (see FIG. The second end face 16b of the load distribution plate 16 (both not shown) is also superimposed by the vibration decoupling means 10 according to this illustration. The portion of the vibration decoupling means 10 overlapping the second end face 16b of the load distribution plate 16 is formed in the region of the collar 22 (see FIG.
    The vibration decoupling means 10 is guided in total by the first opening 26 in the first wall portion 27 of the joint profile 24 and coupled with the arranged in the X direction behind the first wall portion 27 second wall portion 29 of the joint profile 24, wherein the second wall portion 29 as U shaped strip can be seen through the first opening 26 therethrough.
    Furthermore, the limited by the main body 14 and the load distribution plate 16 space is preferably hollow. The portion of the vibration decoupling means 10 indicated by the reference numeral 10c preferably superimposes the end of the carrier unit 6 formed in the X direction, while the further end portion of the vibration decoupling element 10 indicated by the reference numeral 10d preferably the portion which can be coupled to the joint profile 24, in which particularly preferred Collar 22 (see Fig. 2) is formed, forming.
    A trough (not shown) surrounding the vibration decoupling means 10 or the elastomer body 10, in particular a U-shape, may additionally be provided, such an additional solid formwork body, which preferably surrounds the elastomer-sheathed end of the dome 6, not necessary is.
    List of Reference Numerals 1 Apparatus 2 First building part 4 Second building part 6 Support unit
    权利要求:
    Claims (11)
    [1]
    8 First end area 10 Vibration decoupling means 10a Lower wall part 10b Upper wall part 10c End side wall part 10d Further end wall part 12 Second end area 13 Vertical end edge 14 Main body 16 Lastverteilerplatte 16a First end 16b Second end 16c Bottom 16d Surface of the load distribution plate 20 Shell 22 Collar 24 Joint profile 26 First opening of the Joint profiles 27 First wall part of the joint profile 28 Second opening of the joint profile 29 Second wall part of the joint profile 30 Spacers 32 U-profile 32a First lateral web 32b Second lateral web 32c Connecting web 32d End flap Patent claims
    1. Device (1) for at least partially vibration-decoupled connecting a first building part (2) with a second building part (4), comprising at least an elongated support unit (6), wherein the carrier unit (6) a first part of the building (2) assignable first end (8) and a second end region (12), which can be assigned to the second building part (4), and wherein the first end region has a vibration decoupling means (10), characterized in that the carrier unit (6) consists of a profile body which is longitudinally (X) has at least one longitudinal section section with an open and a longitudinal section section with a closed profile shape and that the longitudinal section section with closed profile shape cooperates with the vibration decoupling means.
    [2]
    2. Apparatus according to claim 1, characterized in that the partially closed portion of the profile shape is formed at least in the region of a base body (14) of the carrier unit (6) connected to the load distribution plate (16).
    [3]
    3. A device according to claim 2, characterized in that the base body (14) and the load distribution plate (16) via a surface contact with each other.
    [4]
    4. Apparatus according to claim 2 or 3, characterized in that the base body (14) forms at least partially in the longitudinal direction (X) of the carrier unit (6) open profile, which is at least partially closed by means of the load distribution plate (16).
    [5]
    5. Device according to one of the preceding claims, characterized in that the vibration decoupling means (10) is fixedly arranged at the first end region (8) and this at least partially umschliessend.
    [6]
    6. Device according to one of the preceding claims, characterized in that the vibration decoupling means (10) extends substantially from the first end portion (8) toward the second end portion (12) and thereby at least a predetermined proportion of the carrier unit (6) in the circumferential direction jacketed.
    [7]
    7. The device according to claim 6, characterized in that the vibration decoupling means (10) has a sheath (20) with forming collar (22) for contacting with a joint profile (24).
    [8]
    8. Device according to one of the preceding claims, characterized in that the vibration decoupling means (10) by a foaming of the carrier unit (6) is generated elastomer bearing.
    [9]
    9. Device according to one of the preceding claims, characterized in that the vibration decoupling means (10) at least in sections, a negative mold to the profile shape of the carrier unit (6).
    [10]
    10. Building part with at least one associated device (1) according to one of claims 1 to 9 for connecting the building part (2) with another building part (4).
    [11]
    11. Building with at least one supporting building part (4) and one on the supporting building part (4) arranged further part of the building (2), wherein the building parts (2, 4) by means of at least one device (1) according to one of claims 1 to 9 with each other are connected.
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    同族专利:
    公开号 | 公开日
    CH708383A2|2015-01-30|
    AT514653A2|2015-02-15|
    AT514653A3|2015-04-15|
    AT514653B1|2016-02-15|
    DE102013107589A1|2015-01-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE4409477A1|1994-03-19|1995-09-21|Schoeck Bauteile Gmbh|Noise damping supporting component|
    ES2157247T3|1994-06-01|2001-08-16|Solutia Europ Nv Sa|APPARATUS AND PROCEDURE TO CONFORM SEMIELABORATED ARCHED CUT.|
    DE19513664A1|1995-04-08|1996-10-10|Schoeck Bauteile Gmbh|Insulating element for soundproofing storage of building parts|
    DE19700765A1|1997-01-11|1998-07-16|Elasto Gleitlager Technik Gmbh|Damped mounting for construction|
    DE10063747A1|2000-12-21|2002-06-27|Schoeck Bauteile Gmbh|Structural element used as heat insulation comprises force-transferring reinforcing element made of plastic and surrounded on all sides by closed corrosion-protection coating|
    NO332957B1|2009-04-17|2013-02-11|Svein Berg Holding As|balcony Fixing|
    法律状态:
    2015-03-31| PCAR| Change of the address of the representative|Free format text: NEW ADDRESS: EIGERSTRASSE 2 POSTFACH, 3000 BERN 14 (CH) |
    2020-09-30| PFA| Name/firm changed|Owner name: SCHOECK BAUTEILE GMBH, DE Free format text: FORMER OWNER: SCHOECK BAUTEILE GMBH, DE |
    优先权:
    申请号 | 申请日 | 专利标题
    DE102013107589.4A|DE102013107589A1|2013-07-17|2013-07-17|Device for vibration-decoupled connection of a first building part with a second part of the building|
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