CN220903246U - Flexible pairing device - Google Patents

Abstract

The disclosure relates to a flexible pairing device, and relates to the technical field of pairing devices. The device comprises a platform assembly, a plurality of identification assemblies, a plurality of jacking assemblies and a plurality of compression supporting assemblies, wherein the identification assemblies, the jacking assemblies and the compression supporting assemblies are arranged on the platform assembly; the platform assembly comprises a plurality of platforms, and the upper surface of each platform is provided with first through holes which are arranged in the same array; the identification component, the jacking component and the compression supporting component are all provided with connecting holes, and the connecting holes are matched with the first through holes arranged in an array manner, so that the identification component, the jacking component and the compression supporting component are freely arranged at any position on the platform; the side of the platform is provided with a plurality of second through holes, and the second through holes on the side of two adjacent platforms are arranged in the same array. The flexible pairing device provided by the disclosure can adapt to frames of different sizes and styles, and improves pairing precision and efficiency.

Description

Flexible pairing device

Technical Field

The disclosure relates to the technical field of pairing devices, in particular to a flexible pairing device.

Background

In mine car series products, the front auxiliary frames of different mine car models are different in size, the front auxiliary frames are main component parts of the auxiliary frames of the mine car power system, are generally in a 'mouth' -shaped or 'H' -shaped structure, and are large in size. On the premise of no assembly equipment, the assembly can only be carried out by scribing and measuring the size on a large platform. By adopting the assembly mode, the process of adjusting the relative positions of the components has larger physical consumption for operators and extremely low assembly efficiency, and the dimensional accuracy is difficult to ensure under the assembly mode.

It should be noted that the information disclosed in the above background section is only for enhancing understanding of the background of the present disclosure and thus may include information that does not constitute prior art known to those of ordinary skill in the art.

Disclosure of Invention

The utility model aims at overcoming the defects of the prior art, providing a flexible assembly device, which can flexibly assemble a platform according to the size and the structure of the components to be assembled, move the position of a marking component, a propping component and a compacting support component on the platform, improve the application range and the assembly efficiency and simplify the operation.

According to one aspect of the present disclosure, a flexible pairing device includes a platform assembly, a plurality of identification assemblies, a plurality of jacking assemblies, and a plurality of compression support assemblies disposed on the platform assembly;

The platform assembly comprises a plurality of platforms, and the upper surface of each platform is provided with first through holes which are arrayed; the first through holes on the upper surfaces of the adjacent two platforms after combination are arranged according to the same array;

The identification component is provided with a plurality of first connecting holes, and the plurality of first connecting holes are matched with the first through holes arranged in an array; the identification component is used for establishing a coordinate system of the platform component to realize the determination of the size and the relative position of each component to be assembled;

The jacking component is provided with a plurality of second connecting holes, and the second connecting holes are matched with the first through holes arranged in an array; the jacking component is used for realizing jacking fixation of the parts to be assembled;

The compaction supporting component is provided with a plurality of third connecting holes, and the third connecting holes are matched with the first through holes arranged in an array; the compaction supporting component is used for compacting and supporting the components to be assembled;

The side of the platform is provided with a plurality of second through holes, and the second through holes on the side of two adjacent platforms are arranged in the same array.

In an exemplary embodiment of the present disclosure, a central axis of at least a part of the second through holes is perpendicular to and coplanar with a central axis of each of the first through holes in a row or column direction.

In one exemplary embodiment of the present disclosure, the plurality of platforms includes at least two different sized platforms.

In an exemplary embodiment of the present disclosure, the platform further includes a support column disposed at a lower side surface of the platform, and a lower end surface of the support column is provided with a rubber pad.

In one exemplary embodiment of the present disclosure, the marking assembly includes a marking piece base plate, a marking piece vertical plate vertically fixedly disposed on the marking piece base plate, and a marking plate disposed on the marking piece vertical plate;

The first connecting hole is arranged on the identification bottom plate, and the identification bottom plate is fixedly connected with the platform through the first connecting hole and the first through hole;

the identification plate is provided with at least two first identification connecting through holes, the identification piece vertical plate is provided with a plurality of second identification connecting through holes, and the second identification connecting through holes are matched with the first identification connecting through holes and are used for enabling the identification plate to achieve height adjustment.

In one exemplary embodiment of the present disclosure, the puller assembly includes a puller bottom plate, a puller riser, a threaded sleeve, and a puller screw;

The second connecting hole is formed in the jacking piece bottom plate, and the jacking piece bottom plate is fixedly connected with the platform through the second connecting hole and the first through hole;

The lower end of the jacking piece vertical plate is fixed on the jacking piece bottom plate;

The upper end of the jacking piece vertical plate is provided with a groove, the screw sleeve is fixedly arranged in the groove, and the groove is matched with the outer surface of the screw sleeve;

the jacking screw penetrates through the screw sleeve and is used for realizing jacking of the end part of the jacking screw and the component to be assembled in a threaded connection mode.

In one exemplary embodiment of the present disclosure, the compression support assembly includes a support assembly and a compression assembly;

The support assembly comprises a support bottom plate, a support cover plate and a support vertical plate arranged between the support bottom plate and the support cover plate; the third connecting hole is arranged on the bottom plate of the supporting piece; the support piece cover plate is fixedly provided with a support table and at least one support screw rod, and the upper surface of the support table is flush with the upper surface of the support screw rod;

The compression assembly comprises a plurality of compression screws vertically arranged on the support piece cover plate, a pressing block sleeved on the outer side of the compression screws, and a compression nut sleeved on the compression screws and positioned above the pressing block;

The length of the compression screw is greater than that of the supporting screw.

In one exemplary embodiment of the disclosure, the support stand is an L-shaped support stand, the L-shaped support stand includes a first step and a second step, the first step is flush with the upper surface of the support screw, and the second step is fixed on the support cover plate through threaded connection;

The briquetting is U type briquetting, U type groove size and the size matching of compression screw of U type briquetting for make U type briquetting cover establish in compression screw's outside.

In one exemplary embodiment of the present disclosure, a height adjustment assembly is also included;

The height adjusting assembly comprises a height adjusting piece bottom plate, a height adjusting piece top plate and a height adjusting piece vertical plate; the height adjusting piece vertical plate is arranged between the height adjusting piece bottom plate and the height adjusting piece top plate;

The height adjusting piece bottom plate is provided with a fourth connecting hole, and is fixedly connected with the platform through the fourth connecting hole and the first through hole; the height adjusting piece top plate is fixedly connected with the jacking piece bottom plate of the jacking assembly or the supporting piece bottom plate of the pressing supporting assembly and used for lifting the height of the jacking assembly or the pressing supporting assembly.

In an exemplary embodiment of the disclosure, the identification assembly further includes a first rib plate fixedly connected with the identification piece bottom plate and the identification piece vertical plate;

The jacking assembly further comprises a second rib plate, and the second rib plate is fixedly connected with the jacking piece bottom plate and the jacking piece vertical plate;

The compaction supporting assembly comprises a third rib plate which is at least fixedly connected with the supporting piece bottom plate and the supporting piece vertical plate;

the height adjusting assembly further comprises a fourth rib plate, and the fourth rib plate is at least fixedly connected with the height adjusting piece bottom plate and the height adjusting piece vertical plate.

The flexible pairing device provided by the embodiment of the disclosure realizes pairing work of components to be paired with different sizes by freely combining the platforms and adjusting the number and the mounting positions of the identification component, the jacking component and the compression supporting component on the platforms according to requirements. The product precision is ensured, the labor intensity is reduced, and the labor efficiency is improved. The assembling device is designed through flexibility, so that after the assembling device is simply adjusted, the assembling requirements of different products can be met, the investment in the aspect of assembling devices is reduced, and the production cost is reduced.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure. It will be apparent to those of ordinary skill in the art that the drawings in the following description are merely examples of the disclosure and that other drawings may be derived from them without undue effort.

Fig. 1 is a schematic structural diagram of a flexible pairing device according to an embodiment of the disclosure.

Fig. 2 is a schematic view of a first platform structure of the flexible pairing device according to an embodiment of the disclosure.

Fig. 3 is a schematic diagram of a second platform structure of the flexible pairing device according to an embodiment of the disclosure.

Fig. 4 is a schematic structural diagram of an identification component of a flexible pairing device according to one embodiment of the disclosure.

Fig. 5 is a schematic structural view of a tightening assembly of the flexible pairing device according to an embodiment of the disclosure.

Fig. 6 is a schematic view of a first compression support assembly of a compliant pairing device in one embodiment of the disclosure.

Fig. 7 is a schematic view of a second compression support assembly of a compliant pairing device in one embodiment of the disclosure.

Fig. 8 is a schematic view of a first height adjustment assembly of the flexible pairing device according to one embodiment of the disclosure.

Fig. 9 is a schematic view of a second height adjustment assembly of the compliant pairing device in one embodiment of the disclosure.

Fig. 10 is a schematic view illustrating a usage state of the flexible pairing device according to an embodiment of the disclosure.

FIG. 11 is a schematic view illustrating a usage state of the flexible pairing device according to an embodiment of the disclosure.

The reference numerals are as follows:

1. The platform assembly, 11, the first through hole, 12, the second through hole, 13, the support column, 101, the first platform, 102, the second platform, 2, the marking assembly, 21, the marking piece bottom plate, 22, the marking piece vertical plate, 23, the marking plate, 24, the first rib plate, 3, the jacking assembly, 31, the jacking piece bottom plate, 32, the jacking piece vertical plate, 33, the threaded sleeve, 34, the jacking screw, 35, the second rib plate, 4, the pressing support assembly, 41, the support piece bottom plate, 42, the support piece vertical plate, 43, the support piece cover plate, 44, the third rib plate, 45, the support table, 46, the connecting bolt, 47, the support screw, 48, the pressing screw, 49, the pressing block, 401, the first pressing support assembly, 402, the second pressing support assembly, 5, the height adjustment assembly, 51, the height adjustment piece bottom plate, 52, the height adjustment piece vertical plate, 53, the height adjustment top plate, 54, fourth, 501, the first height adjustment assembly, 502, the second height adjustment assembly, 6 and the components to be assembled.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings. However, the exemplary embodiments can be embodied in many forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the example embodiments to those skilled in the art. The same reference numerals in the drawings denote the same or similar structures, and thus detailed descriptions thereof will be omitted. Furthermore, the drawings are merely schematic illustrations of the present disclosure and are not necessarily drawn to scale.

Although relative terms such as "upper" and "lower" are used in this specification to describe the relative relationship of one component of an icon to another component, these terms are used in this specification for convenience only, such as in terms of the orientation of the examples described in the figures. It will be appreciated that if the device of the icon is flipped upside down, the recited "up" component will become the "down" component. When a structure is "on" another structure, it may mean that the structure is integrally formed with the other structure, or that the structure is "directly" disposed on the other structure, or that the structure is "indirectly" disposed on the other structure through another structure.

The terms "a," "an," "the," "said" and "at least one" are used to indicate the presence of one or more elements/components/etc.; the terms "comprising" and "having" are intended to be inclusive and mean that there may be additional elements/components/etc. in addition to the listed elements/components/etc.; the terms "first," "second," and the like are used merely as labels, and are not intended to limit the number of their objects.

The disclosed embodiments provide a flexible pairing device, as shown in fig. 1, comprising a platform assembly 1, a plurality of identification assemblies 2, a plurality of jacking assemblies 3 and a plurality of compression support assemblies 4 disposed on the platform assembly 1. The platform assembly 1 comprises a plurality of platforms, the side surfaces of the platforms are respectively provided with a plurality of second through holes 12, and the second through holes 12 on the side surfaces of two adjacent platforms are distributed in the same array. In this way, any part of the side of one platform can be connected with an adjacent platform, and the degree of freedom of combination of each platform in the whole platform assembly 1 is increased. The upper surface of each platform is provided with first through holes 11 which are arranged in an array manner; the first through holes 11 on the upper surfaces of the two adjacent platforms are arranged according to the same array. That is, after the respective stages are combined to form the stage assembly, the respective first through holes 11 on the upper surface of the stage assembly 1 are arranged in a uniform array.

The identification component 2 is provided with a plurality of first connecting holes, and the plurality of first connecting holes are matched with the first through holes 11 arranged in an array; the identification assembly 2 is used to establish a coordinate system of the platform assembly to enable determination of the size and relative position of each component 6 to be assembled. The jacking component 3 is provided with a plurality of second connecting holes, and the second connecting holes are matched with the first through holes 11 distributed in an array; the jacking component 3 is used for realizing jacking fixation of the components to be assembled. The compaction supporting component 4 is provided with a plurality of third connecting holes, and the third connecting holes are matched with the first through holes 11 arranged in an array; the compacting support assembly 4 is used for compacting and supporting the components 6 to be assembled. Therefore, the identification component 2, the jacking component 3 and the compression supporting component 4 can be freely arranged and moved at any position on the platform, and the adaptability and the application field of the assembly device are improved.

The flexible assembly provided by the embodiment of the disclosure can be freely assembled and installed on a plurality of platforms of the device, and meanwhile, connecting holes corresponding to the identification component 2, the jacking component 3 and the compression supporting component 4 are matched with the first through holes 11 on the upper surface of the platform component 1, so that the identification component 2, the jacking component 3 and the compression supporting component 4 can be detached and moved on the platforms so as to be convenient for the free adjustment positions. Therefore, the flexible assembling device can be used for assembling various types of mine car auxiliary frames, train frameworks and the like, the assembling operation difficulty is reduced, the assembling efficiency is improved through the matched use of the identification component 2, the jacking component 3 and the compression supporting component 4, and the higher dimensional accuracy is ensured.

The components of the flexible modular device are further described below with reference to the accompanying drawings.

In order to provide a uniform array arrangement of the first through holes 11 on the upper surface of the assembled platform assembly 1, in one embodiment of the present disclosure, as shown in fig. 3, at least a portion of the central axes of the second through holes may be perpendicular to and coplanar with the central axes of the first through holes 11 in the row or column direction. That is, the side of the stage is turned so as to be coplanar with the upper surface of the stage, and then the portion of the second through holes is aligned with each of the first through holes 11 in the corresponding row or column direction. In this way, when each platform is assembled laterally, the first through holes 11 can be positioned according to the part of the second through holes 12, so as to ensure the array arrangement of the first through holes 11 on the upper surface of the assembled platform, without additional alignment holes or other alignment structures. Of course, if the second through holes 12 cannot be provided corresponding to the first through holes 11, through holes may be provided between adjacent second through holes 12 as alignment holes, and as shown in fig. 2 and 3, in a row of through holes on one side of the stage near the upper surface of the stage, both the second through holes 12 and the alignment holes for alignment may be included.

The auxiliary frame and the common vehicle framework are generally irregularly-shaped structures, so that the flexible assembly device can adapt to various components 6 to be assembled, and the situation that the assembly device occupies too large area is avoided, and the operation is not facilitated. In one embodiment of the present disclosure, the plurality of platforms may include a variety of different sized platforms. As shown in fig. 1-3, the platform assembly 1 includes a first platform 101 (small platform shown in fig. 2) and a second platform 102 (large platform shown in fig. 3). For example, the first platform 101 and the second platform 102 may be combined to form the platform assembly 1 shown in fig. 1, and the three second platforms 102 are combined to form the assembly, and then the first platform 101 is assembled at a position where the marking assembly 2, the tightening assembly 3 or the pressing support assembly 4 is required to be arranged at the periphery. Therefore, the flexibility of assembling the platform is improved, the occupied area of the assembly device is reduced, and the operation space around the assembly device is increased. Further, the second through holes 12 on the side surfaces of the adjacent platforms are fixed through bolts and nuts, so that the operation is simple and the disassembly is convenient.

In one example, the platform further comprises support posts 13 provided on the underside of the platform so that the platform is maintained at a distance from the ground to prevent the platform from being deformed by rust. A rubber pad can be arranged on the lower end face of the supporting column 13, so that a buffering effect can be achieved, and the deformation of the platform is further prevented.

In one embodiment of the present disclosure, as shown in fig. 4, the sign assembly 2 may include a sign base 21, a sign riser 22 vertically fixedly disposed on the sign base 21, and a sign plate 23 disposed on the sign riser 22. The first connecting hole is formed in the identification bottom plate, and the identification bottom plate is connected through bolts and nuts through the first connecting hole and the first through hole 11, so that the identification bottom plate is fixed on the platform. It will be appreciated that the identification assembly 2 may be freely movable in position on the platform to accommodate the shape and size of the components 6 to be assembled. At least two first sign connecting through holes are arranged on the sign board 23, and a plurality of second sign connecting through holes are arranged on the sign piece vertical board 22. For example, a row of equidistant second sign connecting through holes are arranged on the sign vertical plate 22, and the first sign connecting through holes are connected with the second sign connecting through holes in a bolt and nut mode; the first identification connection through holes on the identification plate 23 can be connected with the second identification connection through holes with different heights to realize the height adjustment of the identification plate 23. In this embodiment, the plurality of marking boards 23 may be positioned by passing through a line to establish a coordinate system, so as to conveniently determine the size and the relative position of each component of the pair of components 6 to be assembled, reduce the labor intensity of operators, and improve the labor efficiency. In one example, the sign assembly 2 further includes a first rib 24, where the first rib 24 is fixedly connected to the sign base 21 and the sign riser 22 to increase the firmness of the connection between the sign base 21 and the sign riser 22. Further, the first rib plate 24, the marker bottom plate 21 and the marker vertical plate 22 can be fixedly connected by welding.

In one embodiment of the present disclosure, as shown in fig. 5, the jack assembly 3 includes a jack bottom plate 31, a jack riser 32, a threaded sleeve 33, and a jack screw 34; the second connecting hole is formed in the tightening piece bottom plate 31, and the tightening piece bottom plate 31 is fixedly connected with the platform through the second connecting hole and the first through hole 11 in a bolt and nut connection mode. The lower end of the puller vertical plate 32 is fixed on the puller bottom plate 31, and the puller vertical plate 32 may be vertically fixed on the puller bottom plate 31. The upper end of the jacking piece vertical plate 32 is provided with a groove, the screw sleeve 33 can be fixedly arranged in the groove by welding, and the groove is matched with the outer surface of the screw sleeve 33; the screw 33 is penetrated by a tightening screw 34. Further, the threaded sleeve 33 is provided with internal threads, the jacking screw 34 is provided with external threads, the jacking screw 34 is in threaded connection with the threaded sleeve 33, and in a use state, two or more jacking assemblies 3 are matched, so that the end part of the jacking screw 34 is abutted against the to-be-assembled part 6, and limiting and fixing of the to-be-assembled part 6 in the horizontal direction are realized.

Further, the tightening assembly 3 further includes a second rib plate 35, the second rib plate 35 is fixedly connected with the tightening piece bottom plate 31 and the tightening piece vertical plate 32 to increase the connection strength of the tightening piece bottom plate 31 and the tightening piece vertical plate 32, and the second rib plate 35, the tightening piece bottom plate 31 and the tightening piece vertical plate 32 can be fixed by welding. The second rib plate 35 may have a hollow hole formed in a plate surface thereof, and the hollow hole may be circular, oval, triangular, etc. to reduce the overall weight of the assembly device.

In one embodiment of the present disclosure, as shown in fig. 6 and 7, the compression support assembly 4 includes a support assembly and a compression assembly. The support component for supporting and the compression component for compressing and fixing are combined, so that the installation process of the whole flexible assembly device can be simplified, and the manufacturing cost for independently manufacturing the support component and the compression component is saved. The support assembly includes a support base plate 41, a support cover plate 43, and a support riser 42 disposed between the support base plate 41 and the support cover plate 43. The third connection hole is provided on the support base plate 41, and the support base plate 41 may be connected with the first through hole 11 on the platform through the third connection hole in a bolt-and-nut manner. The support cover plate 43 is fixedly provided with a support table 45 and at least one support screw 47, and the upper surface of the support table 45 is flush with the upper surface of the support screw 47. In this way, the upper surface of the support screw 47 forms a support plane with the upper surface of the support table 45, which can be used for supporting the components 6 to be assembled.

In one example, the support table 45 may be an L-shaped support table, where the L-shaped support table has a first step and a second step, and four sides of the first step are chamfered, and a step surface of the first step is flush with an upper surface of the support screw 47, so as to form a support surface, so as to support the component 6 to be assembled. The second step may be provided with a step through hole fixedly connected with the support cover 43 by a connecting bolt 46. Thus, the L-shaped supporting table is fixedly connected with the supporting piece cover plate 43 through the second step, and a supporting plane is formed by the step surface of the first step and the upper surface of the supporting screw rod 47, so that the components 6 to be assembled can conveniently slide on the supporting plane to adjust the horizontal position.

In one example, the support assembly further includes a third rib 44, the third rib 44 being fixedly connected to at least the support floor 41, the support riser 42. For example, the third rib plate 44 may be fixedly welded to the support bottom plate 41 and the support vertical plate 42, so that the connection strength between the support bottom plate 41 and the support vertical plate 42 is enhanced. For another example, the third rib plate 44 may be fixedly welded with the support bottom plate 41, the support vertical plate 42 and the support cover plate 43, so that the connection strength between the support bottom plate 41 and the support vertical plate 42 is enhanced, and the support strength of the support cover plate 43 is also enhanced. Likewise, the third rib 44 may be reduced in weight by providing a hollowed-out hole.

In one embodiment of the present disclosure, the compression assembly includes a plurality of compression screws 48 vertically disposed on the support cover plate 43, a compression block 49 sleeved outside the compression screws 48, and a compression nut sleeved on the compression screws 48 and located above the compression block 49; the compression screw 48 is longer than the support screw 47. In this way, the components to be assembled are placed on a supporting plane formed by the upper surface of the supporting screw 47 and the upper surface of the supporting table 45, the pressing block 49 is sleeved on the outer side of the pressing screw 48, the pressing block 49 moves downwards until the lower surface of the pressing block 49 is abutted against the components to be assembled 6, and then the pressing nut is screwed down, so that the pressing block 49 presses the components to be assembled to be matched with the supporting plane, and the fixing of the components to be assembled in the vertical and horizontal directions is realized. In one example, the compacts 49 may be U-shaped compacts, and the material of the U-shaped compacts may be a metal, such as iron or the like. The size of the U-shaped groove of the U-shaped pressing block is matched with the size of the compression screw, so that the pressing block 49 is conveniently sleeved on the compression screw 48 from the side surface of the compression screw 48.

It will be appreciated that the compression support assembly 4 may be designed in a number of different sizes depending on the actual requirements of the components to be assembled. For example, the first compression support assembly 401 shown in fig. 6 and the second compression support assembly 402 shown in fig. 7 are two sizes of compression support assemblies 4.

In addition to the different setting of the dimensions of the compression support assembly 4 as desired, in one embodiment of the present disclosure, the adjustment of the jacking assembly 3 and/or the compression support assembly 4 in the height direction may also be accomplished by providing a height adjustment assembly 5. As shown in fig. 8 and 9, the height adjustment assembly 5 includes a height adjustment bottom plate 51, a height adjustment top plate 53, and a height adjustment riser 52; the height adjuster standing plate 52 is provided between the height adjuster bottom plate 51 and the height adjuster top plate 53. The height adjusting piece bottom plate 51 is provided with a fourth connecting hole, the fourth connecting hole is matched with the first through holes 11 distributed in an array, and the height adjusting piece bottom plate 51 can be fixedly connected with the platform through the fourth connecting hole, the first through holes 11 and the platform in a bolt and nut mode. The height-adjusting member top plate 53 has a fifth coupling hole thereon, which is matched with the second coupling hole on the tightening member bottom plate 31 or the third coupling hole on the supporting member bottom plate 41. In this manner, the height adjuster top plate 53 may be fixedly coupled to the puller bottom plate 31 of the puller assembly 3 or the support bottom plate 41 of the compression support assembly 4 for elevating the height of the puller assembly 3 or the compression support assembly 4. Of course, the height adjusting assembly 5 can also be set to different heights and different sizes according to the requirement, so as to be used together with the jacking assembly 3 and the pressing support assembly 4 in an adaptive manner, thereby being applied to more components 6 to be assembled with different height requirements, such as a first height adjusting assembly 501 shown in fig. 8 and a second height adjusting assembly 502 shown in fig. 9.

In one example, as shown in fig. 8, the height adjustment assembly 5 further includes a fourth rib 54, where the fourth rib 54 is fixedly connected to at least the height adjustment member bottom plate 51 and the height adjustment member riser 52. For example, the fourth rib plate 54 may be fixedly welded to the height adjuster bottom plate 51 and the height adjuster vertical plate 52, thus enhancing the connection strength of the height adjuster bottom plate 51 and the height adjuster vertical plate 52. The third rib plate 44 can be fixedly welded with the height adjusting member bottom plate 51, the height adjusting member top plate 53 and the height adjusting member vertical plate 52, so that the connection strength of the height adjusting member bottom plate 51 and the height adjusting member vertical plate 52 is enhanced, and the supporting strength of the height adjusting member top plate 53 is also enhanced. Likewise, the fourth rib 54 may be reduced in weight by providing a hollowed-out hole, which will not be described in detail herein.

For a clearer description of the use of the flexible modular device, the mine car subframe and the train frame are further described as examples, respectively. FIG. 10 is a schematic illustration of a sub-frame of a mining vehicle assembled using the flexible alignment apparatus provided by the present disclosure. In this example, the establishment of the coordinate system is achieved by four identification assemblies 2, and the fixation of the subframe is achieved by a plurality of groups of jacking assemblies 3 and a plurality of compression support assemblies 4. The jacking components 3 can be arranged in a corresponding mode according to the specific structure of the auxiliary frame, and are used for jacking and fixing one plane of the auxiliary frame. The auxiliary frame can be a group of three, is arranged in a triangle shape, and is used for jacking and fixing the corner part of the auxiliary frame. In the example, the cross beam and the side beam of the auxiliary frame have larger height difference, and the lower ends of the jacking component 3 and the pressing support component 4 at the corresponding positions of the cross beam are respectively provided with a height adjusting component 5. In another example, a train architecture is paired using the flexible pairing device provided by the present disclosure as shown in fig. 11. It can be seen that the position adjustment movement of the identification component 2, the tightening component 3, the compression supporting component 4 and the height adjusting component 5 is realized through the free combination of the first platform 101 and the second platform 102, so that the pairing device can be well applied to pairing of train architecture.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any adaptations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

Claims (10)

1. The flexible assembling device is characterized by comprising a platform assembly, a plurality of identification assemblies, a plurality of jacking assemblies and a plurality of compression supporting assemblies, wherein the identification assemblies, the jacking assemblies and the compression supporting assemblies are arranged on the platform assembly;

The platform assembly comprises a plurality of platforms, and the upper surface of each platform is provided with first through holes which are arrayed; the first through holes on the upper surfaces of the adjacent two platforms after combination are arranged according to the same array;

The identification component is provided with a plurality of first connecting holes, and the plurality of first connecting holes are matched with the first through holes arranged in an array; the identification component is used for establishing a coordinate system of the platform component to realize the determination of the size and the relative position of each component to be assembled;

The jacking component is provided with a plurality of second connecting holes, and the second connecting holes are matched with the first through holes arranged in an array; the jacking component is used for realizing jacking fixation of the parts to be assembled;

The compaction supporting component is provided with a plurality of third connecting holes, and the third connecting holes are matched with the first through holes arranged in an array; the compaction supporting component is used for compacting and supporting the components to be assembled;

The side of the platform is provided with a plurality of second through holes, and the second through holes on the side of two adjacent platforms are arranged in the same array.

2. The flexible alignment device of claim 1, wherein at least a portion of the central axis of the second through-holes is perpendicular to and coplanar with the central axis of each of the first through-holes in the row or column direction.

3. The flexible alignment device of claim 1, wherein the plurality of platforms comprises at least two different sized platforms.

4. A flexible alignment device as defined in claim 3, wherein the platform further comprises a support post disposed on a lower side of the platform, a lower end surface of the support post being provided with a rubber pad.

5. A flexible pairing device according to any one of claims 1 to 4 wherein,

The identification component comprises an identification piece bottom plate, an identification piece vertical plate vertically and fixedly arranged on the identification piece bottom plate and an identification plate arranged on the identification piece vertical plate;

The first connecting hole is arranged on the identification bottom plate, and the identification bottom plate is fixedly connected with the platform through the first connecting hole and the first through hole;

the identification plate is provided with at least two first identification connecting through holes, the identification piece vertical plate is provided with a plurality of second identification connecting through holes, and the second identification connecting through holes are matched with the first identification connecting through holes and are used for enabling the identification plate to achieve height adjustment.

6. The flexible assembly device of claim 5, wherein the puller assembly comprises a puller base plate, a puller riser, a threaded sleeve, and a puller screw;

The second connecting hole is formed in the jacking piece bottom plate, and the jacking piece bottom plate is fixedly connected with the platform through the second connecting hole and the first through hole;

The lower end of the jacking piece vertical plate is fixed on the jacking piece bottom plate;

The upper end of the jacking piece vertical plate is provided with a groove, the screw sleeve is fixedly arranged in the groove, and the groove is matched with the outer surface of the screw sleeve;

the jacking screw penetrates through the screw sleeve and is used for realizing jacking of the end part of the jacking screw and the component to be assembled in a threaded connection mode.

7. The flexible alignment device of claim 6, wherein the compression support assembly comprises a support assembly and a compression assembly;

The support assembly comprises a support bottom plate, a support cover plate and a support vertical plate arranged between the support bottom plate and the support cover plate; the third connecting hole is arranged on the bottom plate of the supporting piece; the support piece cover plate is fixedly provided with a support table and at least one support screw rod, and the upper surface of the support table is flush with the upper surface of the support screw rod;

The compression assembly comprises a plurality of compression screws vertically arranged on the support piece cover plate, a pressing block sleeved on the outer side of the compression screws, and a compression nut sleeved on the compression screws and positioned above the pressing block;

The length of the compression screw is greater than that of the supporting screw.

8. The flexible alignment device of claim 7, wherein the support stand is an L-shaped support stand comprising a first step flush with an upper surface of the support screw and a second step secured to a support cover plate by a threaded connection;

The briquetting is U type briquetting, U type groove size and the size matching of compression screw of U type briquetting for make U type briquetting cover establish in compression screw's outside.

9. The flexible alignment device of claim 8, further comprising a height adjustment assembly;

The height adjusting assembly comprises a height adjusting piece bottom plate, a height adjusting piece top plate and a height adjusting piece vertical plate; the height adjusting piece vertical plate is arranged between the height adjusting piece bottom plate and the height adjusting piece top plate;

The height adjusting piece bottom plate is provided with a fourth connecting hole, and is fixedly connected with the platform through the fourth connecting hole and the first through hole; the height adjusting piece top plate is fixedly connected with the jacking piece bottom plate of the jacking assembly or the supporting piece bottom plate of the pressing supporting assembly and used for lifting the height of the jacking assembly or the pressing supporting assembly.

10. The flexible alignment device of claim 9, wherein the identification assembly further comprises a first web fixedly connected to the identification member base plate and the identification member riser;

The jacking assembly further comprises a second rib plate, and the second rib plate is fixedly connected with the jacking piece bottom plate and the jacking piece vertical plate;

The compaction supporting assembly comprises a third rib plate which is at least fixedly connected with the supporting piece bottom plate and the supporting piece vertical plate;

the height adjusting assembly further comprises a fourth rib plate, and the fourth rib plate is at least fixedly connected with the height adjusting piece bottom plate and the height adjusting piece vertical plate.