RU2817653C1 - Deflection compensation device, convenient for fixing working table - Google Patents

Abstract

FIELD: furniture.

SUBSTANCE: invention relates to work table equipment used in sheet bending machine. Device comprises a support, a pad, and a fastening assembly. Support and pad are wedged. In the strap there is a groove in which the lower skew blocks are located in the direction of the length of the working table, above which the upper skew blocks are installed. Adjacent lower skew blocks are interconnected by means of connecting blocks. Fastening unit includes fastening oblique block, fixing element and pushing elements. On the support there is a sliding groove with a fixing oblique block, which has a larger diameter at the upper end than at the lower end. Fixing element passes through the fixing oblique block. Pushing elements are installed on the support and push the fixing oblique block from the opposite sides of the fixing oblique block.

EFFECT: due to optimization, the fastening structure is relatively stable and does not undergo loosening during a long period of operation.

4 cl, 6 dwg, 4 ex

Description

Field of technology

The present invention relates to the field of related work table equipment, in particular to a deflection compensation device convenient for fixing the work table.

State of the art

With the rapid development of rail transportation, the demand for sheet metal structural components for rail vehicle body is increasing every year. As a key body processing equipment, the sheet metal structural member bending mold for rail vehicle body is widely used in the field of manufacturing the body of rail vehicles, such as multi-unit rolling stock, high-speed train, subway, and other kinds of vehicles, has a wide range of applications. To produce parts and assemblies for many types of rail vehicles, it is necessary to use sheet bending machines.

In the process of bending sheet metal on a sheet metal bending machine, elastic deformation of the slider is inevitable as a result of the force on the structure of the sheet metal bending machine. Although the amount of deformation is extremely small, however, for workpieces that are bent with high precision, the workpiece is still subject to bending deformation, so it is impossible to ensure the uniformity of the angle along the entire length. For the traditional hydraulic sheet bending machine, due to the uneven force applied by the hydraulic cylinder, the workpiece will be deflected in the length direction during the bending process, moreover, the extra long mold is often used to bend shorter workpieces, which will cause the upper half of the mold to only apply force in the middle part of the lower half of the mold, and after long-term use will cause the middle part of the workbench to sink, causing a serious impact on the straightness of the products.

To solve the problem, it would be possible to: 1) increase the rigidity and strength of the machine body by increasing the total weight of the machine, but this increases the cost of the equipment and does not meet the requirements of modern production; 2) choose a desktop with deflection compensation, this method is less expensive. At present, in China and abroad, there are generally two ways to compensate for the deflection of a sheet metal bending machine: hydraulic deflection compensation, which involves building a plurality of hydraulic cylinders into the vertical plate of the work table; and mechanical deflection compensation, which uses multiple groups of raised wedges. Mechanical compensation of deflection using wedges is enshrined in patents. For example, Chinese Patent Application 201120271046.9, published on March 7, 2012, discloses a deflection compensation device with oblique wedges for a sheet metal bending machine. This device includes an upper plate and a stand; the stand has rectangular grooves in the length direction where the lower carriages are installed. Odd pairs of mechanisms with oblique wedges are evenly installed on the lower carriages in the longitudinal direction; in this case, the mechanism with oblique wedges consists of oblique wedge II and oblique wedge I, laid from bottom to top in series. A rectangular metal support and an upper carriage are placed in series on the lower carriage. Wedges I are evenly laid on the upper carriage; the upper plate is fixedly connected to oblique wedges I using screws.

Another Chinese patent application 201620545340.7, published on October 26, 2016, discloses a deflection compensation device for a sheet metal working table including a stand. The stand is provided with a rectangular groove in the longitudinal direction, a plurality of oblique wedges are placed in the rectangular groove, a longitudinal first oblique plane is located on the upper surface of the oblique wedge, an arc plate is placed above the oblique wedge, the lower surface of which is a second oblique plane, a first oblique plane and a second oblique the plane is located oppositely; the arc pad and stand are fixed in the longitudinal direction relative to the rectangular groove, a hollow bushing is placed between the oblique wedges; a tension rod is installed between the oblique wedge and the hollow bushing, which is a screw rod; On the inner wall of the hollow sleeve there are threads corresponding to the screw rod. Chinese patent application 201811479570.8, published on February 15, 2019, discloses a device for longitudinal mechanical deflection compensation of the work table of a sheet metal bending machine and a method for its manufacture, including upper oblique sheets and lower oblique sheets. The upper oblique sheet and the lower oblique sheet have a separate whole structure and the same dimensions, including on the lower surface of the upper oblique sheet there is a first oblique plane facing the longitudinal direction, where the gradient of the first oblique plane decreases from a larger value of Kj to a smaller value of Ki from the middle to the edges, two adjacent first oblique planes are connected to each other using an arcuate surface, while the arc of the arcuate surface increases from a smaller value of Ri to a larger value of Rj from the middle to the edges; on the upper surface of the lower oblique sheet there is a second oblique plane opposite to the first oblique plane. However, the above devices do not allow accurate compensation to be made depending on the actual conditions of the work table at the time of compensating the work table of the sheet metal bending machine. Moreover, it is not convenient to fix and adjust the above-mentioned desktop deflection compensation devices.

The essence of the invention

1. Task

To solve the problems associated with the inconvenience of operating known devices for compensating deflection of a work table, the present invention provides a device for compensating deflection that is convenient for fixing a work table. By optimizing the design, the fastening structure of the device is relatively stable and not easily loosened over a long period of operation, and has enhanced fastening and adjustment effect.

2. Technical solutions

To solve this problem, the technical solutions of the present invention are as follows:

A deflection compensation device convenient for fixing a work table according to the present invention includes a stand, a pad and a fastening unit, said stand and pad are wedged, said pad is provided with a groove where lower oblique blocks are located in the direction of the length of the work table, adjacent lower oblique blocks connected to each other using connecting blocks, upper oblique blocks are installed above the lower oblique blocks; said fastening unit includes a fastening oblique block, a fixing element and ejecting elements; on said stand there is a sliding groove where said fastening oblique block is located, which has a larger diameter at the upper end than at the lower end, said locking element passes through the fastening oblique block, said pushing elements are mounted on the stand and push out the fastening oblique block from opposite sides mounting oblique block.

In one possible embodiment of the present invention, said lower oblique blocks and connecting blocks are connected to each other using screws.

In yet another exemplary embodiment of the present invention, a sliding groove is located in the center of said connecting block where screws are slidably mounted to secure the connecting block and the stand.

In yet another exemplary embodiment of the present invention, a shoulder hole is provided in the center of said fastening oblique block, said locking member being a fastening screw that extends through the shoulder hole in the fastening oblique block.

In yet another possible embodiment of the present invention, the shoulder end of said hole having a larger diameter is located in the fastening oblique block at the larger diameter end.

In yet another exemplary embodiment of the present invention, a shoulder hole is provided in the center of said fastening oblique block, said locking member being a fastening screw that extends through the shoulder hole in the fastening oblique block.

In yet another possible embodiment of the present invention, the shoulder end of said hole having a larger diameter is located in the fastening oblique block at the larger diameter end.

In another possible embodiment of the present invention, said oblique fastening block is made in the form of a truncated cone, said push-out elements are mounted on the edges of the stand in the width direction and abut against the oblique fastening block.

In one possible embodiment of the present invention, the contact surface of said push elements with the fastening oblique block is arcuate.

In yet another possible embodiment of the present invention, the top surface of said lower oblique block is a first oblique plane, the first oblique plane of adjacent lower oblique blocks having a different gradient.

In another possible embodiment of the present invention, the device further includes a plug head and a bearing seat, said plug head and a bearing seat are located at two ends of the pad, respectively, and said bearing seat is connected to the lower oblique block.

In yet another possible embodiment of the present invention, the device further includes a lead screw and an electric motor, said lead screw being connected on one side to the electric motor and on the other side connected to a bearing seat.

3. Technical result

Compared to existing analogues known from the prior art, the present invention has the following advantages:

(1) in the deflection compensation device convenient for fixing the work table according to the present invention, in the process of installing the work table deflection compensation device on the sheet bending machine, people often encounter problems such as inconvenience of installation, inconvenience of adjustment after installation and fastening of the work table deflection compensation device . By installing the fastening unit on the stand, the stand is connected to other units using a fixing element; the fastening oblique block rests against the fixing element on one side and interacts with the pushing elements on the other side; With the help of push elements, the fastening oblique block is compressed, the position of the oblique fastening block is adjusted, and the fastening oblique block is finely adjusted during its installation, thus the fastening structure is relatively stable and is not easily loosened over a long period of operation, and has an increased effect of fastening and adjustment ;

(2) in the deflection compensation device convenient for fixing the work table according to the present invention, by connecting the lower oblique blocks with connecting blocks, a plurality of lower oblique blocks can be combined into one and placed in the groove on the stand, wherein the upper oblique blocks and The lower oblique blocks are installed accordingly, making it easy to compensate the work table according to different requirements;

(3) in the deflection compensation device convenient for fixing the work table according to the present invention, the lower oblique blocks and connecting blocks are connected to each other by screws, which allows the lower oblique blocks of different gradients to be replaced, therefore, compensation can be realized depending on different requirements; while the screws in the center of the connecting block can slide in the sliding groove, then in the process of moving the lower oblique blocks, the connecting blocks also move, ensuring that the connecting blocks do not deviate and at the same time allowing the connecting blocks and the lower oblique blocks to slide;

(4) in the deflection compensation device convenient for fixing the work table according to the present invention, a shoulder hole is made in the center of the fastening oblique block, by jamming the locking element in the shoulder hole in the fastening oblique block, the position of the locking element is limited, which makes the fastening of the fixing element more effective;

(5) in the deflection compensation device convenient for fixing the work table according to the present invention, the fixing oblique block has a larger diameter at the upper end and a smaller diameter at the lower end. For ease of manufacture, the oblique fastening block can be made in the form of a truncated cone. At the end of the fastening oblique block, which has a larger diameter, there is a hole with a larger diameter, and at the end of the fastening oblique block, which has a smaller diameter, there is a hole with a smaller diameter. Thus, this hole is made in the form of a hole with a ledge, with the help of this hole the position of the fixing element is limited;

(6) in the deflection compensation device convenient for fixing the work table according to the present invention, the outer surface of the fastening oblique block is made with a transition diameter, that is, with a large diameter at the upper end and a smaller diameter at the lower end. Under the action of the pushing elements, that is, the pushing elements apply forces to the middle from both sides, these forces are applied to the fastening oblique block and are directed inward and upward. Under the influence of the forces exerted by the pushing elements and directed inward, the fastening oblique block becomes stable and is not subject to slight vibration. Under the action of upward forces, the oblique fastening block exerts upward forces on the fixing element. In this case, the locking element creates a counter force on the fastening oblique block, which makes the connection between the locking element and the fastening oblique block stable. During the installation of the device for compensating the deflection of the desktop, it is difficult to fix the fixing element and the unit located below, in this case it is often necessary to fine-tune the fixing element. By moving the pushing elements in the direction of the width of the stand, the fastening oblique block together with the locking element is moved in the direction of the width of the stand, thus, fine adjustment of the locking element is carried out, therefore, the locking element can be connected and assembled with the unit located under the stand;

(7) in the deflection compensation device convenient for fixing the work table according to the present invention, the contact surface of the ejecting elements with the fastening oblique block is arc-shaped, which avoids damage to the fastening oblique block and does not affect the force applied by the ejecting elements to the fastening oblique block ;

(8) in the deflection compensation device convenient for fixing the work table according to the present invention, by wedging the upper oblique block and the lower oblique block and placing them in the groove located on the cover plate, the upper oblique block and the cover plate are fixed; and the electric motor drives the lead screw, under the action of which the coupling shaft rotates, therefore, the lower oblique block is set in motion, thus compensating for the deflection of the working table, the process is simple and controllable.

Description of drawings

The following is a more detailed description of the technical aspects of the present invention in conjunction with the accompanying drawings and embodiments, however, it should be understood that the accompanying drawings are for interpretive purposes only and, therefore, are not intended to limit the scope of the present invention. Additionally, unless otherwise indicated, these drawings are intended to provide a conceptual illustration of the structural configuration described herein only and are not necessarily drawn to scale.

Fig. 1 - structural diagram of part of the connecting blocks of the deflection compensation device, convenient for fixing the work table;

Fig. 2 - top view of a deflection compensation device, convenient for fixing the work table;

Fig. 3 - structural diagram of the cross-section of the fastening unit of the deflection compensation device, convenient for fixing the work table;

Fig. 4 - design diagram of the section of the lining;

Fig. 5 - structural diagram of the fastening oblique block;

Fig. 6 - structural diagram of the ejector element.

In the drawings:

1. stand; 2. overlay; 21. lower oblique block; 22. upper oblique block; 23. connecting block; 3. fastening unit; 31. oblique fastening block; 32. fixing element; 33. ejector element; 4. plug head; 5. bearing seat; 6. lead screw; 7. electric motor; 8. shell; 9. rack.

Embodiments of the Invention

In the following detailed description of exemplary embodiments of the present invention, reference is made to the accompanying drawings, which form part of the description, in which exemplary embodiments of the present invention are shown by way of example. While these embodiments have been described in sufficient detail to enable those skilled in the art to practice the present invention, it is understood that other embodiments may be implemented and that various changes may be made to the present invention without departing from beyond the spirit and scope of the present invention. The following more detailed description of the embodiments of the present invention is not intended to limit the scope of the required invention, but only to provide examples and not to limit the description of the features and characteristics of the present invention, to suggest the optimal way to carry out the present invention and is sufficient to enable technical personnel to this area was able to realize the invention. Therefore, the scope of protection of the present invention is to be determined by the appended claims.

The following detailed description and exemplary embodiments of the present invention can be better understood in conjunction with the accompanying drawings, in which elements and features of the invention are indicated by symbols.

EXAMPLE 1

As shown in FIG. 1-6, this example provides a deflection compensation device convenient for fixing the work table, including a stand 1 and a fastening unit 3, the stand 1 is designed to support the components of the work table deflection compensation device. When installing a device for compensating the deflection of the desktop, for example, if it is necessary to install it in a sheet bending machine, you need to connect stand 1 to the sheet bending machine. A known connection method is to make a groove at the bottom of the bending machine and install mounting bolts in the groove to install the stand 1 on the bending machine. However, during the installation of the stand 1 on the sheet bending machine, it is difficult to adjust the position of the stand 1. By making a sliding groove on the stand 1 and installing the fastening unit 3 in the sliding groove, the stand 1 is fixed and adjusted. During the installation of the device for compensating the deflection of the working table on the sheet bending machine On the machine, people often encounter problems such as inconvenient installation, inconvenient adjustment after installation and fastening of the device for compensating the deflection of the working table. By installing the fastening unit 3 on the stand 1, the stand 1 is connected to other units using a locking element 32; the oblique fastening block 31 abuts the locking element 32 on one side and interacts with the pushing elements 33 on the other side; with the help of push-out elements 33, compression of the fastening oblique block 31, adjustment of the position of the fastening oblique block 31 and fine adjustment of the fastening oblique block 31 during its installation are carried out, thus, the fastening structure is relatively stable and is not easily weakened over a long period of operation, has an increased effect of fastening and regulation.

As shown in FIG. 3, the fastening unit 3 includes a fastening oblique block 31, a locking element 32 and push-out elements 33. The locking element 32 is designed to connect the stand 1 with the joint being joined; a fastening screw can be used as a fixing element and a threaded hole can be made in the unit being joined with stand 1. Due to the threaded connection of the mounting screw with the threaded hole, stand 1 is connected to other components. In the present application, a sheet metal bending machine is used as an example, and a threaded connection is made between a mounting screw and a threaded hole on the sheet metal bending machine. At one end of the sliding groove there is a round or square hole for inserting the fastening oblique block 31 and the locking element 32, the round or square hole on one side is connected to the sliding groove, which has a large internal cavity. A round or square hole is designed to insert the fastening oblique block 31 and the locking element 32, then the fastening oblique block 31 and the locking element 32 slide in the sliding groove, the locking element 32 comes out at one end from the sliding groove for connection with the joint unit of the sheet bending machine.

As shown in FIG. 5, the fastening oblique block 31 has a larger diameter at one end and a smaller diameter at the other end, and can be manufactured in the shape of a truncated cone. During installation, the mounting oblique block 31 should be installed so that the end with a larger diameter is at the top and the end with a smaller diameter is at the bottom. A shoulder hole is provided at the center of the fastening oblique block 31, and a larger diameter end of the shoulder hole is located at the larger diameter end of the fastening oblique block 31; and the shoulder end of the hole having a smaller diameter is located at the end of the fastening oblique block 31 having a smaller diameter. In the center of the fastening oblique block 31 there is a hole with a ledge, due to the wedging of the locking element 32 in the hole with a ledge in the fastening oblique block 31, the position of the locking element 32 is limited, which makes the fastening of the locking element 32 more effective. The fastening screw rests on the shoulder hole pad, which is the bearing surface between the fastening screw and the fastening oblique block 31, which makes their connection more stable, and is convenient for inserting the fastening oblique block 31 into the sliding groove located on the stand 1. During operation first assemble the mounting skew block 31 with the mounting screw and place it in place, then insert the mounting skew block 31 into the round or square hole located at one end of the sliding groove, then move the mounting screw, and therefore the mounting skew block 31, so that the mounting skew block 31 moved to the desired position.

The fastening oblique block 31 has a larger diameter at the upper end and a smaller diameter at the lower end. For ease of manufacture, the fastening oblique block 31 can be made in the form of a truncated cone. At the end of the fastening oblique block 31 with a large diameter there is a hole with a large diameter, and at the end of the fastening oblique block 31 with a smaller diameter there is a hole with a smaller diameter. Thus, this hole is made in the form of a hole with a shoulder, with the help of this hole the position of the fixing element 32 is limited. The outer surface of the fastening oblique block 31 is made with a transition diameter, that is, with a larger diameter at the upper end and a smaller diameter at the lower end. Under the action of the pushing elements 33, that is, the pushing elements 33 apply forces to the middle on both sides, these forces are applied to the fastening oblique block 31 and are directed inward and upward. Under the influence of the forces applied by the pushing elements 33 and directed inward, the fastening oblique block 31 becomes stable and does not oscillate easily. Under the action of upward forces, the fastening oblique block 31 exerts upward forces on the locking element 32. In this case, the locking member 32 exerts a counter force on the fastening oblique block 31, which makes the connection between the locking member 32 and the fastening oblique block 31 stable. In the process of installing the desktop deflection compensation device, it is difficult to fix the locking element 32 and the unit located below, in this case, it is often necessary to fine-adjust the locking element 32. By moving the pushing elements 33 in the direction of the width of the stand 1, the fastening oblique block 31 is moved together with the locking member 32 in the direction of the width of the stand 1, thus fine adjustment of the locking member 32 is carried out, therefore, the locking member 32 can be connected and assembled with the unit located under the stand 1.

As shown in FIG. 6, the pushing elements 33 are located on the stand 1 and push the fastening oblique block 31 from opposite sides of the fastening oblique block 31, in addition, the pushing elements 33 are located in the direction of the width of the stand 1, the contact surface of the pushing elements 33 with the fastening oblique block 31 is arcuate. The pushing member 33 can push the fastening oblique block 31 and perform tension and compression in the width direction of the stand 1, as shown in FIG. 6, a bushing is provided on the outside, and a cylinder with an arcuate end being an arcuate surface and connected to the thread of the bushing is installed inside the bushing. By rotating the end located away from the arcuate surface and the threaded connection, it is possible to control the movement of the cylinder in the direction of the width of the stand 1. The contact surface of the pushing elements 33 with the fastening oblique block 31 is arcuate, which avoids damage to the fastening oblique block 31 and does not affect on the force applied by the pushing elements 33 to the fastening oblique block 31.

EXAMPLE 2

A deflection compensation device convenient for fixing the work table in this embodiment is further described based on Example 1. As shown in FIG. 1-3, the device includes a stand 1, a pad 2, a fastening unit 3, a plug head 4, a bearing seat 5, a lead screw 6 and an electric motor 7. The stand 1 and the pad 2 are jammed, forming the general contour of the worker deflection compensation device table. As shown in FIG. 3 and 4, the lining 2 has a groove on the side close to the stand 1, the upper oblique block 22 and the lower oblique block 21 are installed in the groove, the lower oblique block 21 and the upper oblique block 22 are wedged and placed in the groove of the lining 2. The upper surface of the lower The oblique block 21 represents the first oblique plane, the first oblique planes of the adjacent lower oblique blocks 21 have different gradients. The plug head 4 and the bearing seat 5 are located on the two edges of the lining 2, respectively, the mentioned bearing seat 5 is connected to the lower oblique block 21. The plug head 4 is designed to seal the lining 2 and stand 1 on one side, and the bearing seat 5 is connected to the lower oblique block 21 through the connecting shaft, the lead screw 6 is connected on one side to the electric motor 7, and on the other side connected to the bearing seat 5. Due to the wedging of the upper oblique block 22 and the lower oblique block 21 and their placement in the groove located on the lining 2, the upper oblique block 22 and the overlay 2 are fixed; and the electric motor 7 drives the lead screw 6, under the action of which the coupling shaft rotates, therefore, the lower oblique block 21 is set in motion, thus compensating for the deflection of the working table, the process is simple and controllable.

As shown in FIG. 3, the fastening unit 3 includes a fastening oblique block 31, a locking element 32 and push-out elements 33. The locking element 32 is designed to connect the stand 1 with the joint being joined; a fastening screw can be used as a fixing element and a threaded hole can be made in the unit being joined with stand 1. Due to the threaded connection of the mounting screw with the threaded hole, stand 1 is connected to other components. In the present application, a sheet metal bending machine is used as an example, and a threaded connection is made between a mounting screw and a threaded hole on the sheet metal bending machine. At one end of the sliding groove there is a round or square hole for inserting the fastening oblique block 31 and the locking element 32, the round or square hole on one side is connected to the sliding groove, which has a large internal cavity. A round or square hole is designed to insert the fastening oblique block 31 and the locking element 32, then the fastening oblique block 31 and the locking element 32 slide in the sliding groove, the locking element 32 comes out at one end from the sliding groove for connection with the joint unit of the sheet bending machine.

As shown in FIG. 5, the fastening oblique block 31 has a larger diameter at one end and a smaller diameter at the other end, and can be manufactured in the shape of a truncated cone. During installation, the mounting oblique block 31 should be installed so that the end with a larger diameter is at the top and the end with a smaller diameter is at the bottom. A shoulder hole is provided at the center of the fastening oblique block 31, and a larger diameter end of the shoulder hole is located at the larger diameter end of the fastening oblique block 31; and the shoulder end of the hole having a smaller diameter is located at the end of the fastening oblique block 31 having a smaller diameter. In the center of the fastening oblique block 31 there is a hole with a ledge, due to the wedging of the locking element 32 in the hole with a ledge in the fastening oblique block 31, the position of the locking element 32 is limited, which makes the fastening of the locking element 32 more effective. The fastening screw rests on the shoulder hole pad, which is the bearing surface between the fastening screw and the fastening oblique block 31, which makes their connection more stable, and is convenient for inserting the fastening oblique block 31 into the sliding groove located on the stand 1. During operation first assemble the mounting skew block 31 with the mounting screw and place it in place, then insert the mounting skew block 31 into the round or square hole located at one end of the sliding groove, then move the mounting screw, and therefore the mounting skew block 31, so that the mounting skew block 31 moved to the desired position.

The fastening oblique block 31 has a larger diameter at the upper end and a smaller diameter at the lower end. For ease of manufacture, the fastening oblique block 31 can be made in the form of a truncated cone. At the end of the fastening oblique block 31 with a large diameter there is a hole with a large diameter, and at the end of the fastening oblique block 31 with a smaller diameter there is a hole with a smaller diameter. Thus, this hole is made in the form of a hole with a shoulder, with the help of this hole the position of the fixing element 32 is limited. The outer surface of the fastening oblique block 31 is made with a transition diameter, that is, with a larger diameter at the upper end and a smaller diameter at the lower end. Under the action of the pushing elements 33, that is, the pushing elements 33 apply forces to the middle on both sides, these forces are applied to the fastening oblique block 31 and are directed inward and upward. Under the influence of the forces applied by the pushing elements 33 and directed inward, the fastening oblique block 31 becomes stable and does not oscillate easily. Under the action of upward forces, the fastening oblique block 31 exerts upward forces on the locking element 32. In this case, the locking member 32 exerts a counter force on the fastening oblique block 31, which makes the connection between the locking member 32 and the fastening oblique block 31 stable. In the process of installing the desktop deflection compensation device, it is difficult to fix the locking element 32 and the unit located below, in this case, it is often necessary to fine-adjust the locking element 32. By moving the pushing elements 33 in the direction of the width of the stand 1, the fastening oblique block 31 is moved together with the locking member 32 in the direction of the width of the stand 1, thus fine adjustment of the locking member 32 is carried out, therefore, the locking member 32 can be connected and assembled with the unit located under the stand 1.

As shown in FIG. 6, the pushing elements 33 are located on the stand 1 and push the fastening oblique block 31 from opposite sides of the fastening oblique block 31, in addition, the pushing elements 33 are located in the direction of the width of the stand 1, the contact surface of the pushing elements 33 with the fastening oblique block 31 is arcuate. The pushing member 33 can push the fastening oblique block 31 and perform tension and compression in the width direction of the stand 1, as shown in FIG. 6, a bushing is provided on the outside, and a cylinder with an arcuate end being an arcuate surface and connected to the thread of the bushing is installed inside the bushing. By rotating the end located away from the arcuate surface and the threaded connection, it is possible to control the movement of the cylinder in the direction of the width of the stand 1. The contact surface of the pushing elements 33 with the fastening oblique block 31 is arcuate, which avoids damage to the fastening oblique block 31 and does not affect on the force applied by the pushing elements 33 to the fastening oblique block 31.

EXAMPLE 3

This example is based on examples 1 and 2 and further includes a shell 8 and a rail 9. The shell 8 consists of two parts in the vertical direction, which are connected to the stand 1 and the cover 2, respectively, and the rail 9 is connected to two parts of the shell 8 in vertical direction. During the movement of the lower oblique block, the distance from the pad 2 to the stand 1 changes in different places, thanks to the installation of the shell 8 outside the stand 1 and the pad 2 and the connection of the two parts of the shell 8 using the rail 9, it is possible to clearly measure the actual amount of compensation in different places of the worker table and perform more accurate compensation of desktop deflection.

EXAMPLE 4

This example is based on examples 1-3 and differs in that a separate type lower oblique block 21 is adopted, which consists of a plurality of lower oblique blocks 21, the width of the lower oblique block 21 corresponds to the width of the groove, however, a fit is made between the lower oblique block 21 and the groove with a gap, which makes it possible for the lower oblique block 21 to move in the future and does not affect the adjustment of the upper oblique block 22. Adjacent lower oblique blocks 21 are connected to each other using connecting blocks 23, and the lower oblique block 21 and the connecting block 23 are interconnected with using screws, which is convenient for assembling and disassembling the lower oblique blocks 21 and connecting blocks 23. By connecting the lower oblique blocks 21 using the connecting blocks 23, it is possible to combine a plurality of lower oblique blocks 21 into one and place them in the groove, while the upper oblique blocks 22 and lower oblique blocks 21 are installed accordingly, making it easy to compensate the work table according to different requirements. The connecting block 23 and the stand 1 are connected to each other by screws, and at the center of the connecting block 23 there is a sliding groove in which the screws can slide. The lower oblique blocks 21 and the connecting blocks 23 are connected to each other using screws, which allows the lower oblique blocks 21 of different gradients to be replaced, therefore, compensation can be made depending on different requirements; In this case, the screws in the center of the connecting block 23 can slide in the sliding groove, then in the process of moving the lower oblique blocks 21, the connecting blocks 23 also move, ensuring that the connecting blocks 23 do not deflect and simultaneously allowing the connecting blocks 23 and the lower oblique blocks 21 to slide.

Claims (11)

1. A device for compensating the deflection of the desktop, characterized in that it includes a stand (1), a pad (2) and a fastening unit (3); said stand (1) and pad (2) are jammed, said pad (2) has a groove in which lower oblique blocks (21) are located in the direction of the length of the work table, adjacent lower oblique blocks (21) are connected to each other using connecting blocks (23) screws, in the center of said connecting block (23) there is a sliding groove where sliding screws are installed to secure the connecting block (23) and the stand (1), upper oblique blocks (22) are installed above the lower oblique blocks (21); the upper surface of said lower oblique block (21) represents a first oblique plane, wherein the first oblique plane of adjacent lower oblique blocks (21) has a different gradient, said fastening unit (3) includes a fastening oblique block (31), a fixing element (32) and push-out elements (33); wherein the surface of contact of the said pushing elements (33) with the fastening oblique block (31) is made arcuate, on said stand (1) there is a sliding groove where said fastening oblique block (31) is located, which has a larger diameter at the upper end than at the lower end, said locking element (32) is a fastening screw passing through a shoulder hole located in the center of the fastening oblique block (31), wherein the end of said shoulder hole having a larger diameter is located in the fastening oblique block (31) at the end with large diameter, and said push elements (33) are installed on the stand (1) and push the fastening oblique block (31) from opposite sides of the fastening oblique block (31). 2. The device according to claim 1, characterized in that said oblique fastening block (31) is made in the form of a truncated cone, said pushing elements (33) are installed on the edges of the stand (1) in the width direction and abut against the oblique fastening block (31) . 3. The device according to claim 1, characterized in that it also includes a plug head (4) and a bearing seat (5), said plug head (4) and bearing seat (5) are located at two ends of the lining (2) accordingly, said bearing seat (5) is connected to the lower oblique block (21). 4. The device according to claim 1, characterized in that it also includes a lead screw (6) and an electric motor (7), said lead screw (6) is connected to the electric motor (7) on one side, and connected to the saddle on the other side bearing (5).