CN220162160U - Clamping device for gear pump production - Google Patents

Abstract

The utility model discloses a clamping device for gear pump production, which comprises a supporting component, wherein the supporting component comprises a supporting plate, a retaining plate is arranged above the supporting plate, threaded columns are vertically arranged on the side edges of the retaining plate, the threaded columns penetrate through a plate body, the end parts of the threaded columns are connected and inserted into the retaining plate through bearings, the plate body is connected with the supporting plate, the two retaining plates are distributed on two sides of a gear pump shell, a sliding clamping groove is formed in the lower side surface of the supporting plate, a bottom block is arranged below the supporting plate, a sliding clamping plate is fixedly connected to the upper side surface of the bottom block, clamping plates are fixedly connected to two opposite vertical side surfaces, and the sliding clamping plate is positioned in the sliding clamping groove; according to the gear pump shell polishing device, the supporting plate is arranged so as to simultaneously support two gear pump shells, and the supporting plate is movably arranged on the bottom block, so that after the last gear pump body is polished, the other gear pump shell can be rapidly moved to the position below the polishing rod, and the polishing efficiency of the gear pump shells is improved.

Description

Clamping device for gear pump production

Technical Field

The utility model relates to the technical field of gear pump shell polishing, in particular to a clamping device for gear pump production.

Background

The gear pump comprises casing, two gears and front and back end cover, when gear pump casing production, need polish the gear pump casing to form smooth medial surface, for the gear installation and form sealed space and provide convenience.

Most of the existing gear pump housing polishing modes are that a worker holds polishing devices and stretches into the gear pump housing to polish, under the polishing modes, gear pump housings need to be polished one by one, even if polishing equipment is utilized to polish the gear pump housings, the gear pump housings can only polish one by one, and polishing efficiency is low.

Disclosure of Invention

The utility model aims to provide a clamping device for gear pump production, which aims to solve the problem that the efficiency of replacing a gear pump shell by a clamping tool of the existing polishing equipment is low.

The utility model is realized in the following way: the utility model provides a clamping device is used in gear pump production, including holding in the palm and put the subassembly, hold in the palm and put the subassembly and put the board including holding in the palm, hold in the palm the top of putting the board and be provided with the board of keeping out, the side of keeping out the board is provided with the screw thread post perpendicularly, screw thread post penetration plate body sets up, the tip passes through the bearing connection and inserts in the keeping out the board, two keep out the board and distribute in the both sides of gear pump casing, the downside of holding in the palm the board is provided with the slip draw-in groove, the below is provided with the bottom block, the last side fixedly connected with slip cardboard of bottom block, two just are just vertical side equal fixedly connected with buckle board, the slip cardboard is located the slip draw-in groove, the buckle board is located the buckle inslot of bottom plate.

Preferably, the plate body is provided with four vertical plates, and the vertical plates are vertically arranged, and the screw thread column threads penetrate through the upper end of the vertical plates.

Preferably, the four vertical plates are equally divided into two groups, the two groups of vertical plates are respectively positioned at two ends of the supporting plate, the two vertical plates in each group are positioned on two parallel edges of the supporting plate, and the lower ends of the vertical plates are fixedly connected with the supporting plate.

Preferably, the plate body is provided with two second inclined supporting plates, the second inclined supporting plates are distributed on two sides of the supporting plate, the lower end of each second inclined supporting plate is sleeved on the convex shaft of the supporting plate, and the thread column threads penetrate through the upper end of each second inclined supporting plate.

Preferably, the side of the second inclined strut plate is provided with a first inclined strut plate, and the first inclined strut plate and the second inclined strut plate form a herringbone structure.

Preferably, the upper end of second diagonal bracing plate downside is provided with the sliding tray, and the sliding tray sets up along the length direction of second diagonal bracing plate, and the lateral wall is provided with the spacing hole of many eyes, and the spacing hole of many eyes is along the length direction evenly distributed of sliding tray, and sliding tray department is provided with the sliding tray, and connecting bolt runs through the sliding tray setting, and the tip stretches into in the spacing hole, and the upper end of first diagonal bracing plate passes through the connecting axle with the lower extreme of sliding tray and is connected.

Preferably, the lower ends of the two first inclined supporting plates are connected with a driving shaft in a sharing way, middle threads of the driving shaft penetrate through a threaded rod, the end part of the threaded rod is connected with an output shaft of the rotating motor, the end parts of the two vertical side walls of the sliding clamping groove are just opposite to two sliding holes, the driving shaft penetrates through the two sliding holes, the threaded rod penetrates through the end part of the supporting plate, and the rotating motor is arranged on the supporting plate.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the gear pump shell polishing device, the supporting plate is arranged so as to simultaneously support two gear pump shells, and the supporting plate is movably arranged on the bottom block, so that after the last gear pump body is polished, the other gear pump shell can be rapidly moved to the position below the polishing rod, and the polishing efficiency of the gear pump shells is improved.

2. The clamping turnover assembly is arranged, so that the gear pump housing can be lifted and turned over according to requirements, and the gear pump housing is prevented from being unfavorable for polishing due to the fact that the polishing rod is short.

Drawings

FIG. 1 is a first schematic construction of the present utility model;

FIG. 2 is a schematic structural view of the base plate of the present utility model;

fig. 3 is a schematic structural view of the support plate of the present utility model;

FIG. 4 is a schematic structural view of the sanding assembly of the present utility model;

FIG. 5 is a schematic view of the structure of the connecting ring plate and cross bar of the present utility model;

FIG. 6 is a first schematic structural view of the cradle assembly of the present utility model;

FIG. 7 is a second schematic structural view of the present utility model;

FIG. 8 is a second schematic structural view of the cradle assembly of the present utility model;

FIG. 9 is a schematic view of the structure of the support plate of the present utility model

FIG. 10 is a schematic view of the structure of the clamping and flipping mechanism of the present utility model;

fig. 11 is a schematic structural view of a second gusset of the present utility model.

In the figure: 1. a bottom plate; 11. a buckle groove; 2. a support assembly; 3. a support plate; 31. a buckle plate; 32. a lifting groove; 33. adjusting a screw; 34. a slide hole; 4. a polishing assembly; 41. a cross bar; 42. a limiting groove; 43. a slot; 44. a lifting block; 45. a threaded hole; 46. a through pipe; 47. a square groove; 5. polishing the rod; 51. connecting the annular plates; 52. polishing a motor; 53. a square plate; 6. a support plate; 61. a sliding clamping groove; 62. a sliding hole; 63. a protruding shaft; 7. a vertical plate; 71. a retaining plate; 72. a threaded column; 8. a bottom block; 81. a sliding clamping plate; 9. a clamping turnover mechanism; 91. a rotating electric machine; 92. a threaded rod; 93. a driving shaft; 94. a first diagonal strut; 95. a second diagonal brace plate; 96. a sliding groove; 97. a limiting hole; 98. and a sliding plate.

The specific embodiment is as follows:

in the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The following is further described with reference to the accompanying drawings and specific examples:

example 1

As shown in fig. 1, 2 and 4, a polishing and grinding device for a gear pump comprises a bottom plate 1, a supporting plate 3, a grinding assembly 4 and two sets of support assemblies 2. The bottom plate 1 is set to type structure, and inside two just to the lateral wall of bottom plate 1 all is provided with buckle groove 11, and the one end in buckle groove 11 sets up to the opening. The lower extreme fixedly connected with buckle board 31 of backup pad 3, buckle board 31 are located buckle inslot 11, and in limiting bolt screw thread runs through the lateral wall of bottom plate 1 inserts backup pad 3, make backup pad 3 place relatively bottom plate 1 stability. The polishing assembly 4 comprises a cross rod 41 and two symmetrically arranged polishing rods 5, wherein the upper end of each polishing rod 5 is provided with a connecting annular plate 51, the connecting annular plates 51 are connected with the cross rod 41, the upper end of each connecting annular plate is provided with a polishing motor 52, the connecting annular plates 51 are sleeved on the output shafts of the polishing motors 52, and the output shafts of the polishing motors 52 are connected with the polishing rods 5. The two groups of supporting components 2 are arranged on the bottom plate 1 and distributed on two sides of the supporting plate 3. When polishing the gear pump housing, a worker places two gear pump housings on the two sets of the bracket assemblies 2, respectively. The height of the cross bar 41 is adjusted so that the polishing rod 5 descends and extends into the gear pump housing, and the polishing motor 52 is started to work, so that the polishing rod 5 is forced to rotate and polish the side wall of the gear pump housing. In the polishing process, the supporting component 2 works to drive the gear pump shell to move, and the contact position of the gear pump shell and the polishing rod 5 is adjusted, so that the gear pump shell is polished. The two polishing rods 5 polish the two gear pump shells simultaneously, so that the current situation that the gear pump shells need to be polished one by one is changed, and the polishing efficiency of the gear pump shells is improved.

As shown in fig. 3 and 4, the upper end of the support plate 3 is provided with a lifting groove 32, the side wall of the lifting groove 32 is provided with a sliding hole 34, an adjusting screw 33 is arranged in the sliding hole 34, and the upper end of the adjusting screw 33 protrudes out of the support plate 3. The cross bar 41 is provided with a limiting groove 42 and a multi-eye slot 43, the limiting groove 42 is arranged along the length direction of the cross bar 41, the length is equal to the length of the cross bar 41, and the multi-eye slots 43 are uniformly distributed along the length direction of the cross bar 41. The cross bar 41 is sleeved with a through pipe 46, the hole wall of the through pipe 46 is fixedly connected with a limiting column, a limit bolt is arranged in a threaded penetrating manner, the limiting column is located in the limiting groove 42, and the lower end of the limit bolt is inserted into a certain slot 43. The lifting block 44 is fixedly connected to the through pipe 46, the end part of the lifting block 44 extends into the sliding hole 34, and the adjusting screw 33 is arranged through the lifting block 44 in a threaded manner. When the gear pump shell is polished, the adjusting screw 33 is rotated according to the requirement, and the height of the lifting block 44 is changed due to the threaded connection of the adjusting screw 33 and the lifting block 44, so that the polishing rod 5 is inserted into or separated from the gear pump shell, and the gear pump shell after the height is adjusted is stably placed at a certain height. When the diameter of the gear pump shell is large, when two gear pump shells cannot be polished simultaneously, a worker rotates the limit bolt, the limit of the cross rod 41 and the through pipe 46 is relieved, the cross rod 41 is pushed to move, one polishing rod 5 is close to the supporting plate 3, the other polishing rod 5 is far away from the supporting plate 3, the gear pump shell is polished by the polishing rod 5 far away from the supporting plate 3, the gear pump shell with the large diameter cannot be polished due to the position fixing of the polishing rod 5 is avoided, and the practicability of the polishing device is improved.

As shown in fig. 4 and 5, the length of the tube 46 is greater than the thickness of the lifting block 44 and is equal to the width of the support plate 3, and the outer diameter of the tube 46 is equal to the length of the lifting groove 32. The end parts of the cross bars 41 are provided with square grooves 47, the side edges of the connecting ring plates 51 are fixedly connected with square plates 53, and the square plates 53 are inserted into the square grooves 47 through connecting bolt connection.

As shown in fig. 6, the racking assembly 2 includes a racking plate 6 and four abutment plates 71. The support plate 6 is provided with four vertical plates 7, the vertical plates 7 are vertically arranged and equally divided into two groups, the two groups of vertical plates 7 are respectively positioned at two ends of the support plate 6, the two vertical plates 7 in each group are positioned on two parallel edges of the support plate 6, and the lower ends of the vertical plates 7 are fixedly connected with the support plate 6. The side of the retaining plate 71 is provided with a vertically arranged threaded post 72, the threaded post 72 is arranged in a threaded manner through the upper end of the vertical plate 7, and the end is inserted into the retaining plate 71 through bearing connection. Before the gear pump shell is polished, two gear pump shells are placed at two ends of the same supporting plate 6, and simultaneously the threaded columns 72 are rotated, so that the resisting plate 71 moves to the side edge of the gear pump shell, the gear pump shells are extruded, the gear pump shell is stably placed, and a certain gear pump shell is opposite to the polishing rod 5. After the gear pump housing is polished, the supporting plate 6 is controlled to move, so that the other gear pump housing moves to the lower part of the polishing rod 5 and is polished, the polished gear pump housing is taken down, and the gear pump housing to be polished is placed on the supporting plate 6. When the gear pump housing being polished is polished, the tooth support plate 6 is pushed to move, so that the gear pump housing to be polished moves to the lower part of the polishing rod 5. The steps are repeated, so that the polishing efficiency is prevented from being influenced by the occupied time of disassembling the gear pump shell.

As shown in fig. 6, the lower side of the supporting plate 6 is provided with a sliding clamping groove 61, the lower side is provided with a bottom block 8, a driving screw is arranged in the sliding clamping groove 61, the end of the driving screw is connected with an output shaft of a driving motor, the upper side of the bottom block 8 is fixedly connected with a sliding clamping plate 81, two opposite vertical sides are fixedly connected with a clamping plate 31, the sliding clamping plate 81 is positioned in the sliding clamping groove 61, a driving screw thread penetrates through the bottom block 8, and the clamping plate 31 is positioned in a clamping groove 11 of the bottom plate 1. The bottom plate 1 is internally provided with a driving screw, the end part of the driving screw is connected with the output shaft of another driving motor, and the threads of the driving screw penetrate through the bottom block 8, and the two driving screws are in vertical relation, so that the supporting plate 6 is controlled to move according to the grinding progress adjustment of the gear pump shell, and the relative position of the gear pump shell and the grinding rod 5 is adjusted. Through the work of two driving motors, two driving screws are controlled to rotate, and then the supporting plate 6 and the gear pump shell are driven to move, so that the contact between the gear pump shell and the polishing rod 5 is changed, and the side wall of the gear pump shell is comprehensively polished.

Example 2

As shown in fig. 1, 2 and 4, a polishing and grinding device for a gear pump comprises a bottom plate 1, a supporting plate 3, a grinding assembly 4 and two sets of support assemblies 2. The bottom plate 1 is set to type structure, and inside two just to the lateral wall of bottom plate 1 all is provided with buckle groove 11, and the one end in buckle groove 11 sets up to the opening. The lower extreme fixedly connected with buckle board 31 of backup pad 3, buckle board 31 are located buckle inslot 11, and in limiting bolt screw thread runs through the lateral wall of bottom plate 1 inserts backup pad 3, make backup pad 3 place relatively bottom plate 1 stability. The polishing assembly 4 comprises a cross rod 41 and two symmetrically arranged polishing rods 5, wherein the upper end of each polishing rod 5 is provided with a connecting annular plate 51, the connecting annular plates 51 are connected with the cross rod 41, the upper end of each connecting annular plate is provided with a polishing motor 52, the connecting annular plates 51 are sleeved on the output shafts of the polishing motors 52, and the output shafts of the polishing motors 52 are connected with the polishing rods 5. The two groups of supporting components 2 are arranged on the bottom plate 1 and distributed on two sides of the supporting plate 3. When polishing the gear pump housing, a worker places two gear pump housings on the two sets of the bracket assemblies 2, respectively. The height of the cross bar 41 is adjusted so that the polishing rod 5 descends and extends into the gear pump housing, and the polishing motor 52 is started to work, so that the polishing rod 5 is forced to rotate and polish the side wall of the gear pump housing. In the polishing process, the supporting component 2 works to drive the gear pump shell to move, and the contact position of the gear pump shell and the polishing rod 5 is adjusted, so that the gear pump shell is polished. The two polishing rods 5 polish the two gear pump shells simultaneously, so that the current situation that the gear pump shells need to be polished one by one is changed, and the polishing efficiency of the gear pump shells is improved.

As shown in fig. 3 and 4, the upper end of the support plate 3 is provided with a lifting groove 32, the side wall of the lifting groove 32 is provided with a sliding hole 34, an adjusting screw 33 is arranged in the sliding hole 34, and the upper end of the adjusting screw 33 protrudes out of the support plate 3. The cross bar 41 is provided with a limiting groove 42 and a multi-eye slot 43, the limiting groove 42 is arranged along the length direction of the cross bar 41, the length is equal to the length of the cross bar 41, and the multi-eye slots 43 are uniformly distributed along the length direction of the cross bar 41. The cross bar 41 is sleeved with a through pipe 46, the hole wall of the through pipe 46 is fixedly connected with a limiting column, a limit bolt is arranged in a threaded penetrating manner, the limiting column is located in the limiting groove 42, and the lower end of the limit bolt is inserted into a certain slot 43. The lifting block 44 is fixedly connected to the through pipe 46, the end part of the lifting block 44 extends into the sliding hole 34, and the adjusting screw 33 is arranged through the lifting block 44 in a threaded manner. When the gear pump shell is polished, the adjusting screw 33 is rotated according to the requirement, and the height of the lifting block 44 is changed due to the threaded connection of the adjusting screw 33 and the lifting block 44, so that the polishing rod 5 is inserted into or separated from the gear pump shell, and the gear pump shell after the height is adjusted is stably placed at a certain height. When the diameter of the gear pump shell is large, when two gear pump shells cannot be polished simultaneously, a worker rotates the limit bolt, the limit of the cross rod 41 and the through pipe 46 is relieved, the cross rod 41 is pushed to move, one polishing rod 5 is close to the supporting plate 3, the other polishing rod 5 is far away from the supporting plate 3, the gear pump shell is polished by the polishing rod 5 far away from the supporting plate 3, the gear pump shell with the large diameter cannot be polished due to the position fixing of the polishing rod 5 is avoided, and the practicability of the polishing device is improved.

As shown in fig. 4 and 5, the length of the tube 46 is greater than the thickness of the lifting block 44 and is equal to the width of the support plate 3, and the outer diameter of the tube 46 is equal to the length of the lifting groove 32. The end parts of the cross bars 41 are provided with square grooves 47, the side edges of the connecting ring plates 51 are fixedly connected with square plates 53, and the square plates 53 are inserted into the square grooves 47 through connecting bolt connection.

As shown in fig. 7, 8, 10, 11, the racking assembly 2 includes a racking plate 6 and a retaining plate 71. Two second inclined supporting plates 95 are arranged on the supporting plate 6 and distributed on two sides of the supporting plate 6, the lower ends of the second inclined supporting plates are sleeved on the convex shafts 63 of the supporting plate 6, first inclined supporting plates 94 are arranged on the side edges of the second inclined supporting plates 95, and the first inclined supporting plates 94 and the second inclined supporting plates 95 form a herringbone structure. The upper end of second diagonal brace 95 downside is provided with slide groove 96, slide groove 96 sets up along the length direction of second diagonal brace 95, the lateral wall is provided with the spacing hole 97 of many eyes, the spacing hole 97 of many eyes evenly distributed along the length direction of slide groove 96, slide groove 96 department is provided with slide plate 98, connecting bolt runs through slide cardboard 98 setting, and the tip stretches into in the spacing hole 97, the upper end of first diagonal brace 94 passes through the connecting axle with the lower extreme of slide plate 98 to be connected, can be according to the position of the relative second diagonal brace 95 of height-adjusting slide plate 98 of gear pump casing, under the circumstances that first diagonal brace 94 lower extreme is motionless, change the inclination of second diagonal brace 95, adjust the position of second diagonal brace 95 upper end, for the gear pump casing of centre gripping not co-altitude provides convenience. The lower ends of the two first inclined supporting plates 94 are connected with a driving shaft 93 in a sharing mode, middle threads of the driving shaft 93 penetrate through threaded rods 92, and the end portions of the threaded rods 92 are connected with an output shaft of the rotating motor 91. When the gear pump housing is higher and the height is greater than the height of the polishing rod 5, and the gear pump body needs to be turned over to finish polishing tasks, the rotary motor 91 works to control the threaded rod 92 to rotate, the position of the lower end of the first inclined supporting plate 94 is changed, the inclination angles of the first inclined supporting plate 94 and the second inclined supporting plate 95 are adjusted, the gear pump housing is enabled to ascend, after the gear pump housing ascends a certain distance, a worker applies a rotating force to the gear pump housing, the gear pump housing is enabled to rotate 180 degrees and then is placed on the supporting plate 6 again, and polishing tasks are finished by the polishing plate 5. The second inclined supporting plate 95, the first inclined supporting plate 94, the threaded rod 92, the driving shaft 93 and the rotating motor 91 form a clamping and overturning mechanism 9, and the clamping and overturning mechanism 9 can be arranged in two groups and are respectively arranged at two ends of the supporting plate 6 so as to simultaneously support two gear pump housings on the supporting plate 6.

As shown in fig. 10, the side of the abutment plate 71 is provided with a vertically disposed screw post 72, the screw post 72 is disposed to screw through the upper end of the second inclined strut plate 95, and the end is inserted into the abutment plate 71 through bearing connection. Before the gear pump shell is polished, two gear pump shells are placed at two ends of the same supporting plate 6, and simultaneously the threaded columns 72 are rotated, so that the resisting plate 71 moves to the side edge of the gear pump shell, the gear pump shells are extruded, the gear pump shell is stably placed, and a certain gear pump shell is opposite to the polishing rod 5. After the gear pump housing is polished, the supporting plate 6 is controlled to move, so that the other gear pump housing moves to the lower part of the polishing rod 5 and is polished, the polished gear pump housing is taken down, and the gear pump housing to be polished is placed on the supporting plate 6. When the gear pump housing being polished is polished, the tooth support plate 6 is pushed to move, so that the gear pump housing to be polished moves to the lower part of the polishing rod 5. The steps are repeated, so that the polishing efficiency is prevented from being influenced by the occupied time of disassembling the gear pump shell.

As shown in fig. 6, the lower side of the supporting plate 6 is provided with a sliding clamping groove 61, the lower side is provided with a bottom block 8, a driving screw is arranged in the sliding clamping groove 61, the end of the driving screw is connected with an output shaft of a driving motor, the upper side of the bottom block 8 is fixedly connected with a sliding clamping plate 81, two opposite vertical sides are fixedly connected with a clamping plate 31, the sliding clamping plate 81 is positioned in the sliding clamping groove 61, a driving screw thread penetrates through the bottom block 8, and the clamping plate 31 is positioned in a clamping groove 11 of the bottom plate 1. The bottom plate 1 is internally provided with a driving screw, the end part of the driving screw is connected with the output shaft of another driving motor, and the threads of the driving screw penetrate through the bottom block 8, and the two driving screws are in vertical relation, so that the supporting plate 6 is controlled to move according to the grinding progress adjustment of the gear pump shell, and the relative position of the gear pump shell and the grinding rod 5 is adjusted. Through the work of two driving motors, two driving screws are controlled to rotate, and then the supporting plate 6 and the gear pump shell are driven to move, so that the contact between the gear pump shell and the polishing rod 5 is changed, and the side wall of the gear pump shell is comprehensively polished. The end portions of the two vertical side walls of the slide clamping groove 61 are provided with two slide holes 62 in a facing manner, a driving shaft 93 is provided through the two slide holes 62, a threaded rod 92 is provided through the end portion of the supporting plate 6, and a rotating motor 91 is mounted on the supporting plate 6.

The above is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (7)

1. Clamping device is used in gear pump production, a serial communication port, including holding in the palm and putting subassembly (2), hold in the palm and put subassembly (2) including holding in the palm and put board (6), hold in the palm the top of putting board (6) and be provided with and keep out board (71), the side of keeping out board (71) is provided with perpendicularly and is provided with screw thread post (72), screw thread post (72) run through the plate body setting, the tip inserts in keeping out board (71) through the bearing connection, the plate body is connected with hold in the palm board (6), two keep out board (71) distribute in the both sides of gear pump shell, the downside of holding in the palm board (6) is provided with slip draw-in groove (61), the below is provided with foundation block (8), the upside fixedly connected with slip cardboard (81) of foundation block (8), two just are all fixedly connected with buckle board (31) to vertical side, slip cardboard (81) are located slip draw-in groove (61), buckle board (31) buckle is located groove (11) of bottom plate (1).

2. The clamping device for gear pump production according to claim 1, wherein the plate body is provided with four vertical plates (7), the vertical plates (7) are vertically arranged, and the screw thread columns (72) are arranged in a threaded manner penetrating through the upper ends of the vertical plates (7).

3. The clamping device for gear pump production according to claim 2, wherein four vertical plates (7) are equally divided into two groups, the two groups of vertical plates (7) are respectively positioned at two ends of the supporting plate (6), the two vertical plates (7) in each group are positioned on two parallel edges of the supporting plate (6), and the lower ends of the vertical plates (7) are fixedly connected with the supporting plate (6).

4. The clamping device for gear pump production according to claim 1, wherein the plate body is provided with second inclined supporting plates (95), the second inclined supporting plates (95) are arranged at two sides of the supporting plate (6), the lower ends of the second inclined supporting plates are sleeved on the protruding shafts (63) of the supporting plate (6), and the thread columns (72) penetrate through the upper ends of the second inclined supporting plates (95) in a threaded mode.

5. The clamping device for gear pump production according to claim 4, wherein a first inclined supporting plate (94) is arranged on the side edge of the second inclined supporting plate (95), and the first inclined supporting plate (94) and the second inclined supporting plate (95) form a herringbone structure.

6. The clamping device for gear pump production according to claim 5, wherein a sliding groove (96) is formed in the upper end of the lower side face of the second inclined supporting plate (95), the sliding groove (96) is formed in the direction of the length of the second inclined supporting plate (95), multi-hole limiting holes (97) are formed in the side wall of the sliding groove, the multi-hole limiting holes (97) are uniformly distributed in the direction of the length of the sliding groove (96), sliding plates (98) are arranged at the positions of the sliding groove (96), connecting bolts penetrate through the sliding plates (98), the end portions of the connecting bolts extend into the limiting holes (97), and the upper end of the first inclined supporting plate (94) is connected with the lower end of the sliding plates (98) through connecting shafts.

7. The clamping device for gear pump production according to claim 6, wherein the lower ends of the two first inclined supporting plates (94) are connected with a driving shaft (93) in a sharing mode, middle threads of the driving shaft (93) penetrate through a threaded rod (92), the end portions of the threaded rod (92) are connected with an output shaft of a rotating motor (91), the end portions of two vertical side walls of the sliding clamping groove (61) are opposite to two sliding holes (62), the driving shaft (93) penetrates through the two sliding holes (62), the threaded rod (92) penetrates through the end portion of the supporting plate (6), and the rotating motor (91) is mounted on the supporting plate (6).