CN106273221B

CN106273221B - A kind of generator shock pad production system

Info

Publication number: CN106273221B
Application number: CN201610718514.XA
Authority: CN
Inventors: 刘春红
Original assignee: CHONGQING LINGFENG RUBBER PRODUCTS Co Ltd
Current assignee: CHONGQING LINGFENG RUBBER PRODUCTS Co Ltd
Priority date: 2016-08-25
Filing date: 2016-08-25
Publication date: 2018-04-13
Anticipated expiration: 2036-08-25
Also published as: CN106273221A

Abstract

The present invention provides a kind of generator shock pad production system, generator shock pad includes the first beam iron plate and the second beam iron plate, and it is connected to the special gelatin between the first beam iron plate and the second beam iron plate, production system includes supporting mechanism, mould support plate, die ontology, die cover plate and injection (mo(u)lding) machine, mould support plate, the mold mechanism that die ontology and die cover plate are formed is installed on supporting mechanism, supporting mechanism and mold mechanism can be pushed out in the mold cavity of injection (mo(u)lding) machine come with retract, thus the first beam iron plate that the first recess is fixedly mounted on die ontology and the second beam iron plate that the second recess is fixedly mounted is allowed to pass through special gelatin injection connection.The generator shock pad that production system of the present invention makes, the connection between the first beam iron plate and the second beam iron plate is very firm, and the acid resistance and oil resistant corrosivity of special gelatin are very strong, its performance meets the damping requirement of generator.

Description

Generator shock pad production system

Technical Field

The invention relates to the technical field of generator damping, in particular to a generator damping pad production system.

Background

With the rapid development of modern industry, the power of the generator is larger and larger, and the damage of vibration and noise is more and more prominent, and the method widely used at present is to utilize a shock absorber made of rubber materials and framework materials (such as metal, fiber, engineering plastics and the like) or special rubber viscoelastic high-damping materials to eliminate the vibration impact of a vibration source and absorb noise. The generator generates a large amount of heat due to long-term work, the rubber for the shock pad of the generator is required to have high strength, high elongation, high wear resistance and high temperature resistance, and thermal aging is avoided. Therefore, a new generator damper pad is urgently required to appear.

Disclosure of Invention

Aiming at the technical problem that the performance of damping rubber in the prior art cannot meet the requirement of a generator yet, so that the damping performance of a damping pad of the generator cannot meet the expected damping requirement, the inventor of the invention finds out through research that a novel generator damping pad production system is provided, and the generator damping pad produced by the production system has good damping performance and can meet the actual damping requirement of the generator.

In order to solve the technical problems, the invention adopts the following technical scheme:

a generator shock pad production system comprises a first shock pad iron sheet, a second shock pad iron sheet and special glue connected between the first shock pad iron sheet and the second shock pad iron sheet, and comprises a supporting mechanism, a mold supporting plate, a mold body, a mold cover plate and an injection molding machine; wherein,

the supporting mechanism comprises a supporting bedplate and supporting barrier strips, the supporting barrier strips are fixedly connected to the left side and the right side of the supporting bedplate, and a plurality of supporting grooves are formed in the tail sections of the lower sides of the supporting barrier strips;

the die supporting plate is provided with an upper surface and a lower surface which are oppositely configured, the lower surface is fixedly connected to the supporting bedplate, and a trapezoidal protruding platform is integrally formed on the upper surface;

the mould body comprises a plurality of forming mould units, a first mould stop block and a second mould stop block, the first mould stop block and the second mould stop block are respectively and fixedly connected with the front side and the rear side of a mould supporting plate, the plurality of forming mould units are detachably arranged between the first mould stop block and the second mould stop block in parallel, the bottoms of the plurality of forming mould units, the first mould stop block and the second mould stop block are respectively and closely matched with a trapezoidal protruding platform on the upper surface of the mould supporting plate, each forming mould unit is a strip-shaped trapezoidal protruding structure matched with the upper surface of the mould supporting plate, the left end and the right end of the strip-shaped trapezoidal protruding structure are respectively and fixedly connected with a handle convenient to disassemble and assemble, the handle can be placed in a supporting groove at the tail section of the lower side of the supporting stop bar, and a first dent for fixedly installing a first shock absorption iron pad sheet is arranged on the upper surface of each, the lower surface of the forming die unit is provided with a second recess fixedly provided with a second shock-absorbing shim iron sheet, the first recess and the second recess are formed by combining two adjacent forming die units, the parts at the bottoms of the first recess and the second recess are hollowed to ensure that the first recess and the second recess are communicated, the upper surface of the adjacent forming die unit is provided with two first recesses, the lower surface of the adjacent forming die unit is provided with two second recesses, the two first recesses and the two second recesses are respectively and symmetrically arranged at the left side and the right side of the trapezoidal protruding structure, one part of the recesses are positioned on a trapezoidal plane, the other part of the recesses are positioned on a trapezoidal slope, the upper surface of the forming die unit is also provided with a feeding hole, the feeding hole is positioned at the adjacent position of the two adjacent forming die units and is arranged between the two symmetrical first recesses, and is communicated with corresponding die structures hollowed at the bottoms of the first recess and the second recess on the left side and the right side;

the die cover plate is provided with an outer surface and an inner surface which are oppositely configured, the inner surface is a trapezoidal protruding structure which is tightly matched with the upper surface of the die body, the inner surface of the trapezoidal protruding structure is provided with an avoiding groove, a positioning hole and a glue injection through hole which penetrates through the inner surface and the outer surface of the die cover plate, the glue injection through hole is aligned with a material inlet hole on the upper surface of the forming die unit, the avoiding groove is suitable for accommodating a protruding structure of a first shock-absorbing sizing block sheet which is fixedly arranged in a first recess, the positioning hole is suitable for matching and positioning a device which is fixedly connected with a first die stop block and a second die stop block, and the left side wall and the right side wall of the die cover plate are respectively provided with;

the injection molding machine is provided with a mold cavity, a push-pull mechanism and a PLC (programmable logic controller), wherein the mold cavity is suitable for accommodating a supporting mechanism and fixing a mold mechanism which is composed of a mold supporting plate, a mold body and a mold cover plate and is arranged on the mold cavity, the push-pull mechanism is suitable for pushing and pulling back the supporting mechanism which is accommodated in the mold cavity and is fixed with the mold mechanism, when the mold mechanism is pulled back into the mold cavity, an injection nozzle on the injection molding machine is opposite to an adhesive injection through hole on the mold cover plate and is subjected to injection molding, a first shock-absorbing sizing sheet fixedly arranged at a first sunken part and a second shock-absorbing sizing sheet fixedly arranged at a second sunken part are connected through injection molding of special adhesive, and the mold mechanism is pushed out of the mold cavity after the injection molding.

Compared with the prior art, the generator shock pad production system provided by the invention comprises a support mechanism, a mold supporting plate, a mold body, a mold cover plate and an injection molding machine, wherein the support mechanism supports and fixes the mold mechanism, the injection molding machine performs injection molding on the mold mechanism pulled back into a mold cavity to form the generator shock pad, specifically, a plurality of molding mold units are arranged on the mold body of the mold mechanism, the molding mold units are of strip-shaped trapezoidal protrusion structures, a first recess for fixedly installing a first shock pad iron sheet is arranged on the upper surface of each molding mold unit, a second recess for fixedly installing a second shock pad iron sheet is arranged on the lower surface of each molding mold unit, the first recess and the second recess are formed by combining two adjacent molding mold units, and the parts at the bottoms of the first recess and the second recess are hollowed corresponding to the mold structure to enable the first recess and the second recess to be communicated, the upper surface of each forming die unit is also provided with a feeding hole, the feeding holes are positioned at the adjacent positions of the two adjacent forming die units and are arranged between the two symmetrical first recesses, and the feeding holes are communicated with the corresponding die structures hollowed at the bottoms of the first recesses and the second recesses of the left side and the right side, so that in the injection molding process, special rubber materials entering the feeding holes can enter the die structures hollowed at the left side and the right side simultaneously, the first damping shim iron sheets and the second damping shim iron sheets fixedly mounted on the first recesses and the second recesses of the left side and the right side are connected in an injection molding mode and are connected by special rubber, therefore, the connection between the first damping shim iron sheets and the second damping shim iron sheets is very firm, the acid resistance and the oil corrosion resistance of rubber are very strong, the requirements of a generator can be met, and the damping performance of the rubber can meet the expected damping requirements.

Further, the special rubber is acrylate rubber or ethylene propylene diene monomer rubber.

Further, the injection molding of the injection molding machine specifically comprises rubber material melting, injection, pressure maintaining and cooling molding, wherein the rubber material melting conditions are temperature 122-.

Further, the upper surface integrated into one piece of mould layer board has first trapezoidal protruding platform and the trapezoidal protruding platform of second, the junction of first trapezoidal protruding platform and the trapezoidal protruding platform of second is smooth transition's plane slot, the internal surface of mould apron and forming die unit also shaping have two trapezoidal protruding platforms that correspond with first trapezoidal protruding platform and the trapezoidal protruding platform of second.

Furthermore, two ends of the first mold stop block are fixed on the front side of the mold supporting plate through bolts, and a pin shaft fixedly connected with the mold supporting plate is arranged in the middle of the first mold stop block; the two ends of the second mold stop block are fixed on the rear side of the mold supporting plate through pin shafts, and a bolt fixedly connected with the mold supporting plate is arranged in the middle of the second mold stop block.

Furthermore, be located the first depressed part on trapezoidal slope and be equipped with first fixed orifices, be equipped with on the first shock pad iron sheet with the first knob suddenly of first fixed orifices block fit, be located the second depressed part on trapezoidal slope and be equipped with the second fixed orifices, be equipped with on the second shock pad iron sheet with the second knob suddenly of second fixed orifices block fit.

Further, the push-pull mechanism in the injection molding machine is a push-pull air cylinder fixedly connected with the supporting mechanism, and the push-pull air cylinder is electrically connected with the PLC.

Drawings

Fig. 1 is a schematic structural diagram of a generator shock pad provided by the invention.

FIG. 2 is a schematic structural diagram of a generator vibration damping pad production system provided by the present invention.

Fig. 3 is a structural schematic view of the support mechanism, the mold blade, and the mold body in fig. 2.

Fig. 4 is a schematic structural view of the mold cover in fig. 2.

In the figure, 1, a generator shock pad; 11. a first shim plate; 111. a first knob; 12. a second shim plate; 121. a second knob; 13. special glue; 2. a support mechanism; 21. a support platen; 22. supporting the barrier strip; 23. a support groove; 3. a mold pallet; 31. an upper surface; 32. a lower surface; 33. a trapezoidal protruding platform; 4. a mold body; 41. a molding die unit; 411. a trapezoidal protrusion structure; 412; a grip; 413. a first recess; 414. a feeding hole; 415. a first fixing hole; 42. a first mold stop; 43. a second mold stop; 5. a mold cover plate; 51. an avoidance groove; 52. positioning holes; 53. injecting glue through holes; 54. a support pillar; 6. an injection molding machine; 61. and (4) forming a mold cavity.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further explained below by combining the specific drawings.

In the description of the present invention, it is to be understood that the terms "longitudinal", "radial", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1-4, the present invention provides a generator shock pad production system, where the generator shock pad 1 includes a first shock pad iron sheet 11, a second shock pad iron sheet 12, and a special glue 13 connected between the first shock pad iron sheet 11 and the second shock pad iron sheet 12, and the production system includes a support mechanism 2, a mold supporting plate 3, a mold body 4, a mold cover plate 5, and an injection molding machine 6; wherein,

the supporting mechanism 2 comprises a supporting bedplate 21 and supporting barrier strips 22, the supporting barrier strips 22 are fixedly connected to the left side and the right side of the supporting bedplate 21, and a plurality of supporting grooves 23 are formed in the tail sections of the lower sides of the supporting barrier strips 22;

the mould supporting plate 3 is provided with an upper surface 31 and a lower surface 32 which are oppositely arranged, the lower surface 32 is fixedly connected on the supporting bedplate 21, and a trapezoidal protruding platform 33 is integrally formed on the upper surface 31;

the mold body 4 comprises a plurality of forming mold units 41, a first mold stopper 42 and a second mold stopper 43, wherein the first mold stopper 42 and the second mold stopper 43 are respectively fixedly connected to the front side and the rear side of the mold supporting plate 3, the plurality of forming mold units 41 are detachably mounted between the first mold stopper 42 and the second mold stopper 43 in parallel, the bottoms of the plurality of forming mold units 41, the first mold stopper 42 and the second mold stopper 43 are respectively tightly matched with a trapezoidal protruding platform 33 on the upper surface of the mold supporting plate, each forming mold unit 41 is a strip-shaped trapezoidal protruding structure 411 matched with the upper surface of the mold supporting plate, the left end and the right end of the strip-shaped trapezoidal protruding structure 411 are respectively and fixedly connected with a handle 412 convenient to disassemble and assemble, the handle 412 can be placed in a supporting groove 23 at the end section of the lower side of a supporting bar 22, and a first recess 413 for fixedly mounting a first cushion iron sheet 11 is arranged on the upper surface of each forming mold unit 41 A second recess (not shown) for fixedly mounting the second shock-absorbing shim plate 12 is provided on the lower surface of the forming mold unit 41, the second recess is substantially symmetrically arranged with the first recess, the first recess 413 and the second recess are formed by combining two adjacent forming mold units 41, the bottom portions of the first recess 413 and the second recess are hollowed out corresponding to the mold structure so that the first recess 413 and the second recess are communicated, two first recesses 413 are provided adjacent to the upper surface of the forming mold unit 41, two second recesses are provided adjacent to the lower surface of the forming mold unit 41, the two first recesses 413 and the two second recesses are symmetrically provided on the left side and the right side of the trapezoidal protruding structure 411, respectively, and a part of the recesses are located on the trapezoidal plane and the other part of the recesses are located on the trapezoidal slope, the upper surface of the forming mold unit 41 is further provided with a feeding hole 414, the feeding hole 414 is located at the adjacent position of two adjacent forming mold units 41, is arranged between two symmetrical first recesses 413, and is communicated with the corresponding mold structures hollowed at the bottoms of the first recesses 413 and the second recesses on the left side and the right side;

the die cover plate 5 is provided with an outer surface and an inner surface which are oppositely configured, the inner surface is a trapezoidal protruding structure which is tightly matched with the upper surface of the die body 4, the inner surface of the trapezoidal protruding structure is provided with an avoiding groove 51, a positioning hole 52 and a glue injection through hole 53 which penetrates through the inner surface and the outer surface of the die cover plate, the glue injection through hole 53 is aligned with a feeding hole 414 on the upper surface of the forming die unit 41, the avoiding groove 51 is suitable for accommodating a protruding structure of the first shock-absorbing shim iron sheet 11 which is fixedly arranged in the first recess 413, the positioning hole 52 is suitable for matching and positioning a device which is fixedly connected with the first die stop block 42 and the second die stop block 43, and the left side wall and the right side wall of the die cover plate 5 are respectively provided with two supporting columns 54;

the injection molding machine 6 is provided with a mold cavity 61, a push-pull mechanism and a PLC (programmable logic controller), the mold cavity 61 is suitable for accommodating the supporting mechanism 2 and fixing the mold mechanism which is formed by the mold supporting plate 3, the mold body 4 and the mold cover plate 5, the push-pull mechanism is suitable for pushing and pulling back the supporting mechanism 2 which is accommodated in the mold cavity and is fixed with the mold mechanism, when the mold mechanism is pulled back into the mold cavity, an injection nozzle on the injection molding machine 6 is opposite to a glue injection through hole 53 on the mold cover plate 5 and is subjected to injection molding, a first shock-absorbing sizing sheet 11 fixedly arranged at the first recess 413 and a second shock-absorbing sizing sheet 12 fixedly arranged at the second recess are connected through special glue injection, and the mold mechanism is pushed out of the mold cavity after the injection molding.

As a specific example, the special rubber 13 is acrylate rubber or ethylene propylene diene monomer rubber, and the main chain of the special rubber is composed of chemically stable saturated hydrocarbon, and only the side chain contains unsaturated double bonds, so that the special rubber has excellent ozone resistance, heat resistance, weather resistance, acid resistance, oxidation resistance and corrosion resistance, has excellent vulcanization characteristics, can absorb a large amount of filler and oil, and has little influence on the characteristics, and the performance of the generator shock pad prepared from the special rubber meets the shock absorption requirement of a generator.

As a specific embodiment, the injection molding of the injection molding machine 6 specifically comprises three stages of sizing material melting, injection, pressure maintaining and cooling molding, wherein the sizing material melting condition comprises a temperature of 122-. By adopting the injection molding mode and conditions in the embodiment, the special glue can be completely melted, the mobility of a polymer chain in the glue body is relatively good, and the polymer chain can penetrate and wind each other, so that the connection strength between the first shock-absorbing sizing block sheet and the second shock-absorbing sizing block sheet in the welding area is increased, the pressure is continuously applied in the pressure maintaining stage, the melted glue body can be compacted and the glue material density is increased, the melted glue body can be solidified to certain rigidity through cooling molding, and the deformation of a glue material product caused by external force after demolding can be avoided. The injection molding machine 6 may be a rubber injection molding machine known to those skilled in the art.

As a specific embodiment, please refer to fig. 2 and fig. 3, a first trapezoidal protruding platform and a second trapezoidal protruding platform, that is, two trapezoidal protruding platforms 33, are integrally formed on the upper surface 31 of the mold pallet 3, a connection position of the first trapezoidal protruding platform and the second trapezoidal protruding platform is a smooth transition plane groove, that is, a section of horizontal line is formed at a connection position of the bottom of the trapezoidal slope, the section of horizontal line forms a section of plane groove relative to the trapezoidal protruding platform, and two trapezoidal protruding platforms corresponding to the first trapezoidal protruding platform and the second trapezoidal protruding platform are also formed on the inner surface of the mold cover plate 5 and the forming mold unit 41, that is, the inner surfaces of the forming mold unit 41 and the mold cover plate 5 are the same as the upper surface 31 of the mold pallet 3 in shape and structure. In this embodiment, two trapezoidal protruding platforms 33 are integrally formed on the upper surface 31 of the mold pallet 3, so that more first and second shock-absorbing shim plates 11 and 12 can be placed on the first and second recesses 413 and 12 of the forming mold unit 41, thereby improving the injection molding production efficiency and reducing the manufacturing cost. Certainly, the trapezoidal slope section of the trapezoidal protruding platform is also a straight line, and can also be designed into a circular arc shape which is in smooth transition with the surface of the platform, so that the mold supporting plate 3, the mold body 4 and the mold cover plate 5 can be combined more tightly or compactly.

As a specific embodiment, please refer to fig. 2 and 3, two ends of the first mold stopper 42 are fixed on the front side of the mold supporting plate 3 by bolts, and a pin fixedly connected with the mold supporting plate 3 is arranged in the middle of the first mold stopper 42; the two ends of the second mold block 43 are fixed at the rear side of the mold supporting plate 3 through pin shafts, and the middle part of the second mold block 43 is provided with bolts fixedly connected with the mold supporting plate 3, so that the first mold block 42 and the second mold block 43 can be fixedly connected with the front side and the rear side of the mold supporting plate 3, and the positioning holes 52 on the mold cover plate 5 are just suitable for being matched with the bolts fixedly connected with the first mold block 42 and the second mold block 43, namely, the bolts are accommodated in the positioning holes 52, so that the contact matching of the mold cover plate 5 and the first mold block 42 and the second mold block 43 is realized. Of course, the first mold stop 42 and the second mold stop 43 may be fixedly connected to the mold pallet 3 in other manners.

As a specific example, referring to fig. 1 to 3, a first fixing hole 415 is formed at a first recess 413 on the trapezoidal slope (only one first recess and one first fixing hole are shown in fig. 2 and 3, and the design of the other mold units is the same), a first protrusion 111 engaged with the first fixing hole 415 is provided on the first shock-absorbing shim plate 11, a second fixing hole (not shown) is formed at a second recess on the trapezoidal slope, the second fixing hole is substantially symmetrical to the first fixing hole 415, a second protrusion 121 engaged with the second fixing hole is provided on the second shock-absorbing shim plate 12, so that when the first shock-absorbing shim plate 11 is fixedly installed at the first recess 413, the first protrusion 111 can be further engaged in the first fixing hole 415, and when the second shock-absorbing shim plate 12 is fixedly installed at the second recess, the second protrusion button 121 may be further engaged in the second fixing hole, thereby achieving stable installation of the first and second shock-absorbing shim pieces 11 and 12. Particularly, when the second shock-absorbing shim plate 12 is installed, since the second recess is formed in the lower surface of the forming die unit 41, the second shock-absorbing shim plate 12 needs to be installed and fixed after the forming die unit 41 is turned over, and the first shock-absorbing shim plate 11 is installed after the forming die unit 41 is turned over after the installation is completed, so that the snap-fit design of the second fixing hole and the second protruding button 121 is very important. Of course, the first and second shock-absorbing shim plates 11 and 12 can also be directly and respectively clamped and fixedly installed through the first and second recesses 413 and 12. In this embodiment, the first protrusion 111 and the second protrusion 121 are nuts respectively disposed on the first shim plate 11 and the second shim plate 12, and the screw for connecting the nuts is received by the avoiding slot 51 disposed on the mold cover 5.

As a specific embodiment, the push-pull mechanism in the injection molding machine 6 is a push-pull cylinder fixedly connected with the support mechanism 2, so that the support mechanism 2 and the mold mechanism fixed thereon and composed of the mold supporting plate 3, the mold body 4 and the mold cover plate 5 can be pushed and pulled back, that is, the generator shock pad is pushed out of the mold cavity after being injection molded, and when an operator takes out the generator shock pad after injection molding and re-installs the first shock pad iron sheet 11 and the second shock pad iron sheet 12 to be injection molded, the push-pull cylinder draws the generator shock pad back to the mold cavity for continuous injection molding; meanwhile, the push-pull air cylinder is electrically connected with the PLC, so that the push-pull air cylinder can be automatically controlled in the push-pull stroke and the pull-back stroke through the PLC, and the control efficiency and the flexibility of the injection molding machine 6 are improved.

Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.

Claims

1. The generator shock pad production system is characterized in that the generator shock pad (1) comprises a first shock pad iron sheet (11), a second shock pad iron sheet (12) and special glue (13) connected between the first shock pad iron sheet (11) and the second shock pad iron sheet (12), and the production system comprises a supporting mechanism (2), a mold supporting plate (3), a mold body (4), a mold cover plate (5) and an injection molding machine (6); wherein,

the supporting mechanism (2) comprises a supporting bedplate (21) and supporting barrier strips (22), the supporting barrier strips (22) are fixedly connected to the left side and the right side of the supporting bedplate (21), and a plurality of supporting grooves (23) are formed in the tail sections of the lower sides of the supporting barrier strips (22);

the mould supporting plate (3) is provided with an upper surface (31) and a lower surface (32) which are oppositely arranged, the lower surface (32) is fixedly connected to the supporting bedplate (21), and the upper surface (31) is integrally formed with a trapezoidal protruding platform (33);

the die body (4) comprises a plurality of forming die units (41), a first die stop block (42) and a second die stop block (43), the first die stop block (42) and the second die stop block (43) are respectively and fixedly connected to the front side and the rear side of the die supporting plate (3), the plurality of forming die units (41) are parallelly and detachably mounted between the first die stop block (42) and the second die stop block (43), the bottoms of the plurality of forming die units (41), the first die stop block (42) and the second die stop block (43) are respectively and closely matched with a trapezoidal protrusion platform (33) on the upper surface of the die supporting plate (3), each forming die unit (41) is a strip-shaped trapezoidal protrusion structure (411) matched with the upper surface of the die supporting plate (3), the left end and the right end of each strip-shaped trapezoidal protrusion structure (411) are respectively and fixedly connected with a handle (412) convenient to disassemble and assemble, the handle (412) can be placed in a supporting groove (23) at the tail section of the lower side of the supporting barrier strip (22), a first recess (413) for fixedly mounting a first shock-absorbing shim sheet (11) is arranged on the upper surface of the forming die unit (41), a second recess for fixedly mounting a second shock-absorbing shim sheet (12) is arranged on the lower surface of the forming die unit (41), the first recess (413) and the second recess are formed by combining two adjacent forming die units (41), the parts at the bottoms of the first recess (413) and the second recess are hollowed corresponding to die structures so that the first recess (413) and the second recess are communicated, two first recesses (413) are arranged on the upper surface of the adjacent forming die unit (41), two second recesses are arranged on the lower surface of the adjacent forming die unit (41), and the two first recesses (413) and the two second recesses are symmetrically arranged on the left side and the right side of the trapezoidal protruding structure (411), one part of the depressions is positioned on the trapezoidal plane, the other part of the depressions is positioned on the trapezoidal slope, the upper surface of each forming die unit (41) is also provided with a feeding hole (414), the feeding holes (414) are positioned at the adjacent positions of two adjacent forming die units (41), are arranged between two symmetrical first depressions (413), and are communicated with the corresponding die structures with the bottoms of the first depressions (413) and the second depressions on the left side and the right side being hollowed;

the mould cover plate (5) is provided with an outer surface and an inner surface which are oppositely configured, the inner surface is a trapezoidal protruding structure which is tightly matched with the upper surface of the mould body (4), the inner surface of the trapezoid protruding structure is provided with a avoidance groove (51), a positioning hole (52) and a glue injection through hole (53) which penetrates through the inner surface and the outer surface of the mould cover plate, the glue injection through hole (53) is aligned with a material inlet hole (414) on the upper surface of the forming die unit (41), the avoiding groove (51) is suitable for accommodating a protruding structure (111) of a first shock-absorbing parallels sheet (11) fixedly arranged in the first recess (413), the positioning hole (52) is suitable for matching and positioning a device fixedly connected with the first mold stop block (42) and the second mold stop block (43), the left side wall and the right side wall of the die cover plate (5) are respectively provided with two supporting columns (54) for supporting the die cover plate (5);

the injection molding machine (6) is provided with a mold cavity (61), a push-pull mechanism and a PLC controller, the mould cavity (61) is suitable for accommodating the supporting mechanism (2) and fixing a mould mechanism which is composed of a mould supporting plate (3), a mould body (4) and a mould cover plate (5) on the supporting mechanism, the push-pull mechanism is suitable for pushing and pulling back the supporting mechanism (2) which is accommodated in the die cavity (61) and is fixed with the die mechanism, when the mould mechanism is pulled back to the mould cavity (61), an injection nozzle on the injection molding machine (6) is opposite to a glue injection through hole (53) on the mould cover plate (5) and is subjected to injection molding, a first damping shim sheet (11) fixedly arranged at a first sunken part (413) and a second damping shim sheet (12) fixedly arranged at a second sunken part are connected through special glue (13) in an injection molding mode, and the mould mechanism is pushed out of the mould cavity (61) after the injection molding.

2. The generator damping pad production system according to claim 1, characterized in that the special rubber (13) is acrylate rubber or ethylene propylene diene monomer rubber.

3. The generator damping pad production system according to claim 1, wherein the injection molding of the injection molding machine (6) specifically comprises rubber material melting, injection, pressure maintaining and cooling molding, the rubber material melting conditions are temperature 122-.

4. The generator shock pad production system according to claim 1, wherein a first trapezoidal protrusion platform and a second trapezoidal protrusion platform are integrally formed on the upper surface of the mold supporting plate (3), a connection part of the first trapezoidal protrusion platform and the second trapezoidal protrusion platform is a smooth transition plane groove, and two trapezoidal protrusion platforms corresponding to the first trapezoidal protrusion platform and the second trapezoidal protrusion platform are formed on the inner surface of the mold cover plate (5) and the forming mold unit (4).

5. The generator shock pad production system according to claim 1, wherein two ends of the first mold stopper (42) are fixed on the front side of the mold supporting plate (3) through bolts, and a pin shaft fixedly connected with the mold supporting plate (3) is arranged in the middle of the first mold stopper (42); the two ends of the second mold stop block (43) are fixed on the rear side of the mold supporting plate (3) through pin shafts, and a bolt fixedly connected with the mold supporting plate (3) is arranged in the middle of the second mold stop block (43).

6. The generator shock pad production system according to claim 1, wherein a first fixing hole (415) is formed at a first recess (413) on the trapezoidal slope, a first protruding button (111) which is matched with the first fixing hole (415) is arranged on the first shock pad iron sheet (11), a second fixing hole is formed at a second recess on the trapezoidal slope, and a second protruding button (121) which is matched with the second fixing hole is arranged on the second shock pad iron sheet (12).

7. The generator cushion production system according to claim 1, wherein the push-pull mechanism in the injection molding machine (6) is a push-pull cylinder fixedly connected with the support mechanism (2), and the push-pull cylinder is electrically connected with the PLC controller.