CN220075280U - Rubber joint vulcanizer - Google Patents

Abstract

The utility model provides a rubber joint vulcanizing machine, which comprises a base, wherein a supporting rod is arranged on the base in a penetrating way, and a first moving component is arranged on the base in a sliding way and moves along one side of the base to the center of the base and is used for bearing a rubber joint; the extrusion die assembly is movably arranged between the top seat and the base and is used for extrusion die assembly of the rubber joint borne by the first moving assembly; the second moving assembly is arranged on the base in a sliding manner and moves along one side of the base to the center of the base, and is used for bearing the rubber joint after extrusion die assembly and driving the rubber joint to move.

Description

Rubber joint vulcanizer

Technical Field

The utility model belongs to the field of rubber joint production and processing equipment, and particularly relates to a rubber joint vulcanizing machine.

Background

At present, the rubber joint is also called as a flexible rubber joint, a high-pressure rubber joint, a compensator and the like, and is formed by forming a tubular rubber part by inner and outer rubber layers, a ply and a bead ring, and then combining the tubular rubber part with a metal flange or a parallel joint loose sleeve after vulcanization molding. The product can reduce vibration and noise, and can compensate for thermal expansion and contraction caused by temperature change. In particular, in the processing process of the rubber gasket, rubber strips are often processed into the same length, then are butted into different lengths according to the requirement, and then are vulcanized and connected, but the connected rubber strips are in a strip shape or a circular ring shape, the size is large, when the rubber strips are placed on a vulcanizing machine for vulcanization, the rubber strips are easy to drop from two ends of a workbench, dust is easily polluted when the vulcanized joints fall on the ground, and the two ends of the vulcanized joints are easy to deform due to the tensile force in two directions, so that the vulcanizing quality of the rubber strip joints is affected. In the existing rubber soft joint processing process, a four-piece die assembly mode is adopted for a rubber joint die, after the original process is manually assembled by screws, the rubber joint die is pushed into a flat vulcanizing machine for vulcanization, after the vulcanization is completed, the die is manually disassembled, a rubber part is taken out, the time and the labor are wasted in the whole operation process, and the product yield is low.

Therefore, in view of the shortcomings of the practical manufacturing and implementation of the scheme, the utility model is modified and improved, and the utility model is created by the assistance of professional knowledge and experience and after multi-party skillful and test, and the utility model provides a rubber joint vulcanizing machine for solving the problems.

Disclosure of Invention

The utility model provides a rubber joint vulcanizing machine, which solves the problems in the prior art.

The technical scheme of the utility model is realized as follows: the rubber joint vulcanizing machine comprises a base, wherein a supporting rod penetrates through the base, and a top seat is fixedly arranged at the top of the supporting rod;

the first moving assembly is arranged on the base in a sliding manner, moves along one side of the base to the center of the base and is used for bearing the rubber joint;

the extrusion die assembly is movably arranged between the top seat and the base and is used for extrusion die assembly of the rubber joint borne by the first moving assembly;

the second moving assembly is arranged on the base in a sliding manner, moves along one side of the base to the center of the base and is used for bearing the rubber joint after the extrusion die assembly and driving the rubber joint to move;

the first moving assembly and the second moving assembly move in opposite directions.

When the prepared rubber joint to be processed is placed on the first moving assembly, the rubber joint starts to move towards the center of the base under the action of the driving cylinder, and simultaneously the second moving assembly starts to move synchronously, at the moment, the first moving assembly and the second moving assembly move back to back, when the two moving assemblies reach the limit position, the rubber joint carried on the first moving assembly starts to extrude and form a film under the action of the extrusion die assembly, after the rubber joint is processed, the extrusion die assembly and the second moving assembly start to move relatively, when the extrusion die assembly is aligned with the second moving assembly, the extrusion die assembly is opened, and the rubber joint on the extrusion die assembly just falls into the second moving assembly, so that the operation of the whole rubber joint extrusion die assembly process is realized.

As a preferred implementation mode, base one side is provided with the support, the both sides of support are fixed respectively and are provided with the guide rail, both sides the tip of guide rail is located the base, first removal subassembly includes the support frame, support frame bottom and guide rail sliding fit, the base is close to the fixed first actuating cylinder that is provided with in one side of first removal subassembly, first actuating cylinder is located between the guide rail of both sides, the second removal subassembly includes the supporting seat, first actuating cylinder drive supporting seat removes between support and base surface, the supporting seat is located between the guide rail of both sides, realizes the motion of first removal subassembly along the guide rail on the base under the effect of first actuating cylinder, has realized the relative motion of rubber joint at first removal subassembly, makes it can reach the assigned position to by extrusion compound die subassembly snatch.

As a preferred implementation mode, the supporting seat is movably arranged at the lower part of the supporting frame, and a plurality of evenly distributed placing grooves are formed in the top of the supporting seat, so that rubber joints to be processed can be placed better, and the joints are easily offset and inverted in the movement process.

As a preferred embodiment, the press mold clamping assembly includes a pressing member and a pressing member, both of which move up and down along the support bar, the pressing member being located between the pressing member and the base.

As a preferred embodiment, the fixed second actuating cylinder that sets up in footstock top, the part of pushing down includes the holding down plate, four corners of holding down plate respectively with bracing piece clearance fit, the expansion end and the holding down plate fixed connection of second actuating cylinder, the fixed briquetting that is provided with in bottom of holding down plate when the rubber joint that will wait to process moves limit distance, and the second actuating cylinder begins the operation this moment, and the second actuating cylinder drives down the part and begins the downward movement, and the holding down plate bottom this moment is provided with the briquetting down, and the joint of extrusion compound die subassembly position that the briquetting can be better compresses tightly down.

As a preferred implementation mode, the extrusion part includes first slider and the second slider that the symmetry set up, first slider and second slider all with bracing piece sliding fit, the outside of first slider and second slider is all fixed to be provided with the third actuating cylinder, the activity is provided with first extrusion piece and second extrusion piece between first slider and the second slider, first extrusion piece and second extrusion piece set up relatively and the structure is the same, the first extrusion piece of third actuating cylinder drive and second extrusion piece are towards opposite direction removal, when beginning extrusion and membrane process, and the relative motion is begun to first slider of third actuating cylinder drive and second slider, and first extrusion piece and second extrusion piece begin relative motion equally this moment, make the rubber joint that waits to process extruded.

As a preferred implementation mode, a connecting rod is fixedly arranged between the first sliding block and the second sliding block, the first extrusion block and the second extrusion block are movably arranged on the connecting rod, extrusion grooves are respectively formed in the opposite side surfaces of the first extrusion block and the second extrusion block, extrusion molding of a rubber joint can be better achieved between the first extrusion block and the second extrusion block, and molding of the joint can be better achieved by the extrusion grooves.

After the technical scheme is adopted, the utility model has the beneficial effects that: when the prepared rubber joint to be processed starts to move towards the center of the base under the action of the driving cylinder, the second moving assembly synchronously starts to move, the first moving assembly and the second moving assembly move back to back, when the two moving assemblies reach the limiting position, the rubber joint borne on the first moving assembly starts to extrude and form a film process under the action of the extrusion die assembly, after the rubber joint is processed, the extrusion die assembly and the second moving assembly start to do relative movement, when the extrusion die assembly is aligned with the second moving assembly, the extrusion die assembly is opened, at the moment, the rubber joint on the extrusion die assembly just falls into the second moving assembly, the operation of the whole rubber joint extrusion die assembly process is realized, the whole operation process is time-saving and labor-saving, the product yield is high, and the pollution of workpieces is not easy to occur.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic diagram of the structure of the present utility model;

fig. 2 is a schematic view of the other side of fig. 1 according to the present utility model.

In the figure, a 1-base; 2-supporting rods; 3-footstock; 4-a first moving component; 5-extruding the die assembly; 6-a second movement assembly; 7-a bracket; 8, a guide rail; 9-supporting frames; 10-a first drive cylinder; 11-a supporting seat; 12-placing grooves; 13-pressing down the part; 14-extruding the part; 15-a second drive cylinder; 16-a lower pressing plate; 17-pressing down the block; 18-a first slider; 19-a second slider; 20-a third drive cylinder; 21-a first extrusion block; 22-a second extrusion block; 23-connecting rod; 24-extrusion groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-2, the rubber joint vulcanizing machine comprises a base 1, wherein a supporting rod 2 is arranged on the base 1 in a penetrating manner, and a top seat 3 is fixedly arranged at the top of the supporting rod 2;

the first moving assembly 4 is arranged on the base 1 in a sliding manner, moves along one side of the base 1 to the center of the base 1 and is used for bearing a rubber joint;

the extrusion die assembly 5 is movably arranged between the top seat 3 and the base 1 and is used for extrusion die assembly of the rubber joint borne by the first moving assembly 4;

the second moving assembly 6 is arranged on the base 1 in a sliding manner, moves along one side of the base 1 towards the center of the base 1 and is used for bearing the rubber joint after the extrusion die assembly and driving the rubber joint to move;

the first moving assembly 4 and the second moving assembly 6 move in opposite directions.

When the prepared rubber joint to be processed is placed on the first moving assembly 4, the rubber joint starts to move towards the center of the base 1 under the action of the driving cylinder, meanwhile, the second moving assembly 6 starts to move synchronously, at the moment, the first moving assembly 4 and the second moving assembly 6 move back to each other, when the two moving assemblies reach the limit position, the rubber joint carried on the first moving assembly 4 starts to extrude and film the process under the action of the extrusion die assembly 5, after the rubber joint is processed, the extrusion die assembly 5 and the second moving assembly 6 start to move relatively, when the extrusion die assembly 5 is aligned with the second moving assembly 6, the extrusion die assembly 5 is opened, and at the moment, the rubber joint on the extrusion die assembly 5 just falls into the second moving assembly 6, so that the operation of the whole rubber joint extrusion die assembly process is realized.

The base 1 one side is provided with support 7, the both sides of support 7 are fixed respectively and are provided with guide rail 8, both sides the tip of guide rail 8 is located base 1, first removal subassembly 4 includes support frame 9, support frame 9 bottom and guide rail 8 sliding fit, the fixed first actuating cylinder 10 that is provided with in one side that is close to first removal subassembly 4 of base 1, first actuating cylinder 10 is located between the guide rail 8 of both sides, second removal subassembly 6 includes supporting seat 11, first actuating cylinder 10 drive supporting seat 11 removes between support 7 and base 1 surface, supporting seat 11 is located between the guide rail 8 of both sides, realizes the motion of first removal subassembly 4 along guide rail 8 on base 1 under the effect of first actuating cylinder 10, has realized the relative motion of rubber joint on first removal subassembly 4, makes it can reach the assigned position to by extrusion compound die subassembly 5 snatch.

The supporting seat 11 is movably arranged at the lower part of the supporting frame 9, and a plurality of evenly distributed placing grooves 12 are formed in the top of the supporting seat 11, so that rubber joints to be processed can be placed better, and the joints are easily offset and inverted in the moving process.

The extrusion die assembly 5 comprises a pressing part 13 and an extrusion part 14, wherein the pressing part 13 and the extrusion part 14 move up and down along the support rod 2, and the extrusion part 14 is positioned between the pressing part 13 and the base 1.

The fixed second actuating cylinder 15 that sets up in footstock 3 top, the push down part 13 includes holding down plate 16, four corners of holding down plate 16 respectively with bracing piece 2 movable fit, the expansion end and the holding down plate 16 fixed connection of second actuating cylinder 15, the fixed briquetting 17 that is provided with in bottom of holding down plate 16, when the rubber joint that will wait to process when first moving assembly 4 moves the limit distance, second actuating cylinder 15 begins the operation this moment, and second actuating cylinder 15 drives down part 13 and begins the downward movement, and the holding down plate 16 bottom at this moment is provided with briquetting 17 down, and briquetting 17 can be better compress tightly the joint of extrusion compound die assembly 5 position down.

The extrusion part 14 comprises a first slide block 18 and a second slide block 19 which are symmetrically arranged, the first slide block 18 and the second slide block 19 are in sliding fit with the support rod 2, a third driving cylinder 20 is fixedly arranged on the outer sides of the first slide block 18 and the second slide block 19, a first extrusion block 21 and a second extrusion block 22 are movably arranged between the first slide block 18 and the second slide block 19, the first extrusion block 21 and the second extrusion block 22 are oppositely arranged and have the same structure, the third driving cylinder 20 drives the first extrusion block 21 and the second extrusion block 22 to move in opposite directions, and when the extrusion and the film process are started, the third driving cylinder 20 drives the first slide block 18 and the second slide block 19 to start to perform relative movement, and at the moment, the first extrusion block 21 and the second extrusion block 22 also start to perform relative movement, so that a rubber joint to be processed is extruded.

The connecting rod 23 is fixedly arranged between the first sliding block 18 and the second sliding block 19, the first extrusion block 21 and the second extrusion block 22 are movably arranged on the connecting rod 23, extrusion grooves 24 are respectively formed in the opposite side surfaces of the first extrusion block 21 and the second extrusion block 22, extrusion molding of rubber joints can be better achieved between the first extrusion block 21 and the second extrusion block 22, and molding of joints can be better achieved by the extrusion grooves 24.

In the description of the present utility model, it should be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model. In the description of the present utility model, unless otherwise specified and defined, it should be noted that the terms "mounted," "connected," and "coupled" are to be construed broadly, and may be, for example, mechanical or electrical, or may be in communication with each other between two elements, directly or indirectly through intermediaries, as would be understood by those skilled in the art, in view of the specific meaning of the terms described above.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. The rubber joint vulcanizing machine is characterized by comprising a base, wherein a supporting rod penetrates through the base, and a top seat is fixedly arranged at the top of the supporting rod;

the first moving assembly is arranged on the base in a sliding manner, moves along one side of the base to the center of the base and is used for bearing the rubber joint;

the extrusion die assembly is movably arranged between the top seat and the base and is used for extrusion die assembly of the rubber joint borne by the first moving assembly;

the second moving assembly is arranged on the base in a sliding manner, moves along one side of the base to the center of the base and is used for bearing the rubber joint after the extrusion die assembly and driving the rubber joint to move;

the first moving assembly and the second moving assembly move in opposite directions.

2. The rubber joint vulcanizer according to claim 1, wherein a bracket is provided on one side of the base, guide rails are fixedly provided on both sides of the bracket, the ends of the guide rails on both sides are located on the base, the first moving assembly comprises a support frame, the bottom of the support frame is in sliding fit with the guide rails, a first driving cylinder is fixedly provided on one side of the base, which is close to the first moving assembly, and is located between the guide rails on both sides, the second moving assembly comprises a support seat, the first driving cylinder drives the support seat to move between the bracket and the surface of the base, and the support seat is located between the guide rails on both sides.

3. The rubber joint vulcanizing machine according to claim 2, wherein the supporting seat is movably arranged at the lower part of the supporting frame, and a plurality of evenly distributed placing grooves are formed in the top of the supporting seat.

4. The rubber joint vulcanizer as defined in claim 1, wherein the press mold clamping assembly includes a pressing member and a pressing member, both of which move up and down along the support bar, the pressing member being located between the pressing member and the base.

5. The rubber joint vulcanizing machine according to claim 4, wherein the second driving cylinder is fixedly arranged at the top of the footstock, the pressing component comprises a pressing plate, four corners of the pressing plate are respectively movably matched with the supporting rods, the movable end of the second driving cylinder is fixedly connected with the pressing plate, and the pressing block is fixedly arranged at the bottom of the pressing plate.

6. The rubber joint vulcanizer according to claim 5, wherein the extrusion part comprises a first slide block and a second slide block which are symmetrically arranged, the first slide block and the second slide block are in sliding fit with the support rod, a third driving cylinder is fixedly arranged on the outer sides of the first slide block and the second slide block, a first extrusion block and a second extrusion block are movably arranged between the first slide block and the second slide block, the first extrusion block and the second extrusion block are oppositely arranged and have the same structure, and the third driving cylinder drives the first extrusion block and the second extrusion block to move in opposite directions.

7. The rubber joint vulcanizer of claim 6, wherein a connecting rod is fixedly arranged between the first sliding block and the second sliding block, the first extrusion block and the second extrusion block are movably arranged on the connecting rod, and extrusion grooves are respectively arranged on opposite side surfaces of the first extrusion block and the second extrusion block.