CN220548561U - Injection molding die carrier processing system - Google Patents

Abstract

The utility model provides an injection molding die carrier processing system, comprising: the processing mechanism comprises a transmission assembly, a carrying assembly arranged on the inner side of the transmission assembly, and a loading and unloading assembly, a guide sleeve assembly, a connecting assembly, a turnover assembly and a die assembly which are sequentially arranged along the transportation direction of the transmission assembly, wherein the transmission assembly encloses a processing space, and the carrying assembly moves in the processing space; the control mechanism is connected with the processing mechanism and comprises at least seven control modules. According to the injection molding die carrier processing system, the processing system integrates the processes of carrying, conveying, feeding and discharging, guide sleeve assembling, connecting, overturning and die closing, and the control mechanism is used for realizing the interactive connection of each stage, so that the whole production process can be traced, the whole process is visualized, and the automation degree and the production and processing efficiency of the injection molding die carrier processing are greatly improved.

Description

Injection molding die carrier processing system

Technical Field

The utility model relates to the technical field of injection molding, in particular to an injection molding die carrier processing system.

Background

The injection mould frame is a tool for producing plastic or rubber products and also a tool for endowing the plastic products with complete structures and precise dimensions. In the production and processing process, the injection molded product can be used as a qualified molded product after the processing operations such as guide sleeve assembly, element connection, die assembly and the like are performed.

At present, to above-mentioned course of working, all be equipped with independent equipment to every processing, need carry the component after carrying out some processing generally and shift, can not mutually support between a plurality of equipment, and the course of working is uncontrollable, leads to connecting cooperation degree and degree of automation lower in the whole course of working of die carrier of moulding plastics from this, and then greatly reduced production efficiency.

Disclosure of Invention

Therefore, the utility model aims to solve the technical problems of low processing efficiency and uncontrollable processing process of the injection molding die carrier in the prior art and provides an injection molding die carrier processing system capable of controlling and connecting a plurality of devices.

In order to solve the technical problems, the utility model provides an injection molding die carrier processing system, which comprises: the processing mechanism comprises a transmission assembly, a carrying assembly arranged on the inner side of the transmission assembly, and a loading and unloading assembly, a guide sleeve assembly, a connecting assembly, a turnover assembly and a die assembly which are sequentially arranged along the transportation direction of the transmission assembly, wherein the transmission assembly encloses a processing space, and the carrying assembly moves in the processing space; the control mechanism is connected with the processing mechanism and comprises at least seven control modules.

In one embodiment of the utility model, the handling assembly comprises a handling robot moving within the processing space and an adsorbing member connected to the handling robot working end.

In one embodiment of the utility model, the loading and unloading assembly comprises a loading conveyor belt arranged at the initial position of the transmission assembly at intervals and an unloading conveyor belt arranged at the tail position of the transmission assembly.

In one embodiment of the utility model, the guide sleeve assembly component comprises guide sleeve transplanting equipment, an upper die transplanting device and an extrusion assembly part, wherein the upper die transplanting device is connected with the extrusion assembly part in a sliding manner, and the guide sleeve transferring equipment is arranged above the upper die transplanting device and is connected with the extrusion assembly part in a sliding manner along the opposite direction of the upper die transplanting device.

In one embodiment of the utility model, the guide sleeve assembly further comprises a guide sleeve feeder, and the guide sleeve feeder is arranged at one side far away from the transmission assembly.

In one embodiment of the utility model, the connecting assembly comprises a screw driving machine and a moving module, wherein the moving module is connected with the screw driving machine in a sliding manner perpendicular to the conveying direction of the conveying assembly.

In one embodiment of the utility model, the connecting assembly further comprises a connecting piece feeding machine, and the connecting piece feeding machine is arranged at one side far away from the conveying assembly.

In one embodiment of the present utility model, the turnover assembly includes a jacking driver, a rotation driver and a bearing surface, wherein the jacking driver is connected below the bearing surface and drives the bearing surface to move up and down, and the rotation driver is connected to one side of the bearing surface and drives the bearing surface to rotate.

In one embodiment of the utility model, the die assembly comprises a hydraulic device, a lower die moving part and an extrusion die clamping frame, wherein the hydraulic device is connected above the extrusion die clamping frame and drives the extrusion die clamping frame to move up and down, and the lower die moving part is connected below the extrusion die clamping frame and is matched with the extrusion die clamping frame for die clamping.

In one embodiment of the utility model, the transport assembly is a roller conveyor line with a plurality of processing stations and the handling assembly is a six-axis robot.

Compared with the prior art, the technical scheme of the utility model has the following advantages:

according to the injection molding die carrier processing system, the processing mechanism integrates the processes of carrying, conveying, feeding and discharging, guide sleeve assembling, I-shaped plate connecting, overturning and die closing, and the control mechanism is used for realizing the mutual connection of all stages.

Drawings

In order that the utility model may be more readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof that are illustrated in the appended drawings.

FIG. 1 is a schematic perspective view of an injection molding frame processing system in accordance with a preferred embodiment of the present utility model;

FIG. 2 is a schematic perspective view of the handling assembly of FIG. 1;

FIG. 3 is an enlarged schematic view of the guide sleeve assembly at A of FIG. 1;

FIG. 4 is a schematic perspective view of the connection assembly of FIG. 1;

FIG. 5 is a schematic perspective view of the tilting mechanism of FIG. 1;

fig. 6 is a schematic perspective view of the composite membrane assembly of fig. 1.

Description of the specification reference numerals: 100. a processing mechanism; 110. a transmission assembly; 111. a processing site; 120. a handling assembly; 121. a transfer robot; 122. an absorbing member; 130. feeding and discharging components; 131. a feeding conveyor belt; 132. a blanking conveyor belt; 140. the guide sleeve assembly component; 141. a guide sleeve transplanting device; 142. a guide sleeve feeding machine; 143. an upper die shifting device; 144. extruding the assembly; 150. a connection assembly; 151. a connecting piece feeding machine; 152. a screw driving machine; 153. a mobile module; 160. a turnover mechanism; 161. a rotary driver; 162. a bearing surface; 163. a jack-up drive; 170. a mold assembly; 171. a hydraulic device; 172. a lower die moving member; 173. extruding the die carrier.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the utility model and practice it.

Referring to fig. 1, the present embodiment provides an injection mold frame processing system, including: the processing mechanism 100, the processing mechanism 100 comprises a transmission assembly 110, a carrying assembly 120 arranged at the inner side of the transmission assembly 110, and an upper and lower material conveying belt, a guide sleeve assembly 140, a connecting assembly 150, a turnover mechanism 160 and a mold closing assembly 170 which are sequentially arranged along the transportation direction of the transmission assembly 110, wherein a processing space is surrounded by the transmission assembly 110, and the carrying assembly 120 moves in the processing space; the control mechanism is connected with the processing mechanism 100 and comprises at least seven control modules. In this embodiment, the transmission assembly 110 is threaded through the loading and unloading conveyor, the guide sleeve assembly 140, the connecting assembly 150, the turnover mechanism 160 and the mold clamping assembly 170, and can send the processed element of the previous assembly to the next processing assembly, preferably a roller conveyor line with a plurality of processing sites 111, in other embodiments, the transmission assembly 110 may be configured as a continuous transmission device such as a conveyor, and in this embodiment, seven control modules in the control mechanism respectively control the transmission assembly 110, the carrying assembly 120, the loading and unloading conveyor, the guide sleeve assembly 140, the connecting assembly 150, the turnover mechanism 160 and the mold clamping assembly 170, and can preset parameters to limit the operation time, the processing speed and the opening and closing of each part, and also can perform manual control according to real-time conditions.

The injection molding die carrier processing system integrates the processes of carrying, conveying, feeding and discharging, guide sleeve assembling, I-shaped plate connecting, overturning and die closing into a whole through the processing mechanism 100, realizes the mutual connection of each stage through the control mechanism, has reasonable layout in the assembling and processing process and high automation degree, can trace the whole production process, and can realize the whole process visualization, and the efficiency of the assembling and processing is greatly improved.

In this embodiment, the handling assembly 120 is disposed at the center of the processing mechanism 100, and is capable of being matched with each part of the assembly in the processing space to transfer the components, and as shown in fig. 1 and 2, the handling assembly 120 includes a handling robot 121 and an adsorbing member 122, the handling robot 121 moves in the processing space, and the adsorbing member 122 is connected to a working end of the handling robot 121. In this embodiment, the transfer robot 121 is disposed on a fixed base, and includes a first mechanical arm, a second mechanical arm and a third mechanical arm that are sequentially connected from bottom to top, where one end of the first mechanical arm is rotationally connected to the base along a horizontal direction, one end of the second mechanical arm is rotationally connected to the other end of the first mechanical arm along a vertical direction, and one end of the third mechanical arm is also rotationally connected to the other end of the second mechanical arm along a vertical direction, so as to realize multi-directional rotation of the transfer robot 121 in a processing space. In this embodiment, the suction member 122 is detachably connected to the free end of the third mechanical arm and moves synchronously with the third mechanical arm in the processing space, in this embodiment, the suction member 122 is preferably a suction cup, in other embodiments, the suction member 122 may be configured as a clamping jaw, a clamping plate, or other elements with a conveying and transferring function, which is not particularly limited in this utility model, and further, the conveying assembly 120 is preferably a six-axis robot in this embodiment.

Referring to fig. 1, the loading and unloading conveyor belt includes a loading conveyor belt 131 disposed at a start position of the transmission assembly 110 and an unloading conveyor belt 132 disposed at an end position of the transmission assembly 110. In this embodiment, three feeding conveyor belts 131 and one discharging conveyor belt 132 are provided, where the three feeding conveyor belts 131 are respectively used for feeding the upper die, the i-shaped panel and the lower die, the discharging conveyor belt 132 is used for discharging the elements after die assembly, specifically, the feeding conveyor belt 131 used for feeding the upper die and the i-shaped panel is disposed on one side of the handling assembly 120, and the feeding conveyor belt 131 and the discharging conveyor belt 132 used for feeding the lower die are disposed on the other side of the handling assembly 120 so as to be matched with the corresponding processing assembly, so as to improve the processing efficiency.

Referring to fig. 3, the guide sleeve assembly component 140 includes a guide sleeve feeding machine 142, a guide sleeve transplanting device 141, an upper die transplanting device 143 and an extrusion assembly 144, wherein the guide sleeve feeding machine 142 is disposed at a side far away from the transmission component 110, the upper die transplanting device 143 is slidably connected with the extrusion assembly 144, and the guide sleeve transplanting device 141 is disposed above the upper die transplanting device 143 and is slidably connected with the extrusion assembly 144 along the opposite direction of the movement of the upper die transplanting device 143. In this embodiment, the guide sleeve assembling component 140 shown in fig. 3 is used as a reference, the guide sleeve feeding machine 142 and the guide sleeve transplanting device 141 are disposed on the right side of the extrusion assembling component 144, the upper die shifting device 143 is disposed on the left side of the extrusion assembling component 144 so as to be matched with the feeding conveyor belt 131 for feeding the upper die, wherein the upper die shifting device 143 comprises a sliding rail extending along the left-right direction and clamping jaws moving along the sliding rail, specifically, one end of the sliding rail extends above the feeding conveyor belt 131 for feeding the upper die, the clamping jaws can carry the upper die from the feeding conveyor belt 131 to the extrusion assembling component 144, likewise, the guide sleeve shifting device 141 is disposed between the guide sleeve feeding mechanism 142 and the extrusion assembling component 144 in this embodiment, and comprises the sliding rail extending along the left-right direction and the sliding connection of the sliding rail, the guide sleeve can be carried into the extrusion assembling component 144 from the guide sleeve feeding machine 142, further, after the upper die and the clamping jaws are all transported into the extrusion assembling component 144, the two clamping jaws can be carried out on the extrusion assembling component 144 to the upper die, the hydraulic cylinder can be further connected with the guide sleeve, and the hydraulic cylinder can be prevented from being connected with the extrusion cylinder, and the hydraulic cylinder can be further connected to the guide sleeve, and the actual hydraulic cylinder can be prevented from being damaged.

Referring to fig. 4, the connection assembly 150 includes a screw driving machine 152 and a moving module 153, the moving module 153 is slidably connected to the screw driving machine 152 perpendicular to the transporting direction of the transmission assembly 110, and further, the connection assembly 150 further includes a connection piece feeding machine 151, and the connection piece feeding machine 151 is disposed at a side far away from the transmission assembly 110. In this embodiment, the connection assembly 150 is used for connecting an upper die and an i-panel, in this embodiment, the upper die and the i-panel are cooperatively connected by a screw and a screw driving machine 152, the connection assembly 150 shown in fig. 4 is used as a reference, in this embodiment, the moving module 153 extends along the left-right direction, and is connected above the processing space, the screw driving machine 152 is slidably connected with the moving module 153 along the extending direction of the moving module 153, further, in this embodiment, the screw driving machine 152 can also move along the up-down direction, the connection piece feeding machine 151 is disposed on the right side of the connection assembly 150, and is used for feeding screws, when in use, the carrying assembly 120 carries the upper die connected with the guide sleeve assembly 140 into the connection assembly 150, then carries the i-panel into the connection assembly 150 from the feeding conveyor 131 for feeding the i-panel, and then the screw driving machine 152 takes out the screw from the connection piece feeding machine 151 and connects the upper die and the i-panel in the connection assembly 150.

Referring to fig. 1 and 5, the turnover mechanism 160 includes a lifting driver 163, a rotary driver 161 and a bearing surface 162, wherein the lifting driver 163 is connected below the bearing surface 162 and drives the bearing surface 162 to move up and down, and the rotary driver 161 is connected to one side of the bearing surface 162 and drives the bearing surface 162 to rotate. In this embodiment, the turnover mechanism 160 is used for turning over the upper mold connected with the guide sleeve and the i-shaped panel so as to facilitate subsequent processing and production, in this embodiment, the turnover mechanism 160 further includes a connecting frame, a sliding rail is disposed in the height direction of the connecting frame, the bearing surface 162 can reciprocate along the sliding rail, the jacking driver 163 is connected to the bottom of the bearing surface 162 and is used for driving the bearing surface 162 to perform lifting movement, further, in this embodiment, the jacking driver 163 is preferably a driving motor, the rotating driver 161 is connected to one side surface of the bearing surface 162 and is used for driving the bearing surface 162 to turn over, in this embodiment, the bearing surface 162 can be turned over by 180 °, the rotating driver is preferably a rotating motor, in other embodiments, the jacking driver 163 and the rotating driver 161 can be all configured as other driving devices such as an air cylinder, which is not particularly limited in this utility model. In use, the handling assembly 120 can cooperate with the conveying assembly 110 to place the component to be processed on the carrying surface 162, then the carrying surface 162 is lifted by the lifting driver 163, the carrying surface 162 after being lifted is turned over by the rotating driver 161, and finally the component to be processed is lowered to the initial height along the sliding rail.

Referring to fig. 6, the mold clamping unit 170 includes a hydraulic press 171, a lower mold moving member 172, and an extrusion mold clamping frame 173, wherein the hydraulic press 171 is connected to the upper side of the extrusion mold clamping frame 173 and drives the extrusion mold clamping frame 173 to move up and down, and the lower mold moving member 172 is connected to the lower side of the extrusion mold clamping frame 173 and cooperates with the extrusion mold clamping frame 173 to clamp the mold. In this embodiment, the lower die moving member 172 includes a guide rail extending toward the material conveyor 131 for feeding the lower die and a gripping member for gripping the lower die, specifically, the gripping member is preferably a gripper capable of opening and closing, further, a slide rail extending toward the lower die moving member 172 is provided on the extrusion clamping frame 173, and the hydraulic device 171 is capable of moving along the slide rail in the extrusion clamping frame 173 to adjust an actual extrusion assembling position, and in this embodiment, an extrusion block for extrusion-connecting the upper die and the lower die is connected to a working end of the hydraulic device 171. When in use, the lower die moving part 172 carries the lower die to be processed into the die assembly 170 through the feeding conveyor belt 131, meanwhile, the carrying assembly 120 places the overturned upper die in the extrusion die holder 173, then the carrying assembly 120 places the lower die above the upper die, meanwhile, the hydraulic device 171 adjusts the extrusion position along the sliding rail, and finally the hydraulic device extrudes downwards to complete the assembly between the upper die and the lower die.

In conclusion, the injection molding die carrier processing system integrates the processes of carrying, conveying, feeding and discharging, guide sleeve assembling, I-shaped plate connecting, overturning and die closing into a whole through the processing mechanism 100, realizes the mutual connection of each stage through the control mechanism, has reasonable layout in the assembling and processing process and high automation degree, can trace back the whole production process, and is visualized in the whole process, and the efficiency of assembling and processing is greatly improved.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations and modifications of the present utility model will be apparent to those of ordinary skill in the art in light of the foregoing description. It is not necessary here nor is it exhaustive of all embodiments. And obvious variations or modifications thereof are contemplated as falling within the scope of the present utility model.

Claims (10)

1. An injection mold frame processing system, which is characterized in that: comprising the following steps:

the processing mechanism comprises a transmission assembly, a carrying assembly arranged on the inner side of the transmission assembly, and a loading and unloading assembly, a guide sleeve assembly, a connecting assembly, a turnover assembly and a die assembly which are sequentially arranged along the transportation direction of the transmission assembly, wherein the transmission assembly encloses a processing space, and the carrying assembly moves in the processing space;

the control mechanism is connected with the processing mechanism and comprises at least seven control modules.

2. The injection mold frame processing system of claim 1, wherein: the handling assembly comprises a handling robot and an adsorption piece, wherein the handling robot moves in the processing space, and the adsorption piece is connected to the working end of the handling robot.

3. The injection mold frame processing system of claim 1, wherein: the feeding and discharging assembly comprises feeding conveyor belts arranged at the initial position of the transmission assembly at intervals and discharging conveyor belts arranged at the tail position of the transmission assembly.

4. The injection mold frame processing system of claim 1, wherein: the guide sleeve assembly component comprises guide sleeve transplanting equipment, an upper die transplanting device and an extrusion assembly piece, wherein the upper die transplanting device is connected with the extrusion assembly piece in a sliding mode, and the guide sleeve transferring equipment is arranged above the upper die transplanting device and is connected with the extrusion assembly piece in a sliding mode along the opposite direction of the upper die transplanting device.

5. The injection mold frame processing system of claim 4, wherein: the guide sleeve assembly further comprises a guide sleeve feeding machine, and the guide sleeve feeding machine is arranged on one side far away from the transmission assembly.

6. The injection mold frame processing system of claim 1, wherein: the connecting assembly comprises a screw driving machine and a moving module, and the moving module is perpendicular to the conveying direction of the conveying assembly and is in sliding connection with the screw driving machine.

7. The injection mold frame processing system of claim 6, wherein: the connecting assembly further comprises a connecting piece feeding machine, and the connecting piece feeding machine is arranged on one side far away from the transmission assembly.

8. The injection mold frame processing system of claim 1, wherein: the overturning assembly comprises a jacking driver, a rotary driver and a bearing surface, wherein the jacking driver is connected below the bearing surface and drives the bearing surface to move in a lifting manner, and the rotary driver is connected with one side of the bearing surface and drives the bearing surface to rotate.

9. The injection mold frame processing system of claim 1, wherein: the die assembly comprises a hydraulic device, a lower die moving part and an extrusion die assembly frame, wherein the hydraulic device is connected with the upper part of the extrusion die assembly frame and drives the extrusion die assembly frame to move up and down, and the lower die moving part is connected with the lower part of the extrusion die assembly frame and is matched with the extrusion die assembly frame for die assembly.

10. The injection mold frame processing system of claim 1, wherein: the conveying assembly is a roller conveying line with a plurality of processing sites, and the carrying assembly is a six-axis robot.