CN216027860U

CN216027860U - Radiator pin squeeze riveter

Info

Publication number: CN216027860U
Application number: CN202121929004.XU
Authority: CN
Inventors: 张星奎
Original assignee: Dongguan Chixiang Electronic Co ltd
Current assignee: Dongguan Chixiang Electronic Co ltd
Priority date: 2021-08-17
Filing date: 2021-08-17
Publication date: 2022-03-15
Anticipated expiration: 2031-08-17

Abstract

The utility model relates to the technical field of riveting, in particular to a riveting press for radiator pins. The radiator leg snap riveting press comprises a rack, a pressure-bearing assembly, a pressing assembly, a conveying assembly and a feeding assembly; the rack comprises a bottom plate, a top plate and a fixed rod, wherein two ends of the fixed rod are fixedly connected with the top plate and the bottom plate respectively; the pressure bearing assembly comprises a workbench; the workbench is provided with a positioning piece and a sensor; the material pressing assembly comprises a movable plate connected with the fixed rod in a sliding mode, a first air cylinder driving the movable plate to lift and a first electromagnetic block; the electromagnetic block is arranged right above the positioning piece and is fixedly connected with the movable plate; the conveying assembly comprises a feeding mechanism and a pushing mechanism; the feeding mechanism is used for feeding the radiator pins to the side end of the electromagnetic block; the pushing mechanism is used for pushing the radiator pins conveyed by the feeding mechanism to the bottom of the electromagnetic block; the feeding assembly is used for conveying the radiator pins to the feeding mechanism. The utility model solves the problems of inconvenient connection operation and low efficiency of the radiator pin and the radiator in the traditional technology.

Description

Radiator pin squeeze riveter

Technical Field

The utility model relates to the technical field of riveting, in particular to a riveting press for radiator pins.

Background

The squeeze riveter (also called as riveter, rotary riveter, rolling riveter, etc.) is a new type of riveting equipment developed according to the cold rolling principle, that is, it is a mechanical equipment capable of riveting articles with rivets.

In the prior art, the radiator leg is connected with the radiator and is operated by a manual beer machine, so that the processing efficiency is low, and the labor intensity of workers is high.

Therefore, it is necessary to provide a technical solution to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a riveting press for radiator pins, and aims to solve the problems that in the prior art, the radiator pins are connected with a radiator and are operated by a manual beer machine, so that the processing efficiency is low, and the labor intensity of workers is high.

In order to achieve the purpose, the utility model provides a radiator leg rivet pressing machine, which comprises a rack, a pressure-bearing assembly, a pressing assembly, a conveying assembly and a feeding assembly, wherein:

the rack comprises a bottom plate, a top plate and a plurality of fixing rods; two ends of the fixed rods are respectively fixedly connected with the top plate and the bottom plate;

the pressure bearing assembly comprises a workbench; the workbench is provided with a positioning piece for placing the radiator, and the workbench is provided with a sensor for detecting whether the radiator is placed;

the material pressing assembly comprises a movable plate, a first air cylinder and an electromagnetic block; the movable plate is connected with the fixed rod in a sliding manner; the first air cylinder is fixedly connected to the top plate, and the output end of the first air cylinder is fixedly connected with the movable plate; the electromagnetic block is arranged right above the positioning piece and is fixedly connected with the movable plate;

the conveying assembly comprises a feeding mechanism and a pushing mechanism; the feeding mechanism is arranged on the workbench and used for receiving externally input radiator pins and sending the radiator pins to the side end of the electromagnetic block; the pushing mechanism is arranged on the workbench and used for pushing the radiator pins conveyed by the feeding mechanism to the bottom of the electromagnetic block;

the feeding assembly is arranged on the bottom plate and used for conveying the radiator pins to the feeding mechanism.

More specifically, the bottom of the electromagnetic block is provided with a suction groove matched with the radiator leg, and one end of the suction groove is communicated with the outside.

More specifically, the feeding mechanism comprises a sliding block and a second air cylinder; the sliding block is arranged at one end of the suction groove communicated with the outside, is connected to the workbench in a sliding manner, and is provided with a conveying groove with two ends communicated with the outside at the top; the second air cylinder is fixedly connected to the workbench, and the output end of the second air cylinder is fixedly connected with the sliding block; when the output end of the second cylinder extends to an end value, the sliding block is positioned at the side end of the electromagnetic block, and the conveying groove is communicated with the suction groove.

More specifically, a stop block is integrally extended from one side, close to the electromagnetic block, of the sliding block, and when the output end of the second air cylinder extends to an end value, the stop block is located below the suction groove.

More specifically, a limit baffle is fixedly connected to the workbench; the stop block is provided with a limit groove matched with the limit stop block; when the wall surface of the limiting groove is contacted with the limiting baffle plate, the conveying groove is just communicated with the suction groove; when the output end of the second air cylinder is retracted to an end value, one end of the conveying groove is closed by the limiting baffle.

More specifically, the workstation has seted up the trapezoidal groove, the bottom of slider be equipped with the trapezoidal piece of trapezoidal groove looks adaptation, the trapezoidal piece with the cooperation of trapezoidal groove makes slider sliding connection be in on the workstation.

More specifically, the pushing mechanism comprises a push rod and a third cylinder; the push rod is connected to the workbench in a sliding manner, is arranged at one end of the conveying groove, which is far away from the suction groove, and is positioned on the same straight line with the suction groove; the third cylinder is fixedly connected to the workbench and fixedly connected with the push rod.

More specifically, the feeding assembly comprises a fixed seat and a feeding plate; the fixed seat is fixedly connected to the bottom plate; the feed plate is located the conveyer trough is kept away from limit baffle's one end, and its middle part is equipped with the feed channel, when the output end of second cylinder withdrawed to the end value, the feed channel with the conveyer trough communicates with each other, the other end of feed channel is connected with the vibration and goes up the charging tray.

More specifically, the sensor is a metal sensor.

More specifically, a plurality of guide sleeves are fixedly connected to the movable plate, and the guide sleeves are connected with the fixed rods in a sliding mode.

The utility model relates to a radiator pin squeeze riveter, which has the technical effects that:

this application is constantly carried out the material loading for feeding mechanism by the feeding subassembly, is sent the radiator foot son to the electromagnetic block below by pay-off structure and pushing equipment cooperation again, and under the electromagnetic action of electromagnetic block, on the radiator foot son was adsorbed and the electromagnetic block, place the radiator in the setting element afterwards, the first cylinder of drive then removed after putting into of sensor perception radiator, makes the electromagnetic block push down rivet radiator foot son and radiator pressure together. The process has high automation degree, high processing efficiency and high finished product yield, and not only reduces the labor intensity of workers.

Drawings

Fig. 1 is a schematic structural view of a radiator underfoot riveting press according to the present invention;

FIG. 2 is an enlarged schematic view at A in FIG. 1;

FIG. 3 is an enlarged schematic view at B of FIG. 1;

FIG. 4 is a schematic structural view of a feeding assembly of a heat sink foot riveter according to the present invention;

fig. 5 is a partial schematic view of a heat sink underfoot riveter according to the present invention.

The labels in the figure are:

1, a frame; 2-a pressure-bearing assembly; 3-a conveying assembly; 4-a feeding assembly; 5, pressing a material component;

101-a base plate; 102 — a top plate; 103-fixing rod;

201 — a workbench; 202-a positioning element; 203-a sensor;

301-a movable plate; 302-a first cylinder; 303-an electromagnet block; 304-suction groove; 305-a guide sleeve;

41-a feeding mechanism; 411 — a slider; 412 — a second cylinder; 413-conveying trough; 414-a stop; 415-a limit stop; 416-a limiting groove; 417 — a trapezoidal groove; 418-trapezoidal block;

42-a material pushing mechanism; 421-a push rod; 422-third cylinder;

501, a fixed seat; 502-a feed plate; 503 — a feed channel;

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

In order to more clearly illustrate the technical solution of the present invention, a preferred embodiment is provided below, with specific reference to fig. 1 to 5. The utility model provides a little squeeze riveter of radiator foot, includes frame 1, pressure-bearing subassembly 2, presses material subassembly 3, conveying component 4 and feeding subassembly 5, wherein:

the rack 1 comprises a bottom plate 101, a top plate 102 and a plurality of fixing rods 103; two ends of a plurality of fixing rods 103 are respectively fixedly connected with the top plate 102 and the bottom plate 101;

the bearing assembly 2 comprises a worktable 201; a positioning part 202 for placing a radiator is arranged on the workbench 201, and a sensor 203 for detecting whether the radiator is placed is arranged on the workbench 201;

the pressing assembly 3 comprises a movable plate 301, a first cylinder 302 and an electromagnetic block 303; the movable plate 301 is connected with the fixed rod 103 in a sliding manner; the first cylinder 302 is fixedly connected to the top plate 102, and the output end of the first cylinder is fixedly connected to the movable plate 301; the electromagnetic block 303 is disposed over the positioning member 202 and is fixedly connected to the movable plate 301, the bottom of the electromagnetic block 303 is provided with a suction slot 304 adapted to the heat sink leg, and one end of the suction slot 304 is communicated with the outside. Electromagnetic technology is adopted inside the electromagnetic block 303, and the electromagnetic block 303 has magnetism when being electrified, and can adsorb the radiator foot son.

The conveying assembly 4 comprises a feeding mechanism 41 and a pushing mechanism 42;

the feeding mechanism 41 is used for receiving externally input radiator pins and sending the radiator pins to the side end of the electromagnetic block 303, and comprises a sliding block 411 and a second cylinder 412; the sliding block 411 is arranged at one end of the suction groove 304 communicated with the outside, is connected to the workbench 201 in a sliding manner, and is provided with a conveying groove 413 with two ends communicated with the outside at the top; the second cylinder 412 is fixedly connected to the working table 201, and the output end of the second cylinder is fixedly connected with the sliding block 411; when the output end of the second cylinder 412 extends to the end value, the sliding block 411 is located at the side end of the electromagnetic block 303, and the conveying groove 413 is communicated with the suction groove 304.

Furthermore, a stop block 414 is integrally extended from one side of the sliding block 411 close to the electromagnetic block 303, and when the output end of the second air cylinder 412 is extended to an end value, the stop block 414 is located below the suction slot 304. When the radiator leg is pushed to the suction slot 304 by the conveying slot 413, the stopper 414 plays a supporting role to prevent the radiator leg from falling off.

More specifically, a limit baffle 415 is fixedly connected to the workbench 201; the stop block 414 is provided with a limit groove 416 matched with the limit baffle 415; when the wall surface of the limit groove 416 is contacted with the limit baffle 415, the conveying groove 413 is just communicated with the suction groove 304; when the output end of the second cylinder 412 is retracted to the end value, the limit stopper 415 closes one end of the transfer groove 413. The limit baffle 415 is used to limit the forward position of the sliding block 411, and at the same time, to limit the forward position of the input heat sink pins in the conveying groove 413.

The pushing mechanism 42 is used for pushing the radiator pins conveyed by the feeding mechanism 41 to the bottom of the electromagnetic block 303, and comprises a push rod 421 and a third cylinder 422; the push rod 421 is connected to the working table 201 in a sliding manner, is arranged at one end of the conveying groove 413 far away from the suction groove 304, and is positioned on the same straight line with the suction groove 304; the third cylinder 422 is fixedly connected to the working table 201 and is fixedly connected to the push rod 421.

The feeding assembly 5 is used for conveying the radiator pins to the feeding mechanism 41 and comprises a fixed seat 501 and a feeding plate 502; the fixed seat 501 is fixedly connected to the bottom plate 101; the feeding plate 502 is arranged at one end of the conveying groove 413 far away from the limit baffle 415, the feeding channel 503 is arranged in the middle of the feeding plate, when the output end of the second air cylinder 412 is retracted to the end value, the feeding channel 503 is communicated with the conveying groove 413, and the other end of the feeding channel 503 is connected with the vibrating feeding tray.

In the preferred embodiment, the sensor 203 is a metal sensor. Through the change, when the hands of the worker are placed on the positioning part 202, the sensor 203 cannot be mistakenly detected as the placement of the radiator, and therefore the squeeze riveter is prevented from accidentally injuring the worker.

Preferably, the worktable 201 is provided with a trapezoidal groove 417, the bottom of the slider 411 is provided with a trapezoidal block 418 adapted to the trapezoidal groove 417, and the trapezoidal block 418 is matched with the trapezoidal groove 417 to enable the slider 411 to be slidably connected to the worktable 201.

As a preferred embodiment of the present embodiment, a plurality of guide sleeves 305 are fixedly connected to the movable plate 301, and the guide sleeves 305 are slidably connected to the fixed rod 103.

The working process of the utility model is as follows:

a large number of radiator pins are placed in the vibrating upper tray, under the vibrating action, the radiator pins are orderly arranged on the feeding channel 503 and gradually move forward until the radiator pins enter the conveying groove 413, then the second air cylinder 412 drives the sliding block 411 to slide forward, so that the conveying groove 413 is communicated with the suction groove 304, the stop block 414 is placed below the suction groove 304, then the third air cylinder 422 drives the push rod 421 to move forward, the radiator pins in the conveying groove 413 are pushed into the suction groove 304 and are fixed on the suction groove 304 under the action of the electromagnetic block 303, then the third air cylinder 422 and the second air cylinder 412 respectively drive the push rod 421 and the sliding block 411 to return, the radiator is placed in the positioning part 202, and after the metal sensor 203 senses that the radiator is placed in, the first air cylinder 302 is controlled to drive the movable plate 301 to slide down, so that the electromagnetic block 303 presses and rivets the radiator pins on the radiator. The process has high automation degree, high processing efficiency and high finished product yield, and not only reduces the labor intensity of workers.

The utility model relates to a radiator pin squeeze riveter which solves the problems that in the prior art, the radiator pin is connected with a radiator and is operated by a manual beer machine, the processing efficiency is low, and the labor intensity of workers is high.

The above description is only exemplary of the present invention, and the structure is not limited to the above-mentioned shapes, and any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a little squeeze riveter of radiator foot which characterized in that: including frame, pressure-bearing subassembly, pressure material subassembly, conveying component and feeding subassembly, wherein:

2. The heat sink leg squeeze riveter of claim 1, characterized in that: the bottom of the electromagnetic block is provided with a suction groove matched with the radiator leg, and one end of the suction groove is communicated with the outside.

3. The heat sink leg squeeze riveter of claim 2, characterized in that: the feeding mechanism comprises a sliding block and a second air cylinder; the sliding block is arranged at one end of the suction groove communicated with the outside, is connected to the workbench in a sliding manner, and is provided with a conveying groove with two ends communicated with the outside at the top; the second air cylinder is fixedly connected to the workbench, and the output end of the second air cylinder is fixedly connected with the sliding block; when the output end of the second cylinder extends to an end value, the sliding block is positioned at the side end of the electromagnetic block, and the conveying groove is communicated with the suction groove.

4. The heat sink leg squeeze riveter of claim 3, characterized in that: a stop block is integrally extended from one side, close to the electromagnetic block, of the sliding block, and when the output end of the second air cylinder extends to an end value, the stop block is located below the suction groove.

5. The heat sink leg squeeze riveter of claim 4, characterized in that: a limiting baffle is fixedly connected to the workbench; the stop block is provided with a limit groove matched with the limit stop block; when the wall surface of the limiting groove is contacted with the limiting baffle plate, the conveying groove is just communicated with the suction groove; when the output end of the second air cylinder is retracted to an end value, one end of the conveying groove is closed by the limiting baffle.

6. The heat sink leg squeeze riveter of claim 3, characterized in that: the workbench is provided with a trapezoidal groove, the bottom of the slider is provided with a trapezoidal block matched with the trapezoidal groove, and the trapezoidal block is matched with the trapezoidal groove to ensure that the slider is connected on the workbench in a sliding manner.

7. The heat sink leg squeeze riveter of claim 3, characterized in that: the pushing mechanism comprises a push rod and a third cylinder; the push rod is connected to the workbench in a sliding manner, is arranged at one end of the conveying groove, which is far away from the suction groove, and is positioned on the same straight line with the suction groove; the third cylinder is fixedly connected to the workbench and fixedly connected with the push rod.

8. The heat sink leg squeeze riveter of claim 5, characterized in that: the feeding assembly comprises a fixed seat and a feeding plate; the fixed seat is fixedly connected to the bottom plate; the feed plate is located the conveyer trough is kept away from limit baffle's one end, and its middle part is equipped with the feed channel, when the output end of second cylinder withdrawed to the end value, the feed channel with the conveyer trough communicates with each other, the other end of feed channel is connected with the vibration and goes up the charging tray.

9. The heat sink leg squeeze riveter of claim 1, characterized in that: the sensor is a metal sensor.

10. The heat sink leg squeeze riveter of claim 1, characterized in that: the movable plate is fixedly connected with a plurality of guide sleeves, and the guide sleeves are connected with the fixed rods in a sliding mode.