CN216656996U - Automatic change couple pay-off assembly device - Google Patents

Abstract

The utility model discloses an automatic hook feeding and assembling device, and relates to the technical field related to mechanical assembly. The utility model comprises a rotating roller, a connecting block, a gear, a first cam divider and a second cam divider, wherein the front part of one side of the connecting block close to the rotating roller is fixedly provided with meshing teeth, the rear side of the connecting block is rotatably connected with one end of a connecting frame far away from the rotating roller, one sides of the front sides of two mutually meshed gears far away from each other are fixedly provided with counterweight strips, the middle of the front sides of the gears is fixedly provided with a clamping hook, the first cam divider is connected with the rear end of the rotating roller through a power output shaft, and the top output end of the second cam divider is fixedly provided with a rotating disc. According to the hook feeding assembly device, the rotating roller, the connecting block, the gear, the first cam divider and the second cam divider are arranged, so that the problems that the existing hook feeding assembly device cannot accurately feed materials to a specified position and cannot be well matched with an assembly structure are solved, the feeding precision is greatly improved during production, and the assembly after feeding can be well matched.

Description

Automatic change couple pay-off assembly device

Technical Field

The utility model belongs to the technical field related to mechanical assembly, and particularly relates to an automatic hook feeding and assembling device.

Background

The feeding is a machine which applies force to the material by means of the acting force of the movement of the machine to move and transport the material. The feeder is the indispensable equipment of light industry, heavy industry, and in the process of machinery streamlined processing production, can carry out more conveniently through material feeding unit and pay-off for the efficiency of production and processing, but it still has following drawback in the in-service use:

1. when the existing hook feeding and assembling device is used, the position of a material fed down by a hook is not determined enough, and the material cannot be accurately fed to a specified position;

2. the existing hook feeding and assembling device can only simply feed materials, cannot be matched with an assembled structure well, and the yield of produced products is insufficient.

Therefore, the requirement in practical use cannot be met currently, so that an improved technology for solving the above problems is urgently needed in the market.

Disclosure of Invention

The utility model aims to provide an automatic hook feeding and assembling device which solves the problems that the existing hook feeding and assembling device cannot accurately feed materials to a specified position and cannot be well matched with an assembled structure by arranging a rotary roller, a connecting block, a gear, a first cam divider and a second cam divider.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to an automatic hook feeding and assembling device which comprises a rotating roller, connecting blocks, gears, a first cam divider and a second cam divider, wherein four connecting frames are fixed on the circumferential side of the rotating roller in an annular array manner, the rear sides of two mutually meshed gears are rotatably connected with connecting plates, meshing teeth are fixed on the front parts of the connecting blocks, which are close to one side of the rotating roller, the rear sides of the connecting plates are rotatably connected with one ends of the connecting frames, which are far away from the rotating roller, counterweight strips are fixed on the mutually far sides of the front sides of the two mutually meshed gears, a clamping hook is fixed in the middle of the front sides of the gears, the first cam divider is connected with the rear end of the rotating roller through a power output shaft, a rotating disc is fixed on the top output end of the second cam divider, a placing seat is fixed on the circumferential side of the rotating disc, and the automatic hook feeding and assembling device intermittently rotates under the action of power output by the first cam divider through the rotating roller, the rotating roller rotates along with the rotation of the gear connected with the connecting frame through the connecting frame, and the gear moves on the periphery of the rotating roller through the structure on the gear, the part of the clamping hook faces downwards all the time, and an object clamped on the gear is placed through the placing seat on the rotating disc driven by the output power of the second cam divider.

Furthermore, the front end of the rotary roller is rotatably connected with a rotary seat, the rear end part of the rotary roller is inserted with a socket, and the rotary roller is supported on the ground through the cooperation of the rotary seat and the socket.

Furthermore, the meshing teeth are meshed with the gear close to the connecting block, a fixing column is fixed to the rear portion of one side, close to the rotating roller, of the connecting block, one side, far away from the connecting block, of the fixing column is fixed to a socket at the rear end portion of the rotating roller, and the meshing teeth are meshed with the gear, so that an object clamped by the clamping hooks on the gear falls onto the placing seat in the operation process of the gear.

Furthermore, the lower parts of the sides, close to each other, of the clamping hooks on the two gears meshed with each other are in contact with each other, the baffle plates are fixed on the lower parts of the front side and the rear side of each clamping hook, and the gear blocks the goods clamped on the gear through the baffle plates to prevent the gear from loosening.

Furthermore, a rotating motor is arranged on one side behind the first cam divider, a rotating base is fixed at the bottom of the rotating motor, a rotating shaft is fixed at the output end of the rotating motor, the rotating shaft is fixed with the input end of the first cam divider, a bottom block is fixed at the bottom of the first cam divider, and the first cam divider divides power generated by the rotating motor and then drives the rotating roller to rotate.

Furthermore, pillars are fixed at four corners of the bottom of the second cam divider, a driving motor is arranged on one side, away from the rotating roller, below the second cam divider, an output shaft of the driving motor is fixed with an input end of the second cam divider, a bottom plate is fixed at the bottom of the driving motor, the rotating time intervals of the first cam divider and the second cam divider are the same, the rotating period of the second cam divider lags behind that of the first cam divider, and the second cam divider divides power generated by the driving motor and then drives the rotating disc to rotate.

The utility model has the following beneficial effects:

1. the hook feeding assembly device comprises a rotary roller, a connecting block, a gear and a first cam divider, wherein the rotary roller is driven by a rotary motor to rotate under the power output of the first cam divider, two gears which are meshed with each other and connected with the rotary roller through a connecting frame are driven to do intermittent circular motion along with the rotary roller, the rotary roller is meshed with meshing teeth when moving to the positions corresponding to the meshing teeth, and the gear rotates in the process of meshing with the meshing teeth when continuously running, so that the two gears which are meshed with each other rotate, a clamping hook is loosened, and an object clamped on the clamping hook can be accurately placed on a corresponding placing seat.

2. The utility model solves the problem that the existing hook feeding assembly device can not be well matched with an assembled structure by arranging the rotating roller, the connecting block, the gear, the first cam divider and the second cam divider, the first cam divider intermittently works under the action of power generated by the rotating motor to drive the rotating roller to intermittently rotate, so that two mutually meshed gears connected through the connecting frame on the rotating roller are driven to rotate to the position corresponding to the connecting block, the clamping hook is loosened, the structure clamped on the rotating roller falls to the specified position of the placing seat on the second cam divider, and then the rotating roller is rotated away from the lower part of the connecting block through the rotation of the second cam divider, at the moment, the first cam divider rotates the rotating roller, so that the placed clamping hook rotates to the lower part of the rotating roller, the working periods of the first cam divider and the second cam divider are just staggered, the matching is completed, and when the hook feeding device feeds materials, the better adaptability is kept, the production efficiency is accelerated, and the generation of inferior-quality products in the production process is reduced.

Of course, it is not necessary for any product to practice the utility model to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a perspective view of an assembly structure of the present invention;

FIG. 2 is a perspective view of a roller structure according to the present invention;

FIG. 3 is a perspective view of the connection block structure of the present invention;

FIG. 4 is a perspective view of the gear structure of the present invention;

FIG. 5 is a perspective view of a first cam divider structure of the present invention;

FIG. 6 is a perspective view of a second cam divider structure of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

100. rotating the roller; 101. a connecting frame; 102. a socket; 103. rotating; 200. connecting blocks; 201. meshing teeth; 202. fixing a column; 300. a gear; 301. a weight strip; 302. clamping a hook; 303. a baffle plate; 304. a connecting plate; 400. a first cam divider; 401. rotating the motor; 402. a rotating shaft; 403. a power take-off shaft; 404. rotating the base; 405. a bottom block; 500. a second cam divider; 501. a drive motor; 502. a base plate; 503. a pillar; 504. a turntable; 505. placing the seat.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-6, the present invention is an automatic hook feeding and assembling device, including a rotating roller 100, a connecting block 200, a gear 300, a first cam divider 400 and a second cam divider 500, wherein four connecting frames 101 are fixed on the circumferential side of the rotating roller 100 in an annular array, the rotating roller 100 connects a connecting plate 304 to the connecting plate through the connecting frames 101, and changes positions with the rotation of the rotating roller 100, the connecting plate 304 is rotatably connected to the rear side of two gears 300 engaged with each other, the connecting plate 304 connects the two gears 300 engaged with each other, a meshing tooth 201 is fixed on the front portion of the connecting block 200 near one side of the rotating roller 100, the two gears 300 engaged with each other mesh with the meshing tooth 201 when rotating to a position corresponding to the meshing tooth 201, and when continuing to operate, the gear 300 rotates in the process of meshing with the meshing tooth 201, so that the two gears 300 engaged with each other rotate, the clamping hooks 302 are loosened, the structure clamped and hooked on the clamping hooks 302 is loosened and falls on the top of the placing seat 505, the structure moves along with the movement of the placing seat 505, the rear side of the connecting plate 304 is rotatably connected with one end, away from the rotating roller 100, of the connecting frame 101, the sides, away from each other, of the front sides of the two gears 300 which are meshed with each other are fixedly provided with the counterweight strip 301, when the counterweight strip 301 is used, the clamping hooks 302 on the two gears 300 which are meshed with each other always move towards each other and are finally clamped together, the clamping hooks 302 are fixed in the middle of the front sides of the gears 300, the clamping hooks 302 are clamped together, so that materials to be conveyed are clamped between the two clamping hooks 302, the first cam divider 400 is connected with the rear end of the rotating roller 100 through the power output shaft 403, when the first cam divider 400 is used, the power divided in the first cam divider 400 is conveyed to the rotating roller 100 through the power output shaft 403, a rotating disc 504 is fixed on the top output end of the second cam divider 500, the rotating disc 504 is driven by the power divided by the second cam divider 500 to rotate, so as to drive a placing seat 505 to rotate to the lower part of the corresponding clamp hook 302, so as to receive the material put down on the clamp hook 302, and the placing seat 505 is fixed on the peripheral side of the rotating disc 504.

As shown in fig. 1-4, the front end of the roller 100 is rotatably connected with a rotary seat 103, the rear end of the roller 100 is inserted with a socket 102, and the roller 100 is supported on the ground through the socket 102 and the rotary seat 103;

the engaging teeth 201 are engaged with the gear 300 close to the connecting block 200 to release the two clamping hooks 302 clamped together, a fixing column 202 is fixed at the rear part of one side of the connecting block 200 close to the rotating roller 100, one side of the fixing column 202 far away from the connecting block 200 is fixed with a socket 102 at the rear end part of the rotating roller 100, the connecting block 200 is connected to the socket 102 through the fixing column 202, and the connecting block 200 is supported on the ground;

the lower parts of the adjacent sides of the clamping hooks 302 on the two gears 300 which are meshed with each other are contacted with each other, the baffle plates 303 are fixed on the lower parts of the front side and the rear side of the clamping hooks 302, and the clamping hooks 302 hook the materials clamped and hooked thereon through the baffle plates 303 to prevent the materials from loosening;

when the device is used, the rotating roller 100 rotates under the power output of the first cam divider 400 driven by the rotating motor 401, the two mutually meshed gears 300 connected with the rotating roller through the connecting frame 101 are driven to do intermittent circular motion along with the rotating roller 100, when the device moves to the position corresponding to the meshing teeth 201, the device is meshed with the meshing teeth 201, and when the device continues to operate, the gear 300 rotates in the process of meshing with the meshing teeth 201, so that the two mutually meshed gears 300 rotate, the clamping hook 302 is loosened, the structure clamped and hooked on the clamping hook 302 is loosened, falls onto the top of the placing seat 505 and moves along with the movement of the dispensing seat 505.

As shown in fig. 1 to 6, a rotating motor 401 is disposed at one side behind the first cam divider 400, the rotating motor 401 generates power for driving the first cam divider 400 to work, a rotating base 404 is fixed at the bottom of the rotating motor 401, the rotating base 404 supports the rotating motor 401 on the ground, a rotating shaft 402 is fixed at an output end of the rotating motor 401, the rotating shaft 402 transmits the power generated by the rotating motor 401 to the first cam divider 400, the rotating shaft 402 is fixed with an input end of the first cam divider 400, a bottom block 405 is fixed at the bottom of the first cam divider 400, and the first cam divider 400 is supported on the ground through the bottom block 405;

pillars 503 are fixed at four corners of the bottom of the second cam divider 500, the second cam divider 500 is supported on the ground through the pillars 503, a driving motor 501 is arranged at one side of the lower part of the second cam divider 500, which is far away from the roller 100, the driving motor 501 generates power for driving the second cam divider 500 to work, an output shaft of the driving motor 501 is fixed with an input end of the second cam divider 500, a bottom plate 502 is fixed at the bottom of the driving motor 501, the driving motor 501 is supported on the ground through the bottom plate 502, the rotation time intervals of the first cam divider 400 and the second cam divider 500 are the same, and the rotation period of the second cam divider 500 lags behind the first cam divider 400, so that the second cam divider 500 starts to work and rotate after the first cam divider 400 rotates;

when the device is used, the first cam divider 400 works intermittently under the action of power generated by the rotating motor 401 to drive the rotating roller 100 to rotate intermittently, so that the two gears 300 which are meshed with each other and connected with the rotating roller 100 through the connecting frame 101 are driven to rotate to the position corresponding to the connecting block 200, the clamping hook 302 is loosened, the clamped structure on the clamping hook 302 falls to the designated position of the placing seat 505 on the second cam divider 500 and then rotates away from the lower part of the connecting block 200 through the rotation of the second cam divider 500, and at the moment, the first cam divider 400 rotates the rotating roller 100 to enable the placed clamping hook 302 to rotate to the lower part of the rotating roller 100.

The present invention is not limited to the above embodiments, and any modifications, equivalent substitutions and improvements of some technical features, which are made to the technical solutions described in the above embodiments, are all within the scope of the present invention.

Claims (6)

1. The utility model provides an automatic change couple pay-off assembly device, includes commentaries on classics roller (100), connecting block (200), gear (300), first cam divider (400) and second cam divider (500), its characterized in that: the four connecting frames (101) are fixed on the circumferential side annular array of the rotary roller (100), the rear sides of the two gears (300) which are meshed with each other are rotatably connected with a connecting plate (304), meshing teeth (201) are fixed on the front portions, close to one side of the rotary roller (100), of the connecting blocks (200), the rear sides of the connecting plates (304) are rotatably connected with one ends, far away from the rotary roller (100), of the connecting frames (101), weight bars (301) are fixed on the sides, far away from each other, of the front sides of the two gears (300) which are meshed with each other, clamping hooks (302) are fixed in the middle of the front sides of the gears (300), the first cam divider (400) is connected with the rear ends of the rotary roller (100) through a power output shaft (403), a rotary disc (504) is fixed on the top output end of the second cam divider (500), and a placing seat (505) is fixed on the circumferential side of the rotary disc (504).

2. The automatic hook feeding and assembling device as claimed in claim 1, wherein a rotary seat (103) is rotatably connected to the front end of the rotary roller (100), and a socket (102) is inserted into the rear end of the rotary roller (100).

3. An automatic hook feeding and assembling device as claimed in claim 1, wherein the engaging teeth (201) are engaged with a gear (300) close to the connecting block (200), a fixing column (202) is fixed to the rear portion of one side of the connecting block (200) close to the rotating roller (100), and a socket (102) at the rear end of the rotating roller (100) is fixed to one side of the fixing column (202) far away from the connecting block (200).

4. An automatic hook feeding and assembling device as claimed in claim 1, wherein the clamping hooks (302) of the two gears (300) engaged with each other are contacted with each other at the lower parts of the sides close to each other, and the baffle plates (303) are fixed at the lower parts of the front side and the rear side of the clamping hooks (302).

5. The automatic hook feeding and assembling device as claimed in claim 1, wherein a rotating motor (401) is arranged on one side behind the first cam divider (400), a rotating base (404) is fixed to the bottom of the rotating motor (401), a rotating shaft (402) is fixed to the output end of the rotating motor (401), the rotating shaft (402) is fixed to the input end of the first cam divider (400), and a bottom block (405) is fixed to the bottom of the first cam divider (400).

6. The automatic hook feeding and assembling device as claimed in claim 1, wherein pillars (503) are fixed at four corners of the bottom of the second cam divider (500), a driving motor (501) is arranged at one side of the bottom of the second cam divider (500) far away from the rotating roller (100), an output shaft of the driving motor (501) is fixed with an input end of the second cam divider (500), a bottom plate (502) is fixed at the bottom of the driving motor (501), the rotation time intervals of the first cam divider (400) and the second cam divider (500) are the same, and the rotation period of the second cam divider (500) lags behind that of the first cam divider (400).

Images