CN219981171U - Chip mounting device for integrated circuit processing - Google Patents

Abstract

The utility model relates to the technical field of integrated circuit processing equipment, in particular to a chip mounting device for integrated circuit processing, which comprises a chip mounting machine, wherein a workbench of the chip mounting machine is connected with a positioning clamping structure, the side wall of the chip mounting machine is connected with a control switch, the positioning clamping structure comprises a fixed connecting plate, the fixed connecting plate is connected to the workbench of the chip mounting machine, and the end surface of the fixed connecting plate is connected with a fixed supporting plate.

Description

Chip mounting device for integrated circuit processing

Technical Field

The utility model relates to the technical field of integrated circuit processing equipment, in particular to a patch device for integrated circuit processing.

Background

At present, the chip mounting device for integrated circuit processing mostly adopts a fixed clamping mode in processing, so that when integrated circuits of different types are processed, different clamping and positioning devices are required to be replaced, the chip mounting device is not very convenient to use, and the chip mounting device for processing, which can clamp integrated circuit boards of different types, is required to be provided for the above problems.

Disclosure of Invention

The present utility model is directed to a chip mounter for processing an integrated circuit, so as to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the chip mounting device for integrated circuit processing comprises a chip mounter, wherein a workbench of the chip mounter is connected with a positioning and clamping structure, and a side wall of the chip mounter is connected with a control switch;

the positioning clamping structure comprises a fixed connecting plate, the fixed connecting plate is connected to a workbench of the chip mounter, a fixed supporting plate is connected to the end face of the fixed connecting plate, electric telescopic rods are symmetrically connected to the two sides of the fixed supporting plate on the end face of the fixed connecting plate, driving racks are connected to driving ends of the electric telescopic rods through connectors, driven gears are engaged and connected to the side walls of the driving racks, a rotating screw rod is connected to the center of each driven gear, a driving sliding block is connected to the side wall of each rotating screw rod, a transverse fixed clamping plate is connected to the end face of each driving sliding block, a transverse moving clamping plate is connected to the side wall of each transverse fixed clamping plate, a transverse adjusting screw rod is connected to the side wall of each transverse moving clamping plate, a driving connecting plate is connected to one side of each driving sliding block, a driving connecting rod is symmetrically connected to the side wall of each rotating connecting plate through a rotating shaft, the other ends of the driving connecting rods are connected to a fixed connecting rod through rotating shafts, a moving sliding block is connected to the end face of each fixed supporting plate, a sliding rail is correspondingly connected to the side wall of each driving sliding block, a cross sliding block is correspondingly connected to the corresponding driving sliding block, and a longitudinal clamping plate is connected to the longitudinal clamping plate, and the longitudinal clamping plate is longitudinally moves to the longitudinal clamping plate.

As a preferable scheme of the utility model, the electric telescopic rod is connected with the control switch through a wire and is electrically connected in a connection mode, and the rotating screw rod is connected to the end face of the fixed connecting plate through a bearing seat plate, wherein the rotating screw rod is connected with the bearing seat in a rotation mode.

As a preferable scheme of the utility model, the connection mode of the rotating screw rod and the driving sliding block is threaded connection, and a limit groove is formed on the side wall of the transverse moving clamping plate and corresponds to the transverse fixing clamping plate, wherein the connection mode of the transverse fixing clamping plate and the limit groove is sliding connection.

As a preferable scheme of the utility model, one end of the transverse adjusting screw rod is connected to the side wall of the transverse moving clamping plate through a bearing seat, wherein the transverse adjusting screw rod is connected with the bearing seat in a rotating way, the transverse adjusting screw rod is connected to the end face of the transverse fixing clamping plate through a connecting plate, and the transverse adjusting screw rod is connected with the connecting plate in a threaded way.

As a preferable scheme of the utility model, the two groups of rotating screw rods are arranged and are used for fixing the two sides of the supporting plate, one group of rotating screw rods is a left-handed screw rod, the other group of rotating screw rods is a right-handed screw rod, and the driving sliding block, the moving sliding block and the cross sliding rail are connected in a sliding manner.

As a preferable scheme of the utility model, a connecting groove is formed on the side wall of the longitudinal movable clamping plate and corresponds to the longitudinal fixed clamping plate, wherein the longitudinal fixed clamping plate is connected with the connecting groove in a sliding manner, one end of the longitudinal adjusting screw rod is connected with the side wall of the longitudinal movable clamping plate through a bearing seat, and the longitudinal adjusting screw rod is connected with the bearing seat in a rotating manner.

As a preferable scheme of the utility model, the longitudinal adjusting screw rod is connected to the end face of the longitudinal fixing clamping plate through the connecting plate, wherein the connecting mode of the longitudinal adjusting screw rod and the connecting plate is threaded connection.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the positioning and clamping structure is arranged in the paster device for integrated circuit processing, so that the integrated circuit board is positioned and clamped by utilizing the design that the electric telescopic rod in the positioning and clamping structure passes through the transmission structure, and the corresponding size of the device can be adjusted according to the size of the integrated circuit board in the using process of the paster device for integrated circuit processing, so that the device is more convenient in processing, and the problem that the integrated circuit boards of different types cannot be clamped is solved.

Drawings

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

FIG. 2 is a schematic view of a positioning and clamping structure according to the present utility model;

FIG. 3 is a schematic view of the portion of FIG. 2 according to the present utility model.

In the figure: 1. a chip mounter; 2. positioning and clamping structures; 3. a control switch; 201. fixing the connecting plate; 202. a fixed support plate; 203. an electric telescopic rod; 204. a drive rack; 205. a driven gear; 206. rotating the screw rod; 207. driving a sliding block; 208. transversely fixing the clamping plate; 209. transversely moving the clamping plate; 210. a transverse adjusting screw rod; 211. rotating the connecting plate; 212. a drive link; 213. a fixed connecting rod; 214. moving the slide block; 215. a cross slide rail; 216. longitudinally fixing the clamping plate; 217. longitudinally moving the clamping plate; 218. and (5) longitudinally adjusting the screw rod.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and all other embodiments obtained by those skilled in the art without making any inventive effort based on the embodiments of the present utility model are within the scope of protection of the present utility model.

In order that the utility model may be readily understood, several embodiments of the utility model will be described more fully hereinafter with reference to the accompanying drawings, in which, however, the utility model may be embodied in many different forms and is not limited to the embodiments described herein, but instead is provided for the purpose of providing a more thorough and complete disclosure of the utility model.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may also be present, and when an element is referred to as being "connected" to the other element, it may be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs, and the terms used herein in this description of the utility model are for the purpose of describing particular embodiments only and are not intended to be limiting of the utility model, with the term "and/or" as used herein including any and all combinations of one or more of the associated listed items.

Referring to fig. 1-3, the present utility model provides a technical solution:

the chip mounter for integrated circuit processing comprises a chip mounter 1, wherein a workbench of the chip mounter 1 is connected with a positioning and clamping structure 2, and a side wall of the chip mounter 1 is connected with a control switch 3;

in this embodiment, referring to fig. 1 and 3, in the case that the positioning and clamping structure 2 includes a fixed connection plate 201, the fixed connection plate 201 is connected to a workbench of the chip mounter 1, a fixed support plate 202 is connected to an end surface of the fixed connection plate 201, electric telescopic rods 203 are symmetrically connected to both sides of the fixed support plate 202 on the end surface of the fixed connection plate 201, and the electric telescopic rods 203 are started under the condition that the electric telescopic rods 203 are connected to the control switch 3 by wires and are electrically connected in such a manner that driving ends of the electric telescopic rods 203 move upward, driving racks 204 are connected to the driving ends of the electric telescopic rods 203 by connectors, driven gears 205 are driven to rotate under the condition that driven gears 205 are engaged and connected to side walls of the driving racks 204, a rotating screw rod 206 is connected to a center of the driven gears 205, the side wall of the rotating screw rod 206 is connected with a driving slide block 207, the end face of the driving slide block 207 is connected with a transverse fixed clamping plate 208, and the rotating screw rod 206 is connected with the end face of the fixed connecting plate 201 through a bearing seat plate, wherein the rotating screw rod 206 is driven to rotate under the condition that the rotating screw rod 206 is connected with a bearing seat in a rotating way, the driving slide block 207 is driven to move on the side wall of the rotating screw rod 206 under the condition that the rotating screw rod 206 is connected with the driving slide block 207 in a sliding way, the transverse clamping of an integrated circuit board is further realized, the side wall of the rotating screw rod 206 and one side of the driving slide block 207 are connected with a rotating connecting plate 211 at the same time of the transverse clamping of the integrated circuit board, the side wall of the rotating connecting plate 211 is symmetrically connected with a driving connecting rod 212 through a rotating shaft in a rotating way, the other end of the driving connecting rod 212 is rotationally connected with a fixed connecting rod 213 through a rotating shaft, the end surface of the fixed connecting rod 213 is connected with a movable slide block 214, and the movable slide block 214 moves on the cross slide rail 215 under the condition that the movable slide block 214 is in sliding connection with the cross slide rail 215, so that the longitudinal direction of the integrated circuit board is clamped at the same time;

in this embodiment, referring to fig. 1 and 2, a lateral movement clamping plate 209 is connected to a side wall having a lateral movement clamping plate 208, a lateral adjustment screw 210 is connected to a side wall of the lateral movement clamping plate 209, a rotation connecting plate 211 is connected to a side wall of the rotation screw 206 and located at one side of the driving slider 207, a driving connecting rod 212 is connected to the side wall of the rotation connecting plate 211 symmetrically through rotation of a rotation shaft, a fixing connecting rod 213 is connected to the other end of the driving connecting rod 212 through rotation of a rotation shaft, a movement slider 214 is connected to an end face of the fixing connecting rod 213, a cross slide rail 215 is connected to an end face of the fixing supporting plate 202 and corresponding to the driving slider 207 and the movement slider 214, a longitudinal movement clamping plate 216 is connected to an end face of the movement slider 214, a longitudinal movement clamping plate 217 is connected to a side wall of the longitudinal movement clamping plate 217, and a limit groove is formed on the side wall of the transverse moving clamping plate 209 and corresponds to the transverse fixed clamping plate 208, wherein the connection mode of the transverse fixed clamping plate 208 and the limit groove is sliding connection, one end of the transverse adjusting screw 210 is connected on the side wall of the transverse moving clamping plate 209 through a bearing seat, the connection mode of the transverse adjusting screw 210 and the bearing seat is rotating connection, the transverse adjusting screw 210 is connected on the end face of the transverse fixed clamping plate 208 through a connecting plate, the position between the two groups of transverse moving clamping plates 209 is adjusted under the condition that the connection mode of the transverse adjusting screw 210 and the connecting plate is threaded connection, the connection groove is formed on the side wall of the longitudinal moving clamping plate 217 and corresponds to the longitudinal fixed clamping plate 216, the connection mode of the longitudinal fixed clamping plate 216 and the connection groove is sliding connection, one end of a longitudinal adjusting screw rod 218 is connected to the side wall of the longitudinal moving clamping plate 217 through a bearing seat, wherein the longitudinal adjusting screw rod 218 is connected with the bearing seat in a rotating manner, the longitudinal adjusting screw rod 218 is connected to the end face of the longitudinal fixed clamping plate 216 through a connecting plate, and the distance between the two groups of longitudinal moving clamping plates 217 is adjusted under the condition that the longitudinal adjusting screw rod 218 is connected with the connecting plate in a threaded manner.

The working flow of the utility model is as follows: when the paster device for integrated circuit processing is used, firstly, the device is powered on to enable the device to be in a working state, then, according to the size of an integrated circuit board, a limit groove is formed on the side wall of a transverse moving clamping plate 209 and corresponds to a transverse fixed clamping plate 208, wherein the connection mode of the transverse fixed clamping plate 208 and the limit groove is sliding connection, one end of a transverse adjusting screw 210 is connected on the side wall of the transverse moving clamping plate 209 through a bearing seat, the connection mode of the transverse adjusting screw 210 and the bearing seat is rotation connection, the transverse adjusting screw 210 is connected on the end face of the transverse fixed clamping plate 208 through a connecting plate, the position between two groups of transverse moving clamping plates 209 is adjusted under the condition that the connection mode of the transverse adjusting screw 210 and the connecting plate is threaded connection, the side wall of the longitudinal moving clamping plate 217 and the connection groove is correspondingly formed with the longitudinal fixed clamping plate 216, one end of the longitudinal fixed clamping plate 216 is in sliding connection, one end of the longitudinal adjusting screw 218 is connected on the side wall of the longitudinal moving clamping plate 217 through a bearing seat, the connection mode of the longitudinal adjusting screw 218 and the bearing seat is rotation connection, the longitudinal adjusting screw 218 is connected on the end face of the connecting plate through the connecting plate 216, the electric wire is connected with the electric drive end 203 through the electric drive end of the electric telescopic rod 203, the electric telescopic rod is connected between the two groups of electric drive end rods 203 is connected with the electric drive end rods 203 through the electric telescopic rod, and the electric telescopic rod 203 is connected with the electric drive end of the electric drive end rods is in a telescopic rod 203, the side wall of the driving rack 204 is meshed with the driven gear 205 to drive the driven gear 205 to rotate, the rotating screw rod 206 is connected to the end face of the fixed connecting plate 201 through the bearing seat plate, the rotating screw rod 206 is driven to rotate under the condition that the rotating screw rod 206 is connected with the bearing seat in a rotating mode, the rotating screw rod 206 is connected with the driving slide block 207 in a threaded mode, the driving slide block 207 is connected with the cross slide rail 215 in a sliding mode, the driving slide block 207 moves on the side wall of the rotating screw rod 206, the integrated circuit board is clamped transversely, a rotating connecting plate 211 is symmetrically connected to the side wall of the rotating screw rod 206 through a rotating shaft, the other end of the driving connecting plate 212 is connected with a fixed connecting rod 213 through the rotating shaft, the end face of the fixed connecting rod 213 is connected with a moving slide block 214, and the moving slide block 214 is clamped longitudinally and simultaneously under the condition that the moving slide block 214 is connected with the cross slide rail 215.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an integrated circuit processing is with paster device, includes chip mounter (1), its characterized in that: a workbench of the chip mounter (1) is connected with a positioning clamping structure (2), and a side wall of the chip mounter (1) is connected with a control switch (3);

the positioning clamping structure (2) comprises a fixed connecting plate (201), the fixed connecting plate (201) is connected to a workbench of the chip mounter (1), a fixed supporting plate (202) is connected to the end face of the fixed connecting plate (201), electric telescopic rods (203) are symmetrically connected to the two sides of the fixed supporting plate (202) on the end face of the fixed connecting plate (201), a driving rack (204) is connected to the driving end of the electric telescopic rods (203) through a connector, a driven gear (205) is connected to the side wall of the driving rack (204) in a meshed manner, a rotating screw (206) is connected to the center of the driven gear (205), a driving sliding block (207) is connected to the side wall of the rotating screw (206), a transverse fixed clamping plate (208) is connected to the end face of the driving sliding block (207), a transverse moving clamping plate (209) is connected to the side wall of the transverse moving clamping plate (209), a rotating shaft (211) is connected to the side wall of the rotating screw (206) through a rotating connecting rod (211), the other end of the driving connecting rod (212) is rotationally connected with a fixed connecting rod (213) through a rotating shaft, a movable slide block (214) is connected to the end face of the fixed connecting rod (213), a cross slide rail (215) is correspondingly connected to the end face of the fixed supporting plate (202) and the driving slide block (207) and the movable slide block (214), a longitudinal fixed clamping plate (216) is connected to the end face of the movable slide block (214), a longitudinal movable clamping plate (217) is connected to the side wall of the longitudinal fixed clamping plate (216), and a longitudinal adjusting screw rod (218) is connected to the side wall of the longitudinal movable clamping plate (217).

2. The chip mounter for integrated circuit processing according to claim 1, wherein: the electric telescopic rod (203) is connected with the control switch (3) through a wire and is electrically connected in a connection mode, the rotating screw rod (206) is connected to the end face of the fixed connecting plate (201) through a bearing seat plate, and the rotating screw rod (206) is connected with the bearing seat in a rotation mode.

3. The chip mounter for integrated circuit processing according to claim 1, wherein: the connection mode of the rotating screw rod (206) and the driving sliding block (207) is threaded connection, and a limit groove is formed in the side wall of the transverse moving clamping plate (209) and corresponds to the transverse fixing clamping plate (208), wherein the connection mode of the transverse fixing clamping plate (208) and the limit groove is sliding connection.

4. The chip mounter for integrated circuit processing according to claim 1, wherein: one end of the transverse adjusting screw rod (210) is connected to the side wall of the transverse moving clamping plate (209) through a bearing seat, wherein the connecting mode of the transverse adjusting screw rod (210) and the bearing seat is rotary connection, the transverse adjusting screw rod (210) is connected to the end face of the transverse fixing clamping plate (208) through a connecting plate, and the connecting mode of the transverse adjusting screw rod (210) and the connecting plate is threaded connection.

5. The chip mounter for integrated circuit processing according to claim 1, wherein: the two groups of rotating screw rods (206) are arranged on two sides of the fixed support plate (202), one group of rotating screw rods (206) is a left-handed screw rod, the other group of rotating screw rods (206) is a right-handed screw rod, and the driving slide blocks (207), the moving slide blocks (214) and the cross slide rails (215) are connected in a sliding mode.

6. The chip mounter for integrated circuit processing according to claim 1, wherein: the side wall of the longitudinal moving clamping plate (217) is provided with a connecting groove corresponding to the longitudinal fixing clamping plate (216), wherein the connecting mode of the longitudinal fixing clamping plate (216) and the connecting groove is sliding connection, one end of the longitudinal adjusting screw rod (218) is connected to the side wall of the longitudinal moving clamping plate (217) through a bearing seat, and the connecting mode of the longitudinal adjusting screw rod (218) and the bearing seat is rotary connection.

7. The chip mounter for integrated circuit processing according to claim 1, wherein: the longitudinal adjusting screw rod (218) is connected to the end face of the longitudinal fixing clamping plate (216) through a connecting plate, and the connecting mode of the longitudinal adjusting screw rod (218) and the connecting plate is threaded connection.