CN222268675U - Solder ball production rack - Google Patents

Abstract

The utility model discloses a solder ball production rack, which comprises a base, a rack body fixedly arranged on the base and a pouring seat rotatably arranged in the rack body, wherein the rack body is provided with a plurality of pouring seats; the utility model can continuously produce the solder balls without interruption or pause, thereby improving the production efficiency, the molding plates can smoothly cast, slide, overturn and move under the control of the electric push rod, the continuity is realized in the whole production process, meanwhile, the casting raw materials can rapidly move horizontally along the sliding groove in the sliding process of the molding plates, and the raw materials in the molding grooves can be sufficiently cooled when the empty molding plates rotate, and the rapid cooling process is helpful for rapid solidification of the solder balls, thereby improving the production efficiency.

Description

Solder ball production rack

Technical Field

The utility model relates to the technical field of solder ball production frames, in particular to a solder ball production frame.

Background

Solder balls are small balls of solder formed on the surface of a laminate, solder mask or wire during soldering, typically after wave soldering or reflow. This may occur because moisture in the vicinity of the through holes on the printed board is heated to become steam when the printed board is soldered.

At present, in the process of producing the solder balls, raw materials are generally poured into a solder ball forming groove, after the raw materials are formed, a forming device can rotate to discharge the formed solder balls, then the solder balls are continuously poured for production, but after the solder balls are poured, a time for waiting for the raw materials to be formed is needed, the forming device needs to wait for the solder balls to be formed, and then the material can be turned over for discharging, so that the production time of the solder balls is prolonged, and the production efficiency of the solder balls is reduced.

Therefore, there is a need to design a solder ball production rack to solve the above problems.

Disclosure of utility model

The utility model aims to solve the defects in the prior art and provides a tin ball production rack.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

A solder ball production rack comprises a base, a rack body fixedly arranged on the base and a pouring seat rotatably arranged in the rack body;

The novel plastic forming machine comprises a frame body, and is characterized in that two forming plates are arranged in the frame body, a plurality of forming grooves which are distributed in a linear array are formed in the forming plates, grooves are formed in the frame body, sliding grooves are formed in the grooves, reversing ports are formed in two ends of each sliding groove, guide grooves are formed in the positions, opposite to the sliding grooves, of the frame body, a turnover mechanism is arranged between the grooves and the forming plates, and a driving mechanism is arranged on the frame body.

Preferably, the turnover mechanism comprises a gear fixedly installed at one end of the forming plate and a plurality of teeth which are in linear array distribution and meshed with the gear and fixedly installed at the positions of two ends in the slot, and a sliding block matched with the sliding slot is fixedly installed at one end of the gear away from the forming plate.

Preferably, a guide block matched with the guide groove is rotatably arranged at one end of the forming plate far away from the gear.

Preferably, the driving mechanism comprises an extension plate fixedly installed at one end of the guide block, a supporting plate fixedly installed on the extension plate and a vertical plate fixedly installed on the extension plate, an electric push rod is fixedly installed on the frame body, and the telescopic end of the electric push rod is fixedly connected with the vertical plate.

Preferably, the number of the molding grooves is the same as the number of the pouring openings on the pouring seat.

Preferably, the frame body is internally symmetrically provided with a material guide plate, and the base is symmetrically provided with a material receiving groove matched with the material guide plate.

The utility model has the following beneficial effects:

Through setting up shaping board and tilting mechanism, equipment can be continuously produce the solder ball, and need not interrupt or pause to improved production efficiency, through electric putter's control, the shaping board can cast smoothly, slide, upset and remove, make whole production process realize the continuity, the shaping board is in the slip in-process simultaneously, the raw and other materials of pouring can be rapidly along spout horizontal migration, and when the shaping board of empty rotates, the raw and other materials in the shaping groove can obtain fully cooling, this kind of quick refrigerated process helps solder ball solidification rapidly, production efficiency has been improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a solder ball production rack according to the present utility model;

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

FIG. 3 is a schematic view of the overall multi-angle structure of a solder ball production rack according to the present utility model;

FIG. 4 is an enlarged schematic view of the structure at B of FIG. 3;

In the figure, 1, a base; 11, a material collecting groove, 2, a frame body, 21, a material guiding plate, 22, a slot, 23, a chute, 24, a turnover opening, 25, a guide groove, 3, a pouring seat, 4, a forming plate, 41, a forming groove, 42, a turnover mechanism, 421, a gear, 422, teeth, 423, a sliding block, 43, a guide block, 5, a driving mechanism, 51, an extension plate, 511, a supporting plate, 512, a vertical plate, 52 and an electric push rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1 to 4, a solder ball production rack comprises a base 1, a rack body 2 fixedly installed on the base 1, and a pouring seat 3 rotatably installed in the rack body 2;

Two forming plates 4 are arranged in the frame body 2, a plurality of forming grooves 41 which are distributed in a linear array are formed in the forming plates 4, a groove 22 is formed in the frame body 2, a sliding groove 23 is formed in the groove 22, turnover openings 24 are formed in two ends of the sliding groove 23, a guide groove 25 is formed in the position, opposite to the sliding groove 23, of the frame body 2, a turnover mechanism 42 is arranged between the groove 22 and the forming plates 4, and a driving mechanism 5 is arranged on the frame body 2. Through the cooperation of two shaping boards 4, can realize the continuous production to the tin ball, and can cool off the shaping to the tin ball at the in-process that shaping board 4 removed, reduced tin ball refrigerated time, improved the production efficiency of tin ball.

Referring to fig. 2, the turnover mechanism 42 includes a gear 421 fixedly installed at one end of the forming plate 4 and a plurality of teeth 422 fixedly installed at positions of both ends in the slot 22 and in linear array distribution and engaged with the gear 421, and a slider 423 adapted to the chute 23 is installed at one end of the gear 421 away from the forming plate 4. During the moving process, the forming plate 4 can slide horizontally under the cooperation of the sliding block 423 and the sliding groove 23, and the forming plate 4 can be rotationally discharged under the cooperation of the gear 421 and the teeth 422.

Referring to fig. 3, the end of the forming plate 4 remote from the gear 421 is rotatably mounted with a guide block 43 fitted with the guide groove 25. The sliding of the guide block 43 in the guide groove 25 ensures a stable operation of the forming plate 4.

Referring to fig. 4, the driving mechanism 5 includes an extension plate 51 fixedly installed at one end of the guide block 43, a stay plate 511 fixedly installed on the extension plate 51, and a vertical plate 512 fixedly installed on the extension plate 51, and the frame 2 is fixedly installed with an electric push rod 52, and a telescopic end of the electric push rod 52 is fixedly connected with the vertical plate 512. When the electric push rod 52 stretches, the vertical plate 512, the supporting plate 511 and the extending plate 51 drive the guide block 43 and the forming plate 4 to move, so that the forming plate 4 is driven.

Referring to fig. 1, the number of molding grooves 41 is the same as the number of pouring openings in the pouring bed 3. It is ensured that the raw material can enter the forming groove 41 for forming when the pouring seat 3 is poured.

Referring to fig. 3, a material guiding plate 21 is symmetrically arranged in a frame body 2, and a material receiving groove 11 matched with the material guiding plate 21 is symmetrically arranged on a base 1. The tin balls formed during the overturning of the forming plate 4 can enter the collecting groove 11 through the material guiding plate 21 for collection.

The specific working principle of the utility model is as follows:

Firstly, under the initial state, one forming plate 4 is located under the pouring seat 3, at this moment, the pouring seat 3 can be opened to pour raw materials into the forming groove 41 on the forming plate 4, after pouring is completed, the electric push rod 52 can be opened to drive the guide block 43 and the forming plate 4 to slide along the guide groove 25 through the vertical plate 512, the supporting plate 511 and the extending plate 51, the forming plate 4 of pouring raw materials can slide horizontally along the sliding groove 23 through the sliding block 423 in the sliding process of the forming plate 4, at this moment, the other empty forming plate 4 can rotate under the action of the gear 421 and the teeth 422, the empty forming plate 4 can rotate to a horizontal state when the forming plate 4 of the raw materials to be poured starts to overturn, the raw materials in the forming groove 41 in the process can be cooled, the electric push rod 52 can be continuously opened to drive the empty forming plate 4 to move under the pouring seat 3, the forming plate 4 of the raw materials can overturn under the action of the gear 421 and the teeth 422, the solder balls after cooling in the forming groove 41 can drop onto the guide plate 21 under the action of gravity and enter the receiving groove 11, the continuous production time is shortened, and the working principle of the continuous production of the solder balls can be shortened, and the production time is shortened continuously and the production time is shortened.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. A solder ball production rack, comprising a base (1), a frame body (2) fixedly mounted on the base (1), and a casting seat (3) rotatably mounted in the frame body (2); The invention is characterized in that two forming plates (4) are arranged in the frame (2), a plurality of forming grooves (41) distributed in a linear array are provided on the forming plate (4), a slot (22) is provided in the frame (2), a slide groove (23) is provided in the slot (22), reversing openings (24) are provided at both ends of the slide groove (23), a guide groove (25) is provided at a relative position between the frame (2) and the slide groove (23), a flipping mechanism (42) is provided between the slot (22) and the forming plate (4), and a driving mechanism (5) is provided on the frame (2). 2. A solder ball production rack according to claim 1, characterized in that the flip mechanism (42) includes a gear (421) fixedly mounted on one end of the forming plate (4) and a plurality of teeth (422) fixedly mounted at both ends of the slot (22) and distributed in a linear array and meshing with the gear (421), and a slider (423) adapted to the slide groove (23) is fixedly mounted on one end of the gear (421) away from the forming plate (4). 3. A solder ball production rack according to claim 2, characterized in that a guide block (43) adapted to the guide groove (25) is rotatably mounted on one end of the forming plate (4) away from the gear (421). 4. A solder ball production rack according to claim 3, characterized in that the driving mechanism (5) includes an extension plate (51) fixedly mounted on one end of the guide block (43), a support plate (511) fixedly mounted on the extension plate (51), and a vertical plate (512) fixedly mounted on the extension plate (51), and an electric push rod (52) is fixedly mounted on the frame body (2), and the telescopic end of the electric push rod (52) is fixedly connected to the vertical plate (512). 5. A solder ball production rack according to claim 1, characterized in that the number of the molding grooves (41) and the number of the pouring ports on the pouring seat (3) are the same. 6. A solder ball production rack according to claim 1, characterized in that a material guide plate (21) is symmetrically arranged inside the rack body (2), and a material receiving groove (11) adapted to the material guide plate (21) is symmetrically opened on the base (1).