CN116511761B - Soldering tin wire preparation facilities - Google Patents

Abstract

The application relates to the field of welding wire processing, in particular to a soldering wire preparation device, which comprises a rosin boiling mechanism and a soldering wire extruding machine, wherein the rosin boiling mechanism comprises a storage container, the storage container is of a hemispherical shell-shaped rotary structure, a feed inlet is formed in the storage container, the storage container can circumferentially rotate around a rotary axis of the storage container, a material throwing hole is formed in the peripheral wall of the middle upper part of the storage container, a spherical heat conductor is arranged in the storage container, and the storage container and the spherical heat conductor are concentrically arranged. According to the application, the storage container, the spherical heat conductor, the heat source and the shell are arranged, so that the heat radiation intensity of rosin fragments attached to the inner wall of the storage container from the spherical heat conductor is basically consistent by arranging the storage container and the spherical heat conductor concentrically, the heated uniformity of the rosin fragments in the storage container is basically consistent, and finally, the forming quality of the soldering wire extruded by the soldering wire extruder is better.

Description

Soldering tin wire preparation facilities

Technical Field

The application relates to the field of welding wire processing, in particular to a soldering tin wire preparation device.

Background

The solder wire is generally called a solder wire, and is a solder material used for soldering electronic components. The soldering tin wire consists of two parts, namely tin alloy and an auxiliary agent, wherein the tin alloy is used as a filler to be added into the surface and gaps of the electronic component, and the auxiliary agent is used for wetting the welding position, so that a good welding spot can be formed at the welding position. The common soldering tin wire auxiliary agents include rosin, resin and the like, wherein the rosin soldering tin wire with rosin as the auxiliary agent is widely used at present, and the rosin is heated and decocted to be liquid, and then the liquid rosin liquid is extruded into the hollow thick soldering tin wire through a wire extruder.

The prior Chinese patent with the publication number of CN108907511B discloses a rosin boiling all-in-one machine, in order to avoid carbonization of rosin caused by overhigh local heating temperature, a cylinder is adopted to drive a discharging basket to move back and forth, so that the discharging basket can move back and forth on the upper surface of a heat conducting plate, and further carbonization of the rosin caused by long-time contact with the same heat source is avoided, the technical scheme solves the problem that the rosin is easy to be carbonized caused by high heating temperature to a certain extent, but the rosin boiling all-in-one machine still has the following problems: in the process that the cylinder drives the discharging basket to move back and forth on the surface of the heat conducting plate, the rosin materials at all positions in the height direction in the discharging basket are different in heat radiation intensity from the heat conducting plate, and the rosin materials in the discharging basket do not mix and flow in the height direction of the discharging basket, so that the heating uniformity of the rosin materials in the discharging basket is different, and the problem that the rosin materials at the bottom of the discharging basket are heated to carbonize and the rosin materials at the upper part of the discharging basket are not completely heated and melted still occurs.

Disclosure of Invention

Based on this, it is necessary to provide a solder wire preparation device to solve the problems of the existing rosin boiling all-in-one machine, which can improve the heating uniformity of the loose spice in the rosin boiling process, and further make the quality of the solder wire extruded by the extruding machine better.

The above purpose is achieved by the following technical scheme:

the utility model provides a soldering tin silk preparation facilities includes rosin system of decocting and soldering tin silk extruding machine, wherein rosin system of decocting includes the storage container, the storage container is hemispherical shell form revolution structure, the feed inlet has been seted up on the storage container, the storage container can be around its axis of revolution circumference rotation, the material throwing hole has been seted up to the well upper portion perisporium of storage container, be provided with spherical heat conductor in the storage container, storage container and spherical heat conductor concentric configuration, the intussuseption of spherical heat conductor is filled with the heat conduction medium, the heat source is equipped with in the spherical heat conductor, the heat generating end of heat source stretches into in the heat conduction medium, spherical heat conductor and storage container synchronous rotation, the outside of storage container is encircled and is installed the shell, shell and storage container are encircled and are formed the storage cavity, be provided with material transport mechanism between storage cavity and the soldering tin silk extruding machine, material transport mechanism is arranged in sending into the soldering tin silk extruding machine with the liquid rosin material in the storage cavity.

In one embodiment, the bottom center of the storage container is arched upwards to form a protruding part, and the top end of the protruding part is fixedly connected with the lower end of the spherical heat conductor.

In one embodiment, a connecting pipe is arranged at the center of the bottom of the storage container, the axis of the connecting pipe coincides with the rotation axis of the storage container, and the connecting pipe can rotate around the axis of the connecting pipe.

In one embodiment, the material conveying mechanism comprises a first storage box, the first storage box is arranged below the shell, a columnar storage cavity is formed in the first storage box, a first guide pipe is arranged between the shell and the first storage box, the columnar storage cavity is communicated with the storage cavity through the first guide pipe, a first check valve is arranged in the first guide pipe and used for limiting liquid loose perfume in the first storage box to flow back into the first guide pipe, one end, away from the first guide pipe, of the first storage box is provided with a second guide pipe, a second check valve is arranged in the second guide pipe and used for limiting liquid loose perfume in the second guide pipe to flow back into the first storage box, the connecting pipe can slide along the axis of the connecting pipe, a discharge guide pillar is arranged in the connecting pipe, and when the connecting pipe slides downwards, the discharge guide pillar can move into the columnar storage cavity so that the liquid loose perfume in the columnar storage cavity is extruded into the second guide pipe.

In one embodiment, the lower end of the connecting pipe is provided with an annular groove, the upper end of the first storage box is slidably connected in the annular groove, an elastic compression piece is arranged in the annular groove, and one end of the elastic compression piece, which is far away from the connecting pipe, is in elastic contact with the first storage box.

In one embodiment, the material conveying mechanism further comprises a second storage box, a second material guide pipe is connected between the second storage box and the first storage box, an air suction pipe is arranged on the inner top wall of the second storage box in a communicating mode, one end, far away from the second storage box, of the air suction pipe is connected with an air suction pump, and the air suction pump is used for pumping residual air in the second storage box.

In one embodiment, the material conveying mechanism further comprises a third storage box, a third material guiding pipe is arranged between the third storage box and the second storage box, an electric valve is arranged in the third material guiding pipe, one end, far away from the third material guiding pipe, of the third storage box is connected with a material guiding hose, one end, far away from the third storage box, of the material guiding hose is connected with a soldering tin wire extruding machine, a pressurizing mechanism is arranged on the third storage box, and the pressurizing mechanism is used for extruding liquid loose spice in the third storage box into the soldering tin wire extruding machine.

In one embodiment, the outer lower end of the housing is provided with a support bracket.

The beneficial effects of the application are as follows:

according to the application, the storage container, the spherical heat conductor, the heat source and the shell are arranged, so that the shortest straight line distance between rosin fragments attached to all parts on the inner wall of the storage container and the spherical heat conductor is basically the same, the heat radiation intensity from the spherical heat conductor, received by the rosin fragments attached to all parts on the inner wall of the storage container, is basically consistent, the heated uniformity degree of the rosin fragments in the storage container is basically consistent, and finally, the forming quality of the soldering tin wire extruded by the soldering tin wire extruder is better.

Drawings

FIG. 1 is a schematic diagram of the whole structure of a solder wire preparing device according to the present application;

FIG. 2 is a schematic diagram of a connection structure of a housing in a solder wire manufacturing apparatus according to the present application;

FIG. 3 is a schematic top view of the structure of FIG. 2;

FIG. 4 is a schematic view of the cross-sectional view A-A of FIG. 3;

FIG. 5 is an enlarged schematic view of the structure at B in FIG. 4;

fig. 6 is a schematic structural view of a beating exhaust assembly in a solder wire preparation device according to the present application.

Wherein:

100. a storage container; 110. a feed inlet; 111. an enlarged opening; 120. a material throwing hole; 130. a protruding portion; 140. a connecting pipe; 141. an annular groove; 142. an elastic compression member; 150. a toothed ring; 160. discharging guide posts; 200. a spherical heat conductor; 300. a heat source; 400. a housing; 410. a storage chamber; 420. an upper end cap; 500. a first storage bin; 501. a columnar storage cavity; 510. a first material guide pipe; 511. a first one-way valve; 520. a second material guiding pipe; 521. a second one-way valve; 600. a second storage bin; 610. a third material guide pipe; 611. an electric valve; 700. an air suction pipe; 710. a getter pump; 900. a third storage bin; 1000. a material guiding hose; 2000. a solder wire extruder; 2100. a molding outlet; 3000. a support frame; 4000. a base; 5000. a motor; 5100. a synchronous frame; 5200. a guide rod; 5300. a pinion gear.

Detailed Description

The present application will be further described in detail below with reference to examples, which are provided to illustrate the objects, technical solutions and advantages of the present application. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "coupled" as used herein includes both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present application, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

In the present application, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1-6, a solder wire preparation device includes a storage container 100, the storage container 100 is in a hemispherical shell-shaped rotary structure, a feed inlet 110 is formed in the center of the upper end of the storage container 100, a connecting pipe 140 is arranged in the center of the lower end of the storage container 100, the axis of the connecting pipe 140 coincides with the rotary axis of the storage container 100, a toothed ring 150 is fixedly arranged on the outer peripheral surface of the connecting pipe 140, a synchronous frame 5100 is further arranged on the outer periphery of the connecting pipe 140, the synchronous frame 5100 and the connecting pipe 140 rotate relatively, a motor 5000 is arranged on the synchronous frame 5100, a pinion 5300 is fixedly connected to an output shaft of the motor 5000, and the pinion 5300 is meshed with the toothed ring 150, so that the device is used for driving the storage container 100 to rotate through the motor 5000; the middle upper part of the storage container 100 is provided with a material throwing hole 120, the material throwing hole 120 is used for throwing out rosin materials melted into liquid state to the outside of the storage container 100, a spherical heat conductor 200 is arranged in the storage container 100, the spherical heat conductor 200 and the storage container 100 are concentrically configured, a heat conducting medium is filled in the spherical heat conductor 200, a heat source 300 is inserted in the spherical heat conductor 200, the heat source 300 is specifically an electric heating pipe, the heat generating end of the heat source 300 stretches into the heat conducting medium, the outside of the storage container 100 is surrounded and provided with a shell 400, the upper end of the shell 400 is movably provided with an upper end cover 420, the shell 400 and the storage container 100 are surrounded to form a storage cavity 410, the lower end of the outside of the shell 400 is provided with a support frame 3000 used for supporting the shell 400, the lower end of the support frame 3000 is connected with a base 4000, the lower end of the synchronous frame 5100 is connected to the base 4000, and the base 4000 is placed on the ground.

When in use, a worker firstly opens the upper end cover 420, pours solid rosin fragments into the storage container 100 through the feed inlet 110, stops feeding when the volume of the rosin blocks poured into the storage container 100 approaches to one half of the maximum volume of the storage container 100, closes the upper end cover 420, then starts the heat source 300 and the motor 5000, after the heat source 300 is started, the heat generation causes the heat conducting medium in the spherical heat conductor 200 to rise temperature, after the motor 5000 is started, the rotation of the motor 5000 drives the pinion 5300 to rotate, the pinion 5300 drives the toothed ring 150 to rotate, the toothed ring 150 drives the connecting pipe 140 to rotate, the connecting pipe 140 drives the storage container 100 to rotate around the rotation axis thereof, and the rosin fragments in the storage container 100 roll in a direction away from the center of the storage container 100 under the action of the centrifugal force, so that the rosin fragments in the storage container 100 are not accumulated on the lower part of the storage container 100 but are attached on the inner wall of the storage container 100, and the heat conducting medium in the spherical heat conductor 200 is concentric, after the motor 5000 is started, the rotation of the pinion 5300 drives the pinion 5300 to rotate, the toothed ring 150 drives the connecting pipe 140 to rotate, the rosin fragments in the same length as the heat conducting medium is attached on the inner wall of the storage container 100, and the rosin fragments in the same straight line as the heat conducting part is not heated by the storage container, and the heat conducting fragments are basically heated by the rosin fragments in the same length as the storage container;

after the rosin fragments are melted into liquid rosin materials, the fluidity of the rosin materials is increased, so that the rosin materials can move to a larger distance away from the center of the storage container 100 under the action of centrifugal force, the melted rosin materials can move to the area where the material throwing holes 120 are, the rosin materials are centrifugally thrown into the storage cavity 410 through the material throwing holes 120, the melted rosin materials are temporarily stored in the storage cavity 410, the liquid rosin materials stored in the storage cavity 410 are conveyed into the solder wire extruder 2000 through the material conveying mechanism, and thus solder wires are prepared through the solder wire extruder 2000.

It should be further noted that, in order to facilitate the worker to add rosin fragments into the storage container 100, the port of the feed inlet 110 may be further enlarged to be close to the inner wall of the storage chamber 410 to form the enlarged opening 111, so that the arrangement can facilitate the feeding operation of the worker and avoid unmelted rosin fragments from entering the storage chamber 410.

It will be appreciated that the spherical heat conductor 200 is disposed inside the storage container 100, and the resistance wire is not directly disposed inside the storage container 100 to heat the storage container 100, because the specific heat capacity of the liquid is generally larger than that of the solid, and the temperature is raised more uniformly in a liquid heating mode, so that the uniformity of the temperature of the spherical heat conductor 200 can be better.

It is also to be added that, since the melting point of rosin is between 172 ℃ and 173 ℃, silicone oil or other vegetable oil is preferably used as the heat conducting medium.

In a further embodiment, as shown in fig. 5, the bottom center of the storage container 100 is arched upwards to form a protrusion 130, the top end of the protrusion 130 is fixedly connected with the lower end of the spherical heat conductor 200, and two protrusions 130 are used, wherein the first function is to connect and support the storage container 100 and the spherical heat conductor 200 together, so that the spherical heat conductor 200 can synchronously rotate along with the storage container 100 when the storage container 100 rotates, and the second function is to prevent rosin fragments entering the storage container 100 from being extruded at the bottom center of the storage container 100 and not to centrifugally roll away from the center of the storage container 100 due to the friction force between the rosin fragments and the storage container 100.

In a further embodiment, as shown in fig. 1, 4 and 5, the material conveying mechanism further includes a first storage tank 500, the first storage tank 500 is disposed below the housing 400, a columnar storage cavity 501 is formed in the first storage tank 500, the columnar storage cavity 501 is communicated with the storage cavity 410 through a first guide pipe 510, a first guide pipe 510 is communicated between the housing 400 and the first storage tank 500, a first check valve 511 is disposed in the first guide pipe 510, the first check valve 511 is used for limiting the liquid loose perfume in the first storage tank 500 to flow back into the first guide pipe 510, a second guide pipe 520 is disposed at an end of the first storage tank 500 away from the first guide pipe 510, a second check valve 521 is disposed in the second guide pipe 520, the second check valve 521 is used for limiting the liquid loose spice in the second guide pipe 520 to flow back into the first storage tank 500, one end of the second guide pipe 520 away from the first storage tank 500 is connected with the second storage tank 600, the lower end of the connecting pipe 140 is provided with the annular groove 141, the upper end of the first storage tank 500 is slidably connected in the annular groove 141, the annular groove 141 is internally provided with the elastic compression piece 142, one end of the elastic compression piece 142 away from the connecting pipe 140 is elastically contacted with the first storage tank 500, the connecting pipe 140 is internally provided with the discharge guide pillar 160, and when the connecting pipe 140 slides downwards, the discharge guide pillar 160 can move downwards into the columnar storage cavity 501 to enable the liquid loose spice in the columnar storage cavity 501 to be extruded into the second guide pipe 520.

After the material is fed into the storage container 100, the elastic compression member 142 is compressed by force, the connecting pipe 140 and the storage container 100 move downwards, the discharging guide pillar 160 moves downwards along with the connecting pipe 140 to plug the cylindrical storage cavity 501, along with gradual melting of rosin fragments in the storage container 100, liquid loose spice is thrown into the storage container 100 through the throwing hole 120, along with continuous reduction of rosin material in the storage container 100, the compressed amount of the elastic compression member 142 gradually decreases, the discharging guide pillar 160 moves upwards gradually, so that liquid loose spice in the first guide pipe 510 flows into the cylindrical storage cavity 501, after the rosin fragments in the storage container 100 are completely melted and discharged, the compressed amount of the elastic compression member 142 is minimum, at this moment, a large amount of liquid loose spice is stored in the cylindrical storage cavity 501, at this moment, the upper end cover 420 is opened by a worker, the rosin fragments continue to be added into the storage container 100, after the rosin is added into the storage container 100, the connecting pipe 140 and the discharging guide pillar 160 gradually move downwards into the cylindrical storage cavity 501, the liquid loose spice in the cylindrical storage cavity 520 is fed into the second guide pipe 2000, the second guide wire is fed into the liquid storage container 2000, and the second guide wire is processed.

It should be noted that, compared with the previous embodiment, the first storage tank 500 is added to the present embodiment, and the first storage tank 500 mainly serves to temporarily store the liquid loose perfume, so that the liquid loose perfume directly fed into the solder wire extruder 2000 is prevented from having too high temperature to be easily extruded into wires.

It should be further noted that, in order to guide the movement of the synchronous frame 5100, two guide rods 5200 are further disposed on the base 4000, and the two guide rods 5200 are arranged at intervals, so that the synchronous frame 5100 can move synchronously when the connecting pipe 140 moves along the axis thereof through the sliding fit of the guide rods 5200 and the synchronous frame 5100.

In a further embodiment, as shown in fig. 6, the material conveying mechanism further includes a second storage box 600, a second material guiding pipe 520 is connected between the second storage box 600 and the first storage box 500, an air suction pipe 700 is provided in communication with an inner top wall of the second storage box 600, one end of the air suction pipe 700 away from the second storage box 600 is connected with an air suction pump 710, and the air suction pump 710 is used for sucking residual air in the second storage box 600;

after the rosin fragments in the storage container 100 are melted into liquid loose flavor, the worker opens the upper end cap 420 to continuously supplement the materials into the storage container 100, and starts the suction pump 710 after the supplement is completed, the suction pipe 700 forms negative pressure in the inner top wall area of the second storage box 600, so that the air in the second storage box 600 is pumped out, and the liquid loose flavor in the second storage box 600 can be sent to the solder wire extruder 2000 after the air in the second storage box 600 is pumped out.

It should be further noted that, in order to completely discharge the air in the liquid loose spice stored in the second storage tank 600 as much as possible, a rubber hammer may be placed around the second storage tank 600, and during the operation of the suction pump 710, a worker knocks the second storage tank 600 through the rubber hammer for multiple times, so that the air in the liquid loose spice is discharged as much as possible.

In a further embodiment, as shown in fig. 1, 4 and 6, the material conveying mechanism further includes a third storage tank 900, a third material guiding pipe 610 is disposed between the third storage tank 900 and the second storage tank 600, an electric valve 611 is disposed on the third material guiding pipe 610, one end of the third storage tank 900, which is far away from the third material guiding pipe 610, is connected with a material guiding hose 1000, one end of the material guiding hose 1000, which is far away from the third storage tank 900, is connected with a solder wire extruder 2000, a pressurizing mechanism is disposed on the third storage tank 900, and the pressurizing mechanism is used for pressurizing and extruding the liquid loose perfume in the third storage tank 900 into the solder wire extruder 2000.

After the air contained in the liquid loose flavor in the second storage tank 600 is discharged, the electric valve 611 is started, so that the liquid loose flavor in the second storage tank 600 enters the third storage tank 900 through the third material guiding pipe 610, the liquid loose flavor in the third storage tank 900 is sent into the solder wire extruder 2000 through the material guiding hose 1000 under the driving action of the pressurizing mechanism, and finally, the crude solder wire filled with the rosin liquid is extruded from the molding outlet 2100.

It should be further noted that the height of the second storage tank 600 should be higher than the height of the third storage tank 900, so that the liquid loose flavor in the second storage tank 600 can flow into the third storage tank 900 after the electric valve 611 is opened.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the application and are described in detail herein without thereby limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (5)

1. The device is characterized by comprising a rosin boiling mechanism and a soldering wire extruding machine, wherein the rosin boiling mechanism comprises a storage container which is of a hemispherical shell-shaped rotary structure, a feed inlet is formed in the storage container, the storage container can circumferentially rotate around a rotary axis of the storage container, a material throwing hole is formed in the peripheral wall of the middle upper part of the storage container, a spherical heat conductor is arranged in the storage container, the storage container and the spherical heat conductor are concentrically arranged, a heat conducting medium is filled in the spherical heat conductor, a heat source is inserted in the spherical heat conductor, the heat generating end of the heat source extends into the heat conducting medium, the spherical heat conductor and the storage container synchronously rotate, a shell is arranged around the outside of the storage container, a storage cavity is formed by surrounding the shell and the storage container, a material conveying mechanism is arranged between the storage cavity and the soldering wire extruding machine, and the material conveying mechanism is used for conveying liquid rosin material in the storage cavity into the soldering wire extruding machine;

the center of the bottom of the storage container is provided with a connecting pipe, the axis of the connecting pipe is coincident with the rotation axis of the storage container, and the connecting pipe can rotate around the axis of the connecting pipe;

the material conveying mechanism comprises a first material storage box, wherein the first material storage box is arranged below a shell, a columnar material storage cavity is formed in the first material storage box, a first material guide pipe is arranged between the shell and the first material storage box, the columnar material storage cavity is communicated with a material storage cavity through the first material guide pipe, a first one-way valve is arranged in the first material guide pipe and used for limiting liquid loose perfume in the first material storage box to flow back into the first material guide pipe, one end, far away from the first material guide pipe, of the first material storage box is provided with a second material guide pipe, the second material guide pipe is internally provided with a second one-way valve, the second one-way valve is used for limiting liquid loose perfume in the second material guide pipe to flow back into the first material storage box, a connecting pipe can slide along the axis of the connecting pipe, and when the connecting pipe slides downwards, the material guide pillar can move downwards into the columnar material storage cavity to enable the liquid loose perfume in the columnar material storage cavity to be extruded into the second material guide pipe;

the lower end of the connecting pipe is provided with an annular groove, the upper end of the first storage box is connected in the annular groove in a sliding way, an elastic compression piece is arranged in the annular groove, and one end of the elastic compression piece, which is far away from the connecting pipe, is in elastic contact with the first storage box;

the heat conducting medium is silicone oil.

2. The solder wire preparing device of claim 1, wherein the bottom center of the storage container is arched upwards to form a protruding part, and the top end of the protruding part is fixedly connected with the lower end of the spherical heat conductor.

3. The solder wire preparation device according to claim 1, wherein the material conveying mechanism further comprises a second storage box, a second material guiding pipe is connected between the second storage box and the first storage box, an air suction pipe is arranged on the inner top wall of the second storage box in a communicating mode, one end, far away from the second storage box, of the air suction pipe is connected with an air suction pump, and the air suction pump is used for pumping residual air in the second storage box.

4. A solder wire preparation device according to claim 3, wherein the material conveying mechanism further comprises a third material storage box, a third material guide pipe is arranged between the third material storage box and the second material storage box, an electric valve is arranged in the third material guide pipe, one end, far away from the third material guide pipe, of the third material storage box is connected with a material guide hose, one end, far away from the third material storage box, of the material guide hose is connected with a solder wire extruding machine, a pressurizing mechanism is arranged on the third material storage box, and the pressurizing mechanism is used for extruding liquid loose spice in the third material storage box into the solder wire extruding machine.

5. A solder wire preparing device according to claim 1, wherein the outer lower end of the housing is provided with a support frame.