CN216938380U - Lead liquid adding device for cast welding of lead-acid storage battery - Google Patents

Abstract

A lead liquid adding device for cast welding of a lead-acid storage battery comprises a lead liquid pouring plate, wherein one side of the lead liquid pouring plate is provided with a lead liquid inlet, a lead liquid storage tank communicated with the lead liquid inlet is arranged inside the lead liquid pouring plate, a vertical lead liquid pouring runner is also arranged in the lead liquid pouring plate, one end of the lead liquid pouring runner is communicated with the lead liquid storage tank, and the other end of the lead liquid pouring runner is communicated with the outside of the lead liquid pouring plate; and the blocking piece can vertically reciprocate along the lead liquid pouring flow channel in the lead liquid pouring flow channel, and the outer surface of the blocking piece and the inner surface of the lead liquid pouring flow channel can contact to form a sealing surface in the process of vertical reciprocating motion so as to open or close the lead liquid pouring flow channel. The utility model has compact structure, the lead liquid flowing and filling channels are all arranged in the lead liquid filling plate, and the lead liquid can be directly and quantitatively filled into the cavity of the busbar die by controlling the time for forming the sealing surface by lifting the blocking piece.

Description

Lead liquid adding device for cast welding of lead-acid storage battery

Technical Field

The utility model relates to the field of cast welding of bus bars of lead-acid storage batteries, in particular to a lead liquid adding device for cast welding of lead-acid storage batteries.

Background

In the manufacturing process of the lead-acid storage battery, cast welding is an important process in the manufacturing process of the lead-acid storage battery. The cast-weld method of the existing lead-acid storage battery generally comprises the following procedures of immersing a bus bar mould in lead liquid of a lead furnace to enable a cavity on the bus bar mould to be fully immersed in the lead liquid, then taking the bus bar mould out of the lead furnace, then reversely buckling a battery bottom box provided with a plurality of electrode groups on the bus bar mould to enable tabs of the electrode groups to be inserted into the lead liquid of the cavity on the bus bar mould for cast-weld, cooling the bus bar mould, and then taking the battery bottom box out of the bus bar mould. Therefore, the key step of cast-weld is to fill the lead-dipping liquid into the cavity of the busbar mold, and the prior art generally adopts the steps of dipping the whole busbar mold into a lead furnace, taking out the busbar mold, and then dipping the cavity into the lead-dipping liquid. The method has a plurality of defects, one is that the lead liquid amount in the cavity of the busbar die cannot be accurately controlled; secondly, the lead liquid in the lead furnace needs to be kept at a sufficient temperature and liquid level height all the time, and particularly, the lead furnace needs to be heated again after the lead furnace stops working, so that the energy consumption is very high; and thirdly, the whole bus bar die is immersed, so that lead slag is remained on the surface of the bus bar die, and the lead slag curing die needs to be scraped off the surface of the bus bar die at regular time. If the quantitative control of the lead liquid filling of the busbar die cavity can be realized, the lead liquid can be quantitatively supplied according to the requirement, the energy consumption can be greatly saved, and lead slag on the surface of the busbar die cavity cannot be caused to remain.

Several solutions for controlling the amount of lead liquid have been disclosed in the prior art. For example, in the utility model patent with the publication number of "CN 102806338A" entitled "storage battery grid casting machine and lead liquid control device thereof," the telescopic component is used to drive the control plate to rotate around the first support, so as to drive the second valve body to slide up and down, and the valve core moves up and down to control the opening and closing mode of the liquid inlet channel, although the supply of lead liquid can be controlled, the quantitative control of lead liquid filling to the cavity of the busbar mold is not applicable. Firstly, the structure of the technical scheme for controlling the opening and closing of the lead liquid channel is very complex, and the overall structure layout in the storage battery cast welding device is not facilitated. And the second valve body slides up and down, the valve core controls the opening and closing of the liquid inlet channel from the outside, lead liquid can pass through the area between the second valve body and the valve core when flowing out, lead slag of the lead liquid is more remained, and uncertain factors are brought by controlling the lead liquid in a given amount.

Therefore, the lead liquid adding device which is compact and simple in structure and can quantitatively fill the lead liquid into the cavity of the busbar die has important significance in the field.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the technical scheme adopted by the utility model is as follows: the lead-acid storage battery cast welding lead liquid adding device comprises a lead liquid pouring plate, wherein a lead liquid inlet is formed in one side of the lead liquid pouring plate, a lead liquid storage tank communicated with the lead liquid inlet is formed in the lead liquid pouring plate, a vertical lead liquid pouring runner is further formed in the lead liquid pouring plate, one end of the lead liquid pouring runner is communicated with the lead liquid storage tank, and the other end of the lead liquid pouring runner is communicated with the outside of the lead liquid pouring plate; and the plug piece can vertically reciprocate in the lead liquid pouring flow channel along the lead liquid pouring flow channel, and the outer surface of the plug piece can contact with the inner surface of the lead liquid pouring flow channel in the vertical reciprocating process to form a sealing surface so as to open or close the lead liquid pouring flow channel.

Furthermore, the lead liquid pouring plate consists of an upper cover plate and a lower bottom plate, a lead liquid inlet is formed in one side of the lower bottom plate, a lead liquid storage tank is formed in the upper surface of the lower bottom plate in an open mode, and a vertical lead liquid pouring flow channel is formed in the lower bottom plate and communicated with the outside from the bottom of the lower bottom plate; the upper cover plate is covered on the lower bottom plate, and the plugging piece penetrates through the upper cover plate and extends into the lead liquid pouring flow passage.

Further, a sealing plate is also included between the upper cover plate and the lower base plate.

Furthermore, the internal space of the lead liquid pouring runner is formed by connecting an upper cylindrical section and a lower inverted cone section, and the small end of the lower inverted cone section is communicated with the outside of the lead liquid pouring plate; the plug also comprises a cylindrical connecting section and an inverted cone sealing section, wherein the conical surfaces of the inverted cone sealing section and the inverted cone section at the lower part can be contacted with each other in the vertical up-and-down reciprocating motion process of the plug to form a sealing surface.

Furthermore, the lower inverted cone section is also connected with a pouring port, and the pouring port extends out of the lead liquid pouring plate; the back taper sealing section is connected with the dredging section, and the dredging section extends out of one end of the filling opening when the plugging piece vertically reciprocates up and down to form a sealing surface.

Further, the lead liquid fills the runner and fills the board outside through filling the head intercommunication with the lead liquid, and the cylindrical section in part upper portion, whole lower part back taper body section and fill the mouth and all set up inside filling the head.

Furthermore, the top end of the plug and the upper cover plate are connected with a lifting plate, and a lifting driving device drives the lifting plate to vertically lift and drives the plug to vertically reciprocate up and down.

Furthermore, the lifting plate is divided into an independent pole lifting plate and a connection piece lifting plate, and the pole lifting plate and the connection piece lifting plate are respectively connected with an independent lifting driving device.

Furthermore, a limiting plate is arranged above the connecting lifting plate, the limiting plate limits the descending stroke of the lifting plate through vertical up-and-down motion of the lifting plate, and when the lifting plate is limited, the conical surfaces of the inverted cone sealing section of the plug and the lower inverted cone section of the lead liquid filling flow channel are in mutual contact to form a sealing surface.

Further, a mounting plate is further arranged above the limiting plate, the lifting driving device is fixedly mounted on the mounting plate, the limiting plate, the lifting plate and the lead liquid pouring plate are all arranged in parallel, a supporting plate is mounted on the side faces of the mounting plate, the limiting plate, the lifting plate and the lead liquid pouring plate, and two ends of the supporting plate are connected with the mounting plate, the limiting plate and the lead liquid pouring plate; an air cooling area is reserved in front of the mounting plate and the limiting plate.

The utility model has the following advantages:

1. the lead-acid storage battery cast-weld lead liquid adding device has a compact structure, lead liquid flowing and filling channels are arranged in a lead liquid filling plate, and a blocking piece reciprocates up and down in the lead liquid filling channel and is in contact with the inner surface of the lead liquid filling channel to form a sealing surface to control the opening and closing of the lead liquid filling channel. The lead liquid filling flow channel filling opening can be directly aligned to the busbar mold cavity, and the busbar mold cavity can be directly and quantitatively filled with lead liquid by utilizing the time control of lifting the blocking piece to form a sealing surface.

Drawings

FIG. 1: the structure schematic diagram of the lead liquid pouring plate and the plug;

FIG. 2: FIG. 1 is a cross-sectional view;

FIG. 3: a local enlarged view of the blocking piece and the lead liquid pouring flow channel;

FIG. 4: a schematic diagram of a lifting plate structure;

FIG. 5: a corresponding relation diagram of the position layout of the lifting plate, the plugging piece and the busbar mold cavity;

FIG. 6: the overall structure of the lead liquid adding device is schematically shown.

Detailed Description

In order that those skilled in the art will be able to fully practice the present invention, it will be further described with reference to the accompanying drawings and specific examples.

As shown in fig. 1 and fig. 2, the lead liquid adding device for cast welding of a lead-acid storage battery comprises a lead liquid pouring plate 1, wherein one side of the lead liquid pouring plate 1 is provided with a lead liquid inlet 2, a lead liquid storage tank 3 communicated with the lead liquid inlet 2 is arranged inside the lead liquid pouring plate 1, a vertical lead liquid pouring runner 4 is also arranged inside the lead liquid pouring plate 1, one end of the lead liquid pouring runner 4 is communicated with the lead liquid storage tank 3, and the other end of the lead liquid pouring runner is communicated with the outside of the lead liquid pouring plate 1; the inside of the lead liquid pouring flow channel 4 is also provided with a blocking piece 5, the blocking piece 5 can vertically reciprocate along the lead liquid pouring flow channel 4 in the lead liquid pouring flow channel 4, and the outer surface of the blocking piece 5 can contact with the inner surface of the lead liquid pouring flow channel 4 to form a sealing surface in the vertical reciprocating motion process so as to open or close the lead liquid pouring flow channel 4.

When the embodiment is applied to the storage battery cast-weld machine, the busbar mold 300 is only required to be arranged below the lead liquid filling flow channel 4, lead liquid is filled from the lead liquid inlet 2, and flows through the lead liquid storage tank 3 by utilizing the self gravity, and the lead liquid filling flow channel 4 is directly filled into the cavity of the busbar mold 300. Because the runner that the lead liquid flowed through all sets up in the inside that the lead liquid filled board 1, and piece 5 also sets up inside lead liquid fills runner 4, and the compact structure of this embodiment is simple, and piece 5 rises and to open lead liquid and fill runner 4, and the decline forms and closes lead liquid and fill runner 4 behind the sealed face, so can fill accurate control to the lead liquid. Because the setting of plug 5 is inside lead liquid fills runner 4, directly fills the die cavity that gets into busbar mould 300 after the lead liquid flows out, and other parts do not flow through during, and lead liquid lead slag remains fewly to plug 5 also can take away remaining lead liquid lead slag in the up-and-down motion process.

Fig. 2 shows a cross-sectional view of an embodiment of a lead liquid pouring plate 1, wherein the lead liquid pouring plate 1 is composed of an upper cover plate 11 and a lower base plate 12, a lead liquid inlet 2 is arranged at one side of the lower base plate 12, a lead liquid storage tank 3 is arranged on the upper surface of the lower base plate 12 in an open mode, and a vertical lead liquid pouring flow channel 4 is arranged in the lower base plate 12 and communicated with the outside from the bottom of the lower base plate; an upper cover plate 11 covers the lower bottom plate 12, and the blocking piece 5 penetrates through the upper cover plate 11 and extends into the lead liquid pouring flow passage 4. The manufacturing process of the lead liquid pouring plate 1 can be simplified by dividing the lead liquid pouring plate 1 into an upper cover plate 11 and a lower base plate 12, the upper cover plate 11 can be a whole plate provided with a corresponding through hole for the plugging piece 5 to pass through, and a sealing plug 111 is arranged in the through hole for the plugging piece 5 to pass through in the top surface of the upper cover plate 11. Lead liquid storage tank 3 in lower plate 12 then is open groove, lead liquid fills runner 4 can follow lead liquid storage tank 3 directly link up to lower plate 12 bottom surface can, processing is simple and convenient to can dismantle upper cover plate 11 and lower plate 12 separation, fill runner 4 maintenance clearance to lead liquid storage tank 3 and lead liquid. Of course, if the processing and maintenance are not considered, the lead liquid pouring plate 1 can also be integrally formed by pouring.

The upper cover plate 11 and the lower base plate 12 are designed separately, the joint surface between the upper cover plate and the lower base plate needs to be considered for sealing to prevent lead liquid from flowing out, a sealing plate 13 can be arranged between the upper cover plate and the lower base plate, and the sealing plate 13 can be made of high-temperature-resistant materials such as asbestos plates.

As shown in fig. 2 and 3, a preferred design of the lead liquid pouring channel 4 and the plug 5 is that the inner space of the lead liquid pouring channel 4 is formed by connecting an upper cylindrical section 41 and a lower inverted cone section 42, and the small end of the lower inverted cone section 42 is communicated with the outside of the lead liquid pouring plate 1; the closure 5 is also composed of a cylindrical connecting section 51 and an inverted cone sealing section 52, wherein the conical surfaces of the inverted cone sealing section 52 and the lower inverted cone section 42 can contact each other to form a sealing surface during the vertical up-down reciprocating motion of the closure 5. The inner diameters of the cylindrical connecting section 51 and the inverted cone sealing section 52 of the blocking piece 5 can be smaller than the inner diameter of the lead liquid pouring runner 4, so that the up-and-down movement is not blocked, but the inclination of the conical surface of the inverted cone sealing section 52 needs to be matched with the inclination of the inverted cone section 42 at the lower part, so that a sealing surface with a larger area can be formed after the two contact. This structural design allows for a faster flow rate of the lead liquid due to the cone closing effect when the lead liquid flows in the lower inverted cone section 42. Alternatively, other structures can be adopted, such as a fitting sealing mode directly adopting a cylindrical surface, but the mode may require that the plug 5 rises and is completely separated from the inside of the lead liquid perfusion flow channel 4, so that the lead liquid perfusion flow channel 4 can be opened to enable the lead liquid to flow out.

On the basis, the lower inverted cone section 42 is also connected with a pouring port 43, and the pouring port 43 extends out of the lead liquid pouring plate 1; the inverted cone sealing section 52 is connected with the dredging section 53, and the dredging section 53 extends out of one end of the pouring opening 43 when the plugging piece 5 vertically reciprocates up and down to form a sealing surface. In this embodiment, fill mouth 43 for the cylinder cavity of small bore, lead liquid flows out from the cylinder cavity behind lower part back taper body section 42, and the velocity of flow is more stable. The inner diameter of the dredging section 53 is matched with the cylindrical cavity of the pouring opening 43, and when the dredging section extends out of one end of the pouring opening 43, the lead slag in the pouring opening 43 or the lead liquid pouring flow channel 4 can be dredged and ejected out.

The above-mentioned design to the inside cavity of lead liquid pouring runner 4 is comparatively complicated, if directly to the whole processing of lower plate 12 and form above-mentioned structure, processing has certain degree of difficulty. In the preferred embodiment of the present invention, the lead liquid pouring channel 4 is communicated with the outside of the lead liquid pouring plate 1 through the pouring head 6, and a part of the upper cylindrical section 41, the whole lower inverted cone section 42 and the pouring opening 43 are all opened inside the pouring head 6. The filling head 6 can be internally processed to form a cylindrical section 41, a lower inverted cone section 42 and a filling opening 43, and then the filling head 6 is mounted on the lower bottom plate 12 and at one end of the lead liquid filling flow channel 4.

As shown in fig. 4, the plugging member 5 needs to be controlled to move up and down to open and close the sealing surface, in this embodiment, the lifting plate 7 is connected to the top end of the plugging member 5 and above the upper cover plate 11, and the lifting driving device 8 drives the lifting plate 7 to vertically lift and drives the plugging member 5 to vertically reciprocate up and down. This structural design makes lifter plate 7 can drive the perpendicular up-and-down reciprocating motion of a plurality of stifled pieces 5 of control, and the design of 1 range upon range of lifter plate 7 and lead liquid filling plate, compact structure. The lift driving device 8 employs a cylinder in the present embodiment.

As shown in fig. 5, the cavities of the busbar mold 300 are divided into a connecting sheet cavity 302 and a terminal cavity 301, wherein the connecting sheet cavity 302 is used for connecting the positive and negative electrodes between the electrode groups in series, and the internal volumes of the connecting sheet cavity 302 are consistent, and the terminal cavity 301 is used for connecting the positive and negative electrodes leading-out ends of the electrode groups, and has two groups with consistent volumes. Therefore, the lead solution filling amounts of the connecting sheet cavity 302 and the terminal cavity 301 are different, and the lead solution filling amounts need to be controlled independently and quantitatively.

Therefore, the lifting plate 7 is divided into an independent pole lifting plate 71 and a connecting plate lifting plate 72 which respectively drive the blocking pieces 5 connected with the pole lifting plate 71 and the connecting plate lifting plate 72 to lift, and the pole lifting plate 71 and the connecting plate lifting plate 72 are respectively connected with an independent lifting driving device 8. In a typical embodiment, as shown in fig. 5, in a general battery cast-weld machine, a busbar mold 300 has three sets of cavities, each set of cavities has five sets of connecting plate cavities 302 and two sets of pole cavities 301, and a cast-weld station fills two molds with lead liquid at the same time. Therefore, in this embodiment, in order to facilitate the arrangement and installation of the lifting plates 7 and the independent control, all the connecting-piece molten lead pouring channel plugs 502 corresponding to the molten lead pouring channels 4 of the connecting-piece cavity 302 are connected to one connecting-piece lifting plate 72. And the polar column lead liquid filling flow channel blocking piece 501 of the lead liquid filling flow channel 4 corresponding to the polar column cavity 301 is connected to the two polar column lifting plates 71 and respectively corresponds to the positive and negative polar column cavities 301. Therefore, the two polar column lifting plates 71 and the connecting sheet lifting plate 72 are independently controlled to lift, so that the lead liquid plugging and sealing time of the polar column lead liquid pouring flow channel plugging piece 501 and the connecting sheet lead liquid pouring flow channel plugging piece 502 can be respectively controlled, and further different lead liquid pouring amounts of the connecting sheet cavity 302 and the polar column cavity 301 can be controlled. Two utmost point post lifter plates 71 and a connection piece lifter plate 72 parallel arrangement, connection piece lifter plate 72 are located the intermediate position, and the overall arrangement setting of stifled piece 5 just in time corresponds the overall arrangement of connection piece die cavity 302 and utmost point post die cavity 301 like this.

When the plugging member 5 descends to make the conical surfaces of the inverted cone sealing section 52 and the lower inverted cone section 42 contact with each other to form a sealing surface, at this time, if the plugging member 5 continues to descend, the plugging member will collide with the conical surface of the lower inverted cone section 42, and therefore, the descending stroke of the plugging member 5 needs to be limited. As shown in fig. 6, a limiting plate 9 is further disposed above the lifting plate 7, the limiting plate 9 limits the descending stroke of the lifting plate 7 when the lifting plate 7 moves vertically up and down, and when the lifting plate 7 is limited, the tapered surfaces of the inverted cone sealing section 52 of the plug 5 and the inverted cone section 42 of the lead liquid pouring channel 4 contact with each other to form a sealing surface.

In order to make the device compact as much as possible, the whole device can be designed into a laminated and frame structure. As shown in fig. 6, a mounting plate 10 is further arranged above the limiting plate 9, the lifting driving device 8 is fixedly mounted on the mounting plate 10, the limiting plate 9, the lifting plate 7 and the lead liquid pouring plate 1 are all arranged in parallel, a supporting plate 101 is mounted on the side surfaces of the mounting plate 10, the limiting plate 9, the lifting plate 7 and the lead liquid pouring plate 1, and two ends of the supporting plate 101 are connected with the mounting plate 10, the limiting plate 9 and the lead liquid pouring plate 1; an air-cooled area 102 is left in front of the mounting plate 10 and the stopper plate 9. The air-cooling area 102 may be externally connected with an air-cooling device for the purpose of dissipating heat from the lifting drive device 8.

Obviously, the above-mentioned embodiments only represent some practical limitations of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. The utility model provides a lead acid battery cast joint adds plumbous liquid device which characterized in that: the lead liquid pouring device comprises a lead liquid pouring plate (1), wherein a lead liquid inlet (2) is formed in one side of the lead liquid pouring plate (1), a lead liquid storage tank (3) communicated with the lead liquid inlet (2) is formed in the lead liquid pouring plate (1), a vertical lead liquid pouring runner (4) is further formed in the lead liquid pouring plate (1), one end of the lead liquid pouring runner (4) is communicated with the lead liquid storage tank (3), and the other end of the lead liquid pouring runner is communicated with the outside of the lead liquid pouring plate (1); the lead liquid pouring channel (4) is internally provided with a blocking piece (5), the blocking piece (5) can vertically reciprocate up and down along the lead liquid pouring channel (4) in the lead liquid pouring channel (4), and the outer surface of the blocking piece (5) and the inner surface of the lead liquid pouring channel (4) can contact to form a sealing surface in the up-down reciprocating process to open or close the lead liquid pouring channel (4).

2. The lead-acid storage battery cast-weld lead liquid adding device of claim 1, characterized in that: the lead liquid pouring plate (1) consists of an upper cover plate (11) and a lower base plate (12), a lead liquid inlet (2) is formed in one side of the lower base plate (12), a lead liquid storage tank (3) is formed in the upper surface of the lower base plate (12) in an open mode, and a vertical lead liquid pouring flow channel (4) is formed in the lower base plate (12) and communicated with the outside from the bottom of the lower base plate; the upper cover plate (11) covers the lower bottom plate (12), and the blocking piece (5) penetrates through the upper cover plate (11) and extends into the lead liquid pouring flow passage (4).

3. The lead-acid storage battery cast-weld lead liquid adding device of claim 2, characterized in that: a sealing plate (13) is also arranged between the upper cover plate (11) and the lower base plate (12).

4. The lead-acid storage battery cast-weld lead-adding liquid device of any one of claims 1 to 3, characterized in that: the internal space of the lead liquid pouring runner (4) is formed by connecting an upper cylindrical section (41) and a lower inverted cone section (42), and the small end of the lower inverted cone section (42) is communicated with the outside of the lead liquid pouring plate (1); the plug (5) also comprises a cylindrical connecting section (51) and an inverted cone sealing section (52), wherein the conical surfaces of the inverted cone sealing section (52) and the lower inverted cone section (42) can be contacted with each other to form a sealing surface in the vertical up-and-down reciprocating process of the plug (5).

5. The lead-acid storage battery cast-weld lead liquid adding device of claim 4, characterized in that: the lower inverted cone section (42) is also connected with a pouring port (43), and the pouring port (43) extends out of the lead liquid pouring plate (1); the inverted cone sealing section (52) is connected with the dredging section (53), and the dredging section (53) extends out of one end of the filling opening (43) when the plugging piece (5) vertically reciprocates to form a sealing surface.

6. The lead-acid storage battery cast-weld lead liquid adding device of claim 5, characterized in that: the lead liquid pouring channel (4) is communicated with the outside of the lead liquid pouring plate (1) through a pouring head (6), and a part of the upper cylindrical section (41), the whole lower inverted cone section (42) and the pouring port (43) are all arranged inside the pouring head (6).

7. The lead-acid storage battery cast-weld lead liquid adding device of claim 4, characterized in that: the top end of the plugging piece (5) and the upper part of the upper cover plate (11) are connected with a lifting plate (7), and a lifting driving device (8) drives the lifting plate (7) to vertically lift and drives the plugging piece (5) to vertically reciprocate.

8. The lead-acid storage battery cast-weld lead liquid adding device of claim 7, characterized in that: the lifting plate (7) is divided into an independent pole lifting plate (71) and a connecting sheet lifting plate (72), and the pole lifting plate (71) and the connecting sheet lifting plate (72) are respectively connected with an independent lifting driving device (8).

9. The lead-acid storage battery cast-weld lead liquid adding device of claim 8, characterized in that: connect lifter plate (7) top and still set up limiting plate (9), limiting plate (9) are spacing to lifter plate (7) descending stroke at lifter plate (7) perpendicular up-and-down motion, and when lifter plate (7) were spacing, the sealed section of the back taper (52) of stifled piece (5) and the conical surface of the lower part back taper section (42) of lead liquid pouring runner (4) contacted each other and formed sealed face.

10. The lead-acid storage battery cast-weld lead liquid adding device of claim 9, characterized in that: the mounting plate (10) is further arranged above the limiting plate (9), the lifting driving device (8) is fixedly mounted on the mounting plate (10), the limiting plate (9), the lifting plate (7) and the lead liquid pouring plate (1) are all arranged in parallel, a supporting plate (101) is mounted on the side faces of the mounting plate (10), the limiting plate (9), the lifting plate (7) and the lead liquid pouring plate (1), and two ends of the supporting plate (101) are connected with the mounting plate (10), the limiting plate (9) and the lead liquid pouring plate (1); an air cooling area (102) is reserved in front of the mounting plate (10) and the limiting plate (9).

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