KR101996791B1 - Soldering device - Google Patents

Abstract

According to the present invention, there are provided a solder melting vessel 10 for heating a solder by a heater (not shown), a solder holder 10 mounted in a solder melting vessel 10 for supplying molten solder S to a PCB substrate (not shown) And a nitrogen injection module 30 for injecting nitrogen gas horizontally and symmetrically with respect to the molten solder S at an upper portion of the solder melting tank 10 is provided.

Description

Soldering device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soldering apparatus, and more particularly, to a soldering apparatus capable of providing stable soldering by preventing clogging of nozzles for injecting nitrogen when a nitrogen atmosphere is formed on molten lead during soldering.

In the printed circuit board, which is an essential component of electronic and electrical products, various parts and the whole circuit are connected by solder by the solder port so that each function can be exhibited. In the soldering apparatus, a plurality of heaters for melting solder are provided in the solder port, and a nozzle for spraying the molten solder to the upper portion of the port is provided at one side of the solder port. On the other side, And an impeller for spraying the solder is provided on the upper part. Meanwhile, a nitrogen supply pipe for forming a nitrogen atmosphere is provided on the inner side of the solder port in order to weaken the cohesive force of the melted solder during soldering to enable continuous soldering.

Therefore, when the printed circuit board is to be soldered, the solder is put into the port and power is applied to the heater, so that the solder is melted by the heat of the heater and becomes a liquid state.

When the impeller is driven in this state, the melted solder is sprayed upward through the nozzle, so that the printed circuit board is moved to the solder side to be soldered. Such a conventional solder port can not be soldered smoothly to a printed circuit board due to irregular pressure maintained when the solder is ejected through the nozzle, resulting in poor efficiency in soldering to a printed circuit board and frequent product failures There is a problem. In order to solve such a problem, Japanese Unexamined Patent Application Publication No. 10-2017-70848 discloses a lead fusing tank in which a plurality of heaters are combined so that a solder bar which is opened at an upper portion thereof is melted and converted into lead, A lead storage tank coupled to the lead molten bath through a connecting bracket to be introduced into the lead molten bath and to store the lead by pressure; a drive motor disposed in the lead storage tank and coupled to the lead- An impeller which is connected through a transmission means and is pumped by the drive motor so as to introduce a lead of the lead molten bath into the lead storage tank; and an impeller coupled to the lead storage tank so as to be exposed above the lead molten bath, In operation, the pressure of the lead water acting as the lead storage tank in the lead molten bath And it by the pumping force of the impeller, the soldering apparatus is disclosed comprising a nozzle adapted to discharge at a constant pressure toward the printed circuit board that is disposed above the pair of the napmul napmul napmul melt in the storage tank.

1, a nitrogen supply line 10 for forming a nitrogen atmosphere is provided on one side of a solder melting vessel 20, and an injection nozzle (not shown) provided in the nitrogen supply line 10, A nitrogen gas is supplied to one side of the solder melting tank 20. [ However, according to the conventional soldering apparatus, as shown in FIG. 2, when the nitrogen supply line 10 is provided on one side of the solder melting vessel 20, There is a case where the uniform flow of the molten solder flowing out from the solder jetting port 32 of the solder nozzle 30 and the nitrogen for restricting the stress can not be supplied smoothly Often occurs.

That is, according to the conventional soldering apparatus, when the nitrogen supply line 10 is provided at one side of the solder melting vessel 20, the nitrogen injection port 12 for injecting nitrogen in a diagonal line along the longitudinal direction of the nitrogen supply line 10 A wave generated from one side of the surface S1 of the molten solder S in the solder melting tank 20 is generated to generate a wave of a shaping wave from the opposite side and a new molten solder S is formed again, (S2). A part of the surface S2 of the molten solder S due to the rippling of the molten solder S not only covers the nitrogen injection port 12 but also forms the nitrogen injection port 12 in the nitrogen supply line 10 separated from the heating heater The molten solder SS introduced into the molten solder SS is rapidly changed from a molten state to a solid state so that nitrogen can not be supplied to the solder melting vessel 20 from the nitrogen injection port 12 of the nitrogen supply line 10. Since nitrogen is no longer supplied to the solder melting vessel 20 as described above, unfavorable flow and stress of the molten solder flowing out from the solder jetting port 32 of the solder nozzle 30 are not limited, Defects often occur.

Accordingly, development of a solder apparatus capable of solving such problems is required.

It is therefore an object of the present invention to provide a solder apparatus capable of improving the efficiency of a solder process by uniformly forming a nitrogen atmosphere in a molten solder.

Another object of the present invention is to provide a solder apparatus capable of reducing the manufacturing cost in improving the efficiency of the solder process by uniformly forming a nitrogen atmosphere in the molten solder.

According to the present invention, there are provided a solder melting vessel 10 for heating a solder by a heater (not shown), a solder holder 10 mounted in a solder melting vessel 10 for supplying molten solder S to a PCB substrate (not shown) And a nitrogen injection module 30 for injecting nitrogen gas horizontally and symmetrically with respect to the molten solder S at an upper portion of the solder melting tank 10 is provided.

Here, the nitrogen injection module 30 includes a nitrogen-inducing injection block (not shown) configured to close the upper portion of the solder melting tank 10 and to symmetrically oppose the nitrogen flow channel recess 32a for horizontally symmetrically injecting nitrogen, 32 and a plate 34 for sealing the nitrogen flow channel recess 32a of the nitrogen-induced spray block 32.

It is preferable that a plurality of nitrogen injection ports 32b for injecting nitrogen are provided symmetrically with each other on the bottom surface of the pair of opposed nitrogen flow grooves 32a.

Therefore, according to the present invention, it is possible to improve the efficiency of the solder process by forming a nitrogen atmosphere in the molten solder smoothly, and the manufacturing cost thereof can be reduced.

1 is a schematic perspective view of a conventional soldering apparatus.
2 is a schematic cross-sectional view taken along the line AA in Fig.
3 is a schematic exploded perspective view of a soldering apparatus according to a preferred embodiment of the present invention.
Fig. 4 is a schematic cross-sectional view of the BB line of Fig. 3. Fig.

FIG. 3 is a schematic exploded perspective view of a soldering apparatus according to a preferred embodiment of the present invention, and FIG. 4 is a schematic cross-sectional view of the BB line of FIG.

According to the soldering apparatus of the present invention, the solder melting vessel 10 for heating the solder by a heater (not shown) is placed in the solder melting vessel 10 and supplies the molten solder S to a PCB substrate (not shown) And a nitrogen injection module 30 for injecting nitrogen gas horizontally and symmetrically with respect to the molten solder S on the upper side of the solder melting tank 10 are provided.
Here, the nitrogen injection module 30 includes a nitrogen-inducing injection block (not shown) configured to close the upper portion of the solder melting tank 10 and to symmetrically oppose the nitrogen flow channel recess 32a for horizontally symmetrically injecting nitrogen, 32 and a plate 34 for sealing the nitrogen flow channel recess 32a of the nitrogen-induced spray block 32.
It is preferable that a plurality of nitrogen injection ports 32b for injecting nitrogen are provided symmetrically with each other on the bottom surface of the pair of opposed nitrogen flow grooves 32a.
As described above, according to the present invention, the groove and the nitrogen injection hole 32b are formed by milling or the like on the nitrogen-introducing injection block 32 having the nitrogen flow groove 32a formed as a unit block, Not only the efficiency of the manufacturing process is high, but also stabilization of the surface (SF) of the molten solder (S) due to nitrogen injection can be achieved.

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4, the nitrogen injection ports 32b formed in the nitrogen flow channel recesses 32a of the nitrogen-induced spray block 32 are symmetrically symmetrical with respect to the center line, and nitrogen (nitrogen) flows into the surface SF of the molten solder S It is possible to keep the surface tension of the molten solder S at the same maximum level in the same horizontal plane. As a result, the molten solder S does not form a wave, and clogging of the nitrogen injection port 32b can be prevented. By preventing clogging of the nitrogen injection port 32b, the soldering operation can be stably performed.

10: solder melting tank
20: Solder supply part
22: Impeller
22a: pulley
24: Solder dispensing nozzle
24a: Solder nozzle
30: Nitrogen injection module
32: Nitrogen-induced injection block
32a: Nitrogen flow groove
32b: Nitrogen injection nozzle
34: Plate
S: Melting solder

Claims (3)

A solder melting vessel 10 for heating the solder by a heater (not shown);
A solder supply unit 20 mounted in the solder melting tank 10 for supplying molten solder S to a PCB substrate (not shown); And
And a nitrogen injection module 30 for injecting nitrogen gas horizontally symmetrically with respect to the molten solder S at an upper portion of the solder melting vessel 10,
The nitrogen injection module 30 includes a nitrogen-inducing injection block 32 configured to close an upper portion of the solder melting vessel 10 and to symmetrically oppose the nitrogen flow channel recess 32a for horizontally and symmetrically inductively injecting nitrogen, And a plate 34 for sealing the nitrogen flow channel recess 32a of the nitrogen-induced spray block 32,
A plurality of nitrogen injection ports 32b for injecting nitrogen are provided symmetrically with each other on the bottom surface of a pair of opposed nitrogen flow grooves 32a,
The upper outer periphery of the solder melting vessel 10 is sealed by the nitrogen-induced spray block 32 and the plate 34 to maintain the molten solder solution in the solder melting vessel 10 in a flat state. Device. delete delete

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