KR101319932B1 - Bolt welding device - Google Patents

Abstract

PURPOSE: A bolt welding device is provided to prevent welding failure after a bolt and a welded material are completely welded in a state of being compressed by upper and lower electrodes by installing a cooling unit for cooling the lower electrode. CONSTITUTION: A bolt welding device comprises a lower holder (100), a lower electrode (200), an upper holder (300), an upper electrode (400), and a cooling unit (500). The lower electrode is coupled to the upper part of the lower holder and has an insertion groove in which a shaft portion of a bolt is inserted. The upper holder is installed in a state of facing the lower holder. The upper electrode is coupled to the lower part of the upper holder and welds a welded material by compressing the welded material. The cooling unit cools the lower holder with cooling fluid. An upper air-cooled passage is formed inside the upper electrode.

Description

Bolt welding device

The present invention relates to a bolt welding device, and more particularly to a bolt welding device for welding the bolt on the panel.

Generally, projection bolts (hereinafter referred to as bolts) are welded onto various body panels of a vehicle to fix the connection with other components in an accurate and solid state.

The bolt is welded to the panel through a bolt welding device. Referring to FIG. 1, the vehicle body panel 1 of the vehicle is disposed on the lower electrode 11 of the lower holder 10, and the lower electrode ( After inserting the bolt 2 into the insertion hole 12 of 11, the upper electrode 20 is lowered, the upper electrode 21 coupled to the lower portion of the upper holder 20 is the head portion of the bolt (2) Pressurize. In addition, when the lower holder 10 and the upper holder 20 are energized, the bolt 2 is welded to the panel 1.

As described above, the bolt welding device conducts electricity while the panel 1 and the bolt 2 are disposed between the lower electrode 11 and the upper electrode 21, thereby generating heat generated while increasing the electrical resistance of the contact surface. Welding is made through.

However, in the conventional bolt welding device, the lower holder 10 generates heat and naturally cools while the panel 1 and the bolt 2 are welded, and the lower holder 10 is cooled stably. As the high temperature state of the lower holder 10 and the lower electrode 11 is maintained, the welded portions of the panel 1 and the bolt 2 are separated.

An object of the present invention is to provide a bolt welding device for increasing the cooling efficiency of the lower holder to enable a stable welding of the bolt and the panel.

The present invention, the lower holder, coupled to the upper portion of the lower holder, the lower electrode having an insertion groove formed to insert the shaft portion of the bolt, the upper holder disposed to face the lower holder, coupled to the lower portion of the upper holder And an upper electrode installed in the lower holder to press the welding target base material supplied between the bolt inserted into the insertion groove and the lower electrode in a contact state, and the lower holder to cool the lower holder with a cooling fluid. It provides a bolt welding device comprising a cooling means to.

In addition, an upper air cooling passage may be formed inside the upper electrode to circulate the cool gas supplied from the outside, and discharge the liquid to the outside.

In addition, the outlet of the upper air cooling passage may be formed to be positioned on the center axis of the insertion groove of the lower electrode, so that the cooling gas discharged from the upper air cooling passage is supplied to the insertion groove.

The cooling means may include an upper cooling unit configured to cool the upper end portion of the lower holder while circulating the cooling fluid outside the upper end of the lower holder, and the lower holder while circulating the cooling fluid inside the lower end of the lower holder. It may include a lower cooling portion for cooling the lower portion of the.

In addition, the upper cooling unit, the circulation base coupled to the lower holder to surround the upper outer side of the lower holder in a state having a cylindrical shape provided with a space inside, and is in communication with one side of the circulation base, the outside from the It may include a fluid inlet pipe for guiding the cooling fluid to be supplied to the space portion, and a fluid discharge pipe connected to the other side of the circulation base, to guide the cooling fluid introduced into the space portion to be discharged to the outside.

The lower cooling unit may include a lower cooling passage which receives the cooling fluid from the outside, circulates the lower end of the lower holder, and then discharges it to the outside.

In addition, a lower flow path may be formed inside the lower holder to communicate with the insertion groove, such that a cooling gas supplied from the outside into the lower flow path may be discharged into the insertion groove.

The bolt welding device according to the present invention includes a cooling means for cooling the lower electrode inside and outside of the lower holder and the lower electrode fastened to the lower holder using a cooling fluid supplied from the outside. After the welding is completed in the pressurized state by the electrode and the upper electrode, it is possible to prevent the welding failure occurs.

1 is a configuration cross-sectional view showing a conventional bolt welding device.
2 is a cross-sectional view showing the configuration of a bolt welding device according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

2 is a cross-sectional view showing the configuration of a bolt welding device according to an embodiment of the present invention. Referring to FIG. 1, the bolt welding apparatus according to an embodiment includes a lower holder 100, a lower electrode 200, an upper holder 300, an upper electrode 400, and cooling means 500. .

The lower holder 100 and the upper holder 300 are moved to be adjacent to each other in a state in which they are disposed to face each other in the up and down direction, and a bolt disposed between the lower electrode 200 and the upper electrode 400 to be described later ( 10) and welding the base material 20 to be welded to each other. That is, the lower holder 100 and the upper holder 300 are supplied with current from the outside and transferred to the lower electrode 200 and the upper electrode 400, respectively. Therefore, the lower holder 100 and the upper holder 300 is formed of the same material as the copper alloy, but is not limited to this can be used by selectively applying a material having excellent conductivity. In addition, any one or both of the lower holder 100 and the upper holder 300 may be installed in conjunction with the lifting means (not shown) to be elevated in the vertical direction. Here, the bolt 10 has a known bolt structure consisting of the head portion 11 and the shaft portion 12, the welding target base material 20 has a plate shape in the shaft portion of the bolt 10 ( A through hole 21 is formed to penetrate 12.

The lower fastening groove 101 is formed on the upper surface of the lower holder 100 so as to insert and fasten the lower end of the lower electrode 200 to be described later, and the lower surface of the upper holder 300 will be described later. An upper fastening groove 301 is formed to allow the upper end of the upper electrode 400 to be inserted into and fastened. Here, the lower end of the lower electrode 200 is detachably inserted and coupled to the lower fastening groove 101 of the lower holder 100, and the upper end of the upper electrode 400 is the upper fastening groove of the upper holder 300. It can be inserted and detachably coupled to the 301. Here, the lower electrode 200 and the lower fastening groove 101, and the upper electrode 400 and the upper fastening groove 301 are formed with a screw portion (not shown) corresponding to each other detachable through the screw fastening. Of course, it is possible to select a variety of known detachable coupling structures that are combined but not limited thereto.

In addition, a lower flow path 110 may be formed inside the lower holder 100 to communicate with the insertion groove 210 of the lower electrode 200 to be described later. The inlet 111 of the lower passage 110 is disposed on the outer surface of the lower holder 100 so that the compressor body can be supplied from the outside while being connected to an external connection line (not shown). In addition, although the outlet 112 of the lower passage 110 is illustrated as being connected to the lower fastening groove 101 of the lower holder 100, the insertion groove 210 of the lower electrode 200 is more preferable. It is formed to be in communication with. Therefore, the external compressor body flowing from the inlet 111 of the lower flow path 110 is supplied into the insertion groove 210 of the lower electrode 200 to be described later, and the foreign matter inside the insertion groove 210 is supplied. In addition to the removal, the lower electrode 200 can be cooled.

The lower electrode 200 is coupled to the upper portion of the lower holder 100 to receive current from the lower holder 100. That is, the lower end of the lower electrode 200 is inserted into the lower fastening groove 101 of the lower holder 100 is fastened. The welding target base material 20 is disposed on the lower electrode 200. In this case, the lower electrode 200 may be inserted into and detachably attached to the lower fastening groove 101 to enable replacement of the lower electrode 200 when the lower electrode 200 is damaged while performing the welding operation. The detachable fastening structure of the lower electrode 200 and the lower fastening groove 101 will not be described in detail as described above in the lower fastening groove 101 of the lower holder 100.

In addition, an insertion groove 210 is formed in the upper surface of the lower electrode 200. The insertion groove 210 may be formed in the longitudinal direction of the lower electrode 200 so as to penetrate from the upper end to the lower end of the lower electrode 200. Here, the insertion groove 210 allows the shaft portion 12 of the bolt 10 to be inserted and arranged, and the bolt 10 is maintained in a fixed state on the lower electrode 200, the The lower holder 100 and the upper holder 300 are moved up and down to be adjacent to each other, and the welding is made at the correct position when welding in a pressurized state.

The upper electrode 400 is coupled to the lower portion of the upper holder 300 to receive a current from the upper holder 300. That is, the upper end of the upper electrode 300 is inserted into the upper fastening groove 301 of the upper holder 300 is fastened. The lower end of the upper electrode 300 of the bolt 10 is inserted into the insertion groove 210 of the lower electrode 200 in accordance with the lifting of the lower holder 100 or the upper holder 300. The bolt 10 and the welding target base material 20 are pressed while being in contact with the head portion 11 and the bolt 10 and the welding target base material 20 disposed between the lower electrode 200. To be welded while energized. In this case, the upper electrode 400 is detachably inserted and fastened to the upper fastening groove 301, so that the upper electrode 400 may be replaced when damaged while performing a welding operation. The detachable fastening structure of the upper electrode 400 and the upper fastening groove 301 will not be described in detail as described above in the upper fastening groove 301 of the upper holder 300.

In addition, an upper air cooling passage 410 is formed inside the upper electrode 400 to allow the cooling gas to be circulated from the outside and to be discharged to the outside of the upper electrode 400. That is, the upper air cooling passage 310 cools the upper electrode 400 through the cooling gas supplied from the outside.

The inlet 311 of the upper air cooling passage 310 is formed at one side of the upper electrode 400, and the outlet 312 is formed at one side of the lower surface. Here, the outlet 312 of the upper air cooling passage 310 may be formed to be positioned on the center axis of the insertion groove 210 of the lower electrode 200. Thus, when the outlet 312 of the upper air cooling passage 310 is formed to be located on the center axis of the insertion groove 210 of the lower electrode 200, the cooling gas discharged through the outlet 312 is In addition to cooling the lower electrode 200, it is possible to remove the foreign matter inside the insertion groove 210.

The cooling means 500 allows the lower holder 100 to be cooled by a cooling fluid supplied from the outside. That is, the cooling means 500 pressurizes the bolt 10 and the welding target base material 20 in a state of being energized by the lower electrode 200 and the upper electrode 400 to be welded and coupled thereto. While cooling the lower holder 100, the welding failure between the bolt 10 and the welding target member 20 is prevented from occurring. In this case, the cooling means 500 cools the lower holder 100. As a result, the cooling means 500 also cools the lower electrode 200 connected to the lower holder 100. The cooling means 500 includes an upper cooling unit 510 and a lower cooling unit 520.

The upper cooling unit 510 cools the upper end portion of the lower holder 100 while circulating to receive the cooling fluid from the outside to the outside of the upper end of the lower holder 100 and then discharged to the outside. The upper cooling unit 510 includes a circulation base 511, a fluid inlet pipe 512, and a fluid discharge pipe 513. Here, the circulation base 511 is a cylindrical member inserted into the upper outer side of the lower holder 100 so as to surround the upper outer side of the lower holder 100. The space is provided inside the circulation base 511 such that the cooling fluid can be supplied between the upper and outer portions of the lower holder 100 through the space. The fluid inlet pipe 512 is connected to a line portion (not shown) for supplying the cooling fluid from the outside to the other end in a state in which one end in the longitudinal direction is communicatively coupled to one side of the circulation base 511. Is guided so that the feed is supplied to the space portion inside the circulation base (511). The fluid discharge pipe 513 is a means for cooling the discharged cooling fluid again after being introduced into the circulation base 511 at the other end in a state where one end in the longitudinal direction is communicatively coupled to the other side of the circulation base 511. It is connected to a line portion (not shown) for guiding the transfer, and guides the cooling fluid supplied to the space portion of the circulation base 511 to be discharged to the outside of the circulation base 511 again.

The lower cooling unit 520 cools the lower end portion of the lower holder 100 while circulating to receive the cooling fluid from the outside into the lower end of the lower holder 100 and then discharged to the outside. The lower cooling part 520 may be a lower cooling flow path formed in the lower inner side of the lower holder 100. That is, as shown in the drawing of an embodiment, the inlet 521 and the outlet 522 of the lower cooling passage is the lower holder 100 in a state where the lower cooling passage is formed inside the lower holder 100. It is provided on the side. Here, the inlet 521 of the lower cooling passage is connected to a line portion (not shown) for supplying the cooling fluid from the outside, and the outlet 522 of the lower cooling passage circulates inside the lower holder 100. It is connected to a line portion (not shown) for guiding the cooling fluid is transferred to the means for cooling again.

Referring to the operation of the bolt welding apparatus according to an embodiment configured as described above, first, the welding target base material 20 is placed and disposed on the lower electrode 200, the lower electrode 200 of the The shaft portion 12 of the bolt 10 is inserted into the insertion groove 210.

Then, while moving the upper holder 300, the upper electrode 400 is in contact with the upper surface of the head portion 11 of the bolt 10, the bolt 10 and the welding target base material 20 ) Will be pressed. At this time, the current is supplied to the lower holder 100 and the upper holder 300 while the bolt 10 and the welding target base material 20 are energized through the lower electrode 200 and the upper electrode 400. This is done. Then, as the resistance increases at the contact portion between the bolt 10 and the welding target base material 20, the bolt 10 and the welding target base material 20 are coupled to each other in a welding state.

As such, when welding of the bolt 10 and the welding target base material 20 is completed, the lower holder 100 is rapidly cooled by the cooling means 500, and the bolt 10 and the welding target base material are provided. It prevents the welding defect of (20) from occurring. That is, the current is supplied while supplying the cooling fluid to the upper outer side and the lower inner side of the lower holder 100 through the upper cooling unit 510 and the lower cooling unit 520 of the cooling means 500, respectively. By cooling the lower holder 100 and the lower electrode 200 fastened to the lower holder 100 by heating at high temperatures.

In addition, while supplying the cooling gas to the lower flow path 110 of the lower holder 100 to be circulated through the insertion groove 210 of the lower electrode 200, the lower holder 100 and the lower In addition to cooling the electrode 200, foreign matter inside the insertion groove 210 is removed.

In addition, while cooling the upper electrode 400 while supplying and discharging the cooling gas to the upper air cooling passage 410 of the upper electrode 400, the cooling gas discharged from the upper air cooling passage 410. Is injected into the insertion groove 210 of the lower electrode 200 to cool the lower electrode 200 and remove foreign substances in the insertion groove 210.

As such, the bolt welding apparatus according to an embodiment may be provided to the inner and outer sides of the lower holder 100 and the lower holder 100 by using the cooling fluid supplied from the outside to the lower holder 100. And the cooling means 500 for cooling the lower electrode 200 fastened to each other. The bolt 10 and the welding target base material 20 are provided on the lower electrode 200 and the upper electrode 400. After the welding is completed in the pressurized state, it is possible to prevent the occurrence of welding failure.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: lower holder 110: lower euro
200: lower electrode 210: insertion groove
300: upper holder 400: upper electrode
410: upper air cooling passage 500: cooling means
510: upper cooling unit 520: lower cooling unit

Claims (7)

A lower holder;
A lower electrode coupled to an upper portion of the lower holder and having an insertion groove formed to insert a shaft portion of the bolt;
An upper holder disposed to face the lower holder;
An upper electrode coupled to the lower part of the upper holder and configured to weld while pressing a welding target base material supplied between the bolt inserted into the insertion groove and the lower electrode in a contact state; And
Is installed in the lower holder, and comprises a cooling means for cooling the lower holder with a cooling fluid,
An upper air cooling passage is formed inside the upper electrode to circulate the cooling gas supplied from the outside, and then discharged to the outside, and the outlet of the upper air cooling passage is formed on the center axis of the insertion groove of the lower electrode. The cooling gas discharged from the upper air cooling passage is supplied to the insertion groove,
The lower passage is formed in the lower holder to communicate with the insertion groove, the bolt welding device for discharging the cooling gas supplied to the lower passage from the outside into the insertion groove. delete delete The method according to claim 1,
Wherein the cooling means comprises:
An upper cooling unit configured to cool the upper end portion of the lower holder while circulating the cooling fluid outside the upper end of the lower holder;
And a lower cooling unit for cooling the lower end of the lower holder while circulating the cooling fluid into the lower inner side of the lower holder. The method of claim 4,
The upper cooling unit,
A circulation base coupled to the lower holder so as to surround a top outer side of the lower holder in a state having a cylindrical shape having a space provided therein;
A fluid inlet pipe coupled to one side of the circulation base to guide the cooling fluid to the space part from the outside;
And a fluid discharge pipe connected to the other side of the circulation base to guide the cooling fluid introduced into the space to be discharged to the outside. The method of claim 4,
The lower cooling unit, the bolt welding device including a lower cooling passage for receiving the cooling fluid from the outside to circulate the lower inner side of the lower holder, and discharged to the outside again.

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