KR102594283B1 - Lazer Welding Apparatus of Silicon Steel - Google Patents

Abstract

A laser welding device for silicon steel sheets is disclosed. A laser welding device for a silicon steel sheet according to an embodiment of the present invention includes a welder for welding the connection portion of the preceding and succeeding steel plates that are sequentially supplied, a cooling unit provided at the lower portion of the connection portion of the steel plate to cool the connection portion of the steel plate to be welded, and , and includes an oxygen blocking unit that sprays inert gas to prevent oxygen from flowing into the connection part of the steel plate being welded.

Description

Laser Welding Apparatus of Silicon Steel}

The present invention relates to a laser welding device for silicon steel plates, and more specifically, to a laser welding device for silicon steel plates that can prevent cracks in the weld zone.

Generally, silicon steel sheet coils pass through each processing line for pickling and cold rolling during the production process, and at this time, the material and welded portion of the silicon steel sheet undergoes bending deformation under tensile stress, resulting in the occurrence of cracks. This will have a big impact on your mail order ability.

In addition, recent silicon steel coils tend to gradually increase their silicon content to ensure excellent electromagnetic properties, and as a result, there is a possibility that cracks may occur in the welded area immediately after welding the silicon steel sheets or while passing through a series of production lines. is also increasing.

Silicon steel plates can be welded using SAW (Submerged Arc Welding), GTAW (Gas Tungsten Arc Welding), GMAW (Gas Metal Arc Welding), and LBW (Laser Beam Welding), of which the laser welding method with the least heat effect ( LBW) has recently been widely applied in the production of silicon steel sheet coils. Laser welding radiates laser light from the top of a silicon steel plate to melt and weld the thin plate base material.

However, even with laser welding, which has little thermal effect, the welded part of the thin plate material may melt and melt due to the high heat generated during welding, which causes the problem of the welded part being irregularly stretched and separated when tension is applied after welding.

Korean Patent Publication No. 10-2001-0036384 (May 7, 2001)

The laser welding device for silicon steel sheets according to an embodiment of the present invention is intended to prevent cracks in the weld area.

According to one aspect of the present invention, a welder for welding the connection portion of the preceding and succeeding steel plates that are sequentially supplied, a cooling portion provided below the connection portion of the steel plate to cool the connection portion of the steel plate to be welded, and the connection portion of the steel plate to be welded. A laser welding device for a silicon steel sheet including an oxygen blocking unit that sprays an inert gas to prevent oxygen from entering the furnace may be provided.

Additionally, the cooling unit may include a copper plate provided at the lower part of the connection unit.

Additionally, the oxygen blocking portion may include an upper gas supply portion provided at the upper portion of the connection portion and a lower gas supply portion provided in the cooling portion located at the lower portion.

Additionally, the lower gas supply unit may include a plurality of lower nozzles provided in parallel on the left and right sides of the cooling unit connection unit, and a first gas supply line connecting the lower nozzles.

Additionally, the upper gas supply unit may include a plurality of upper nozzles provided in parallel with the width direction of the steel plate on the upper part of the connection part, and a second gas supply line provided in the cooling unit to connect the upper nozzles.

In addition, it further includes a driving cylinder provided in the cooling unit and a link whose one end is connected to the cylinder rod of the driving cylinder, and the upper nozzle is provided at the other end of the link and rotates by a link that moves up and down along the cylinder rod. It can be selectively connected to two gas supply lines.

The laser welding device for silicon steel sheets according to an embodiment of the present invention sprays inert gas from above and below around the weld joint during welding to block the inflow of oxygen in the atmosphere, thereby not only providing a cooling effect but also fundamentally preventing oxide mixing in the weld area and the generation of internal foreign substances. It can be blocked, and through this, when applying tension to a silicon steel plate, the tension deviation across the entire steel plate can be minimized and cracks occurring in defective welded areas can be prevented.

In addition, the laser welding device for silicon steel sheets according to an embodiment of the present invention can prevent melting defects that chronically occur in ultra-thin materials by cooling the welding heat generated during welding with the copper plate of the cooling unit.

Figure 1 is a diagram illustrating part of the manufacturing process of a steel sheet to which a laser welding device for a silicon steel sheet according to an embodiment of the present invention is applied.
Figure 2 is a perspective view showing a laser welding device for a silicon steel sheet according to an embodiment of the present invention.
Figure 3 is a side view of a laser welding device for a silicon steel sheet according to an embodiment of the present invention.
Figure 4 is a partially enlarged side view of a laser welding device for a silicon steel sheet according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples so that the idea of the present invention can be sufficiently conveyed to those skilled in the art. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly explain the present invention, parts not related to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated for convenience. Like reference numerals refer to like elements throughout the specification.

Figure 1 schematically shows the manufacturing process of a general high-silicon steel sheet to which a laser welding device for silicon steel sheet according to an embodiment of the present invention is applied. As shown, the high-silicon steel sheet (1) is sequentially supplied with a preceding steel sheet and a following steel sheet wound in a coil shape, and the joint of the two steel sheets is joined using a welder (2) to enable continuous rolling in the subsequent process. It is provided to make it possible. As shown in an enlarged view, the welder (2) focuses the light of the laser beam (3) with the condenser lens (4) at the top of the thin plate base material (1a), such as a silicon steel plate, and radiates it through the nozzle (5) to melt the thin plate base material. Weld.

Figure 2 is a perspective view showing a laser welding device for a silicon steel sheet according to an embodiment of the present invention, and Figure 3 is a side view of Figure 2.

Referring to the drawings, the laser welding device for silicon steel sheets according to this embodiment includes a welder 10 for welding the connection portion P of the preceding steel plate S1 and the following steel plate S2, and the connection portion P to be welded. It includes a cooling part 20 provided below the steel plates S1 and S2 to cool the steel plates S1 and S2, and an oxygen blocking part 30 to prevent oxygen from flowing into the connection part being welded.

The welder 10 uses a high-input heat source that can generate the least heat effect around the connection part P where the weld line is formed. For example, a laser welder can be used.

The cooling unit 20 is located below the connection part (P) of the preceding steel plate (S1) and the following steel plate (S2), and is provided in a plate shape to sufficiently support the connection part (P). The cooling unit 20 may use a copper plate that has high thermal conductivity and is provided with a predetermined thickness to sufficiently cool the area around the connection portion P and is at least wider than the width of the steel plate. Additionally, the cooling unit 20 may include some components of the oxygen blocking unit 30, which will be described later.

The oxygen blocking portion 30 includes a lower gas supply portion 31 provided on the lower side of the connecting portion (P) and an upper gas supply portion 35 provided on the upper side of the connecting portion (P). The gas injected through the oxygen blocking unit 30 is an inert gas.

The lower gas supply unit 31 includes a plurality of lower nozzles 32 provided in parallel along the longitudinal direction of the connection part P in the cooling unit 20, and a first gas supply line 33 connecting the lower nozzles 32. ) includes. Lower nozzles 32 are provided on the left and right sides adjacent to the connection part P, and each lower nozzle 32 injects gas in an oblique direction toward the connection part P. In this embodiment, inert gas may be continuously sprayed through the lower nozzle 32 to prevent oxygen from entering while welding the connection portion P. The inert gas may be delivered to the lower nozzle 32 through the gas chamber 34 and the first gas supply line 33, and a valve 33a may be provided in the gas supply line to be able to open and close.

The upper gas supply unit 35 includes a plurality of upper nozzles 36 provided in parallel along the longitudinal direction of the weld line on the upper part of the connection part P to be welded, and a second gas supply line 37 connecting the upper nozzles 36. Includes. The upper nozzles 36 are provided on the left and right sides adjacent to the connection part P, and each upper nozzle 36 injects an inert gas in an oblique direction toward the connection part P. The second gas supply line 37 may be provided along the first gas supply line 33 in the width direction of the steel plate inside the cooling unit 20, and the gas supply line connected to the gas chamber 34 may be provided with a valve. (37a) may be provided to be openable and closed.

Looking more specifically with reference to FIG. 3, the upper nozzle 36 is connected at one end to the driving cylinder 41 provided on the lower base 22 of the cooling unit 20 and the cylinder rod of the driving cylinder 41. It includes a link 42, and an upper nozzle 36 is connected to the other end of the link 42. The driving cylinder 41 can be operated hydraulically or pneumatically, and the control part for electrically driving the driving cylinder 41 is omitted. Additionally, a driving cylinder and a link for rotating the upper nozzle 36 may be provided on the left and right sides of the connection portion P, respectively.

The link 42 is rotatably supported at its center on a fixed shaft 43 fixed to a support member (not shown) of the welding device. Therefore, the link 42, which is rotatably provided on the fixed shaft 43 in a seesaw shape, raises the upper nozzle 36 when the cylinder rod of the driving cylinder 41 is reduced, and when the cylinder rod is extended, the upper nozzle 36 ) increases.

The upper nozzle 36 includes a gas flow path 38 therein. One communication port (38a) of the gas flow path (38) communicates with the second gas supply line (37) provided in the cooling unit (20), and the other nozzle tip (38b) supplies inert gas from the upper part of the steel plate toward the connection portion (P). It is prepared to spray. The upper nozzle 36 is rotatably supported at its center on a rotating shaft 44 fixed to a support member (not shown) of the welding device, and the other end of the link 42 is rotatably supported on the communication port side. there is.

Accordingly, the upper nozzle 36, which is rotatable in a seesaw shape on the rotation axis 44, moves around the nozzle side link 42 around the fixed axis 43 when the drive cylinder 41 descends, as shown in FIG. 3. ) rises, and as a result, the communication port (38a) of the upper nozzle (36) communicates with the second gas supply line (37), and the inert gas in the gas chamber (34) is supplied to the connection portion (P) through the nozzle tip (38b). It can be sprayed.

On the contrary, as shown in FIG. 4, when the driving cylinder 41 rises, the link 42 on the nozzle side descends around the fixed axis 43, which causes the communication port 38a of the upper nozzle 36 and As the second gas supply line 37 is disconnected, the inert gas in the gas chamber 34 is blocked from being sprayed to the connection portion P through the nozzle tip 38b.

The lower nozzle 32 and the upper nozzle 36 are controlled by a control unit (not shown) so that the inert gas can be sprayed toward the steel plate connection portion (P) only during laser welding. In particular, the upper nozzle 36 is not used in normal times. It is in a position that is not in communication with the second gas supply line 37, and at the time of laser welding, it is lifted by the driving cylinder 41 and communicates with the second gas supply line 37, and inert gas is directed toward the steel plate connection portion P. Spray.

The laser welding device for silicon steel sheets according to this embodiment prepared as described above can prevent melting defects that chronically occur in ultra-thin materials by cooling the welding heat generated during welding with the copper plate of the cooling unit 20, During welding, inert gas is sprayed from the top and bottom around the weld joint to block the inflow of oxygen into the atmosphere, which not only provides a cooling effect but also fundamentally blocks the incorporation of oxides into the weld area and the generation of internal foreign substances.

10..welder 20..cooling unit
30.. Oxygen blocking part 31.. Lower gas supply part
32..Lower nozzle 33..First gas supply line
34..Gas chamber 35..Upper gas supply unit
36..Upper nozzle 37..2nd gas supply line
41..Drive cylinder 42..Link

Claims (6)

Welding machine for welding joints of leading and trailing steel plates;
a plate-shaped cooling unit disposed below the steel plate and provided with a first gas supply line and a second gas supply line through which an inert gas is supplied;
It includes an oxygen blocking part that sprays the inert gas to the upper and lower parts of the connection part during welding,
The oxygen blocking unit,
a plurality of lower nozzles connected to the first gas supply line and provided in the cooling unit to spray the inert gas toward a lower surface of the connection unit; and
A communication port capable of communicating with the second gas supply line is provided at one end, a nozzle tip for spraying the inert gas toward the upper surface of the connection part is provided at the other end, and a plurality of upper nozzles are rotatably supported on the cooling unit. Contains ;,
When the upper nozzle rotates toward the connection portion, the communication port communicates with the second gas supply line, and when the upper nozzle rotates away from the connection portion, the communication port does not communicate with the second gas supply line. A laser welding device for a silicon steel sheet. According to clause 1,
The cooling unit is a laser welding device for a silicon steel plate including a copper plate. delete According to clause 1,
A laser welding device for a silicon steel sheet wherein the plurality of lower nozzles are provided side by side on the left and right sides of the connection part. According to clause 1,
A laser welding device for a silicon steel sheet, wherein the plurality of upper nozzles are provided parallel to the width direction of the steel sheet. According to clause 1,
It further includes a driving cylinder provided in the cooling unit and a link whose end is connected to the cylinder rod of the driving cylinder,
The upper nozzle is provided at the other end of the link, rotates by the link that moves up and down along the cylinder rod, and selectively communicates with the second gas supply line.

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