KR20120003700A - Crucible moving equipment - Google Patents

Abstract

PURPOSE: A crucible transferring device is provided to stably transfer a crucible by fixing it through two clamp jogs of two clamp arms. CONSTITUTION: A crucible transferring device comprises driving shafts(110), sliding units(130), clamp arms(140), and clamp jogs(150). Some of the driving parts are fixed to the body of the crucible transferring device. The driving shaft rotate by torque supplied from the outside. The sliding unit moves by the rotation of the driving shaft along the driving shaft. The upper end of the clamp arm is connected to each sliding unit. The gaps between the lower ends of the clamp arms become narrow or wide depending on the movement of the sliding unit. The clamp jogs are arranged on the other end of each clamp arm.

Description

Crucible conveying equipment {Crucible moving equipment}

The present invention relates to a crucible conveying device.

As demand for solar cells increases by several tens of percent every year, the demand for polycrystalline silicon ingots for solar cells also increases significantly every year. In general, polycrystalline silicon ingots for solar cells are manufactured by melting raw silicon into silicon agglomerates and filling the quartz or graphite crucible 10, followed by melting and directional solidification.

As such, the crucible 10 used to fill and melt the raw material silicon generally has a weight of 80 kg to 90 kg.

In order to transfer the crucible 10, as shown in FIG. 1, two or three workers must hold and transport the lower edge of the crucible 10 with both hands on both sides, thereby acting as a factor of increasing the manufacturing cost. There was a problem that the space for preparing several crucibles 10 also takes up excessively.

Therefore, for convenience of transporting the crucible 10, a method of adsorbing and moving both sides of the crucible 10 with a vacuum pad and then loading the crucible 10 is used.

As described above, when the crucible 10 transfer apparatus of the adsorption method is used, the crucible 10 may fall and be damaged due to unstable adsorption.

The present invention is to provide a crucible transfer device that can more easily and stably transfer a crucible for melting the silicon lumps in which the raw material silicon is crushed.

The apparatus for conveying the crucible used for melting the silicon is fixed to the body of the crucible conveying apparatus, the drive shaft is rotated by a rotational force supplied from the outside; Sliding parts disposed on both drive shafts in the center of the drive shaft and moving along the drive shaft by rotation of the drive shaft; An upper end connected to each of the sliding parts, and a clamp arm in which the distance between the lower ends of the lower ends is narrowed or widened according to the movement of the sliding part; And a protrusion formed at a lower portion of the clamp arm and disposed at each other end of the clamp arm to narrow the gap between the clamp arms so that the protrusions are in close contact with both lower edges of the crucible.

Here, the part in which the sliding part is disposed in the drive shaft is formed of a male screw, the sliding part is formed of a female screw, and the direction of the male screw and the female screw may be formed to move in a direction in which the distance between the sliding parts is narrowed or widened as the driving part rotates. .

In addition, the crucible conveying apparatus may further include a pad portion for fixing a side portion of the crucible inside the upper portion of the clamp arm in which the clamp jog is disposed.

In addition, the clamp jog is detachable from the clamp arm.

Specifically, the clamp jog may include a body portion coupled to the clamp arm; and a protrusion portion having a width greater than that of the body portion and protruding from the body portion. In addition, the body portion and the protrusion may be formed integrally.

Here, the protrusion may be formed to correspond to the shape of the lower edge of the crucible.

For example, the protruding form of the protrusion may be a form in which the width increases linearly from the trunk portion in an oblique direction, and the protruding form of the protruding portion may be a form in which the width thereof increases non-linearly in the diagonal direction from the body portion.

In addition, the crucible conveying apparatus may further include a fixing bar connected to the lower portion of the clamp arm connected to the sliding portion in each clamp arm to fix the gap between the clamp arms.

Here, the fixing bar may be fixed to the body of the crucible transfer device.

Therefore, when the spacing between the sliding parts is narrowed, the spacing between the clamp jogs is widened, and when the spacing between the sliding parts is widened, the spacing between the clamp jogs can be narrowed.

In addition, the drive shaft includes a first drive shaft rotated by a direct rotational force supplied from the outside; and a second drive shaft disposed on both sides in a direction perpendicular to the first drive shaft, and rotated in a staggered direction by the rotation of the first drive shaft; can do.

The crucible conveying apparatus according to an example of the present invention includes a clamp jog that closely adheres to the lower edge of the crucible and supports the crucible at the lower part of the crucible, thereby enabling the crucible to be conveyed more stably.

1 is a view for explaining a problem when transferring the crucible for melting the silicon lump in the conventional method.
2 is a view for explaining an example of the crucible transfer apparatus according to the present invention.
3 to 5 are views for explaining various examples of the clamp jig in the crucible transfer apparatus.
6 is a view for explaining various examples of the clamp jog attached to the lower end of the clamp arm in the clamp jig.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted for simplicity of explanation, and like reference numerals designate like parts throughout the specification.

Hereinafter, a solar cell module and a manufacturing method thereof according to an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a view for explaining an example of the crucible 10 transfer apparatus according to the present invention.

Crucible 10 transfer apparatus according to the present invention can be used in the process of transferring the crucible 10 used to crush the silicon raw material into the silicon agglomeration 20 to melt in a liquid state.

Such a crucible 10 has a weight of 80kg ~ 90kg when there is no silicon lump 20, the silicon raw material is crushed, the weight of the silicon lump 20 is filled as shown in (b) of FIG. Since it can reach 120 to 150, there is a limit for the operator to transfer the crucible 10 by hand can be used to solve this.

Such a crucible 10 conveying apparatus includes a conveying rail 1, a conveying roller 2, a lift 3, and a clamp jig 100 as shown in FIG. 2A. .

The transfer rail 1 is a space for filling the crucible 10 from the place where the crucible 10 is prepared, or silicon for melting the silicon chunk 20 after the silicon chunk 20 is filled. It may be arranged to extend to the space in which the furnace is located.

The conveying roller 2 may be moved in the direction of the arrow along the conveying rail 1, and a roller rotating along the conveying rail 1 may be disposed therein.

Lift 3 is used to raise or lower the clamp jig 100 in the direction of the arrow for the convenience of the crucible 10, it may be formed including a roller and a chain as shown.

The clamp jig 100 functions to fix the protrusion 150b formed on the clamp arm 140 to the lower edges of both sides of the crucible 10 in the direction of the arrow to transport the crucible 10.

Such a clamp jig 100 is described with reference to FIGS. It will be described in more detail through 5.

As shown in FIG. 3, one example of the clamp jig 100 includes a drive shaft 110, a sliding part 130, a clamp arm 140, and a clamp jog 150.

A part of the driving shaft 110 is fixed to the clamp jig 100 body of the crucible 10 transfer device and rotates in the direction of the arrow by a rotational force supplied from the outside. Here, the handle 170 may be formed at the end of the drive shaft 110 so that an operator can rotate the drive shaft 110 by hand, although not shown, a motor for rotating the drive shaft 110 is provided. May be

The sliding unit 130 is disposed on both drive shafts 110 at the center of the drive shaft 110, and moves in the direction of the arrow along the drive shaft 110 by the rotation of the drive shaft 110.

More specifically, the portion 120 in which the sliding part 130 is disposed in the drive shaft 110 may be formed of a male screw, and the sliding part 130 may be formed of a female screw, and the direction of the male screw and the female screw may be As the driving unit rotates, the sliding unit 130 may be formed to move in a direction in which the interval between the sliding units 130 is narrowed or widened.

The clamp arm 140 is formed by connecting one upper end to each of the left and right sliding parts 130, and is formed to narrow or widen the intervals of the other lower ends according to the movement of the sliding part 130. do. More specifically, when the clamp arm 140 is integrally fixed to the sliding part 130 and the sliding part 130 is moved in the direction of the arrow so that the gap is narrowed, the clamp arm 140 also moves in the direction of the arrow so that the gap is narrowed together. When the sliding unit 130 is moved in the direction of the arrow to widen the gap, the clamp arm 140 may also be moved in the direction of the arrow to widen the gap together. In this way, the left and right clamp arms 140 which are fixed to the left and right sides of the sliding part 130 may be in close contact with both sides of the crucible 10.

The clamp jog 150 has a protrusion 150b formed at a lower portion thereof, and is disposed at each other end of the clamp arm 140 so that the gap between the clamp arms 140 is narrowed. ) Is in close contact with both lower edges of the crucible 10 and serves to fix the crucible 10.

Therefore, the clamp jog 150 has a function of allowing the crucible 10 to be stably transported when the crucible 10 is lifted by the lift 3 described above with reference to FIG. 2 and moved along the transport rail 1. do.

The clamp jog 150 includes a body portion 150a and a protrusion 150b which are integrally formed. The body portion 150a forms a hole, and the clamp arm 150c is inserted through the hole. A function of fixing the clamp jog 150 to 140, the protrusion 150b has a width larger than the width of the body portion (150a) is formed to protrude than the body portion (150a).

As such, the protrusion 150b included in the clamp jog 150 has an effect of more stably fixing the crucible 10.

More specifically, as shown in FIG. 2B, the lower edge of the crucible 10 used to melt the polycrystalline silicon agglomerate 20 is generally formed diagonally.

As such, the protrusion 150b is formed to correspond to the lower edge of the crucible 10 formed in an oblique direction, so that the protrusion 150b is in close contact with the lower edge of the crucible 10 to support the crucible 10. ) Is substantially the same as supporting the physical force at the bottom.

Therefore, the bottom surface of the crucible 10 can be supported by a stronger force than the method of conveying the side surface of the crucible 10 by using an adsorption pad, so that the clamp jig 100 of the crucible 10 conveying apparatus is shaken during the conveyance. Even if the crucible 10 can be transported more stably without falling.

In addition, since the crucible 10 is transferred to the male screw of the drive shaft 110 and the female screw of the sliding part 130, the sliding part 130 is provided even when the clamp arm 140 receives an external force in the direction of the arrow. It will not move in the direction of the arrow. Therefore, such a structure of the drive shaft 110 and the sliding portion 130 has an effect that allows the crucible 10 to be transported more stably.

In addition, the clamp jog 150 described above is connected to the clamp arm 140 by a screw so as to be detachable, so when the shape of the crucible 10 is different, there is an advantage that the clamp jog 150 can be replaced with another form There is this. Another example of the clamp jog 150 will be described in more detail with reference to FIG. 6.

In addition, the clamp jig may further include a pad unit 160. In detail, the pad portion 160 may be further formed at the clamp arm 140 to fix the side portion of the crucible 10 to the inner side of the upper portion where the clamp jog 150 is disposed.

The pad 160 is fixed to the side surface of the crucible 10, so that the crucible 10 may be more stably transported when the crucible 10 is transferred.

In addition, the clamp jig 200 may be formed in another form as shown in FIG.

As shown in FIG. 4, the clamp jig 200 includes a driving shaft 210, a sliding part 230, a clamp arm 240, and a clamp jog 250, and further includes a fixing bar 270. Can be.

Here, the basic functions of the drive shaft 210, the sliding unit 230, the clamp arm 240, and the clamp jog 250 are the same as described in Figure 3, but unlike the Figure 3 clamp arm 240 is a sliding portion The clamp arm 240 is not integrally formed with the 230, and the clamp arm 240 is connected to the sliding part 230, even though the sliding part 230 moves on the drive shaft 210 in the direction of the arrow. Only the upper end may be moved together with the sliding part 230 in the direction of the arrow on the drive shaft 210, and the lower end of the clamp arm 240 may be moved in the opposite direction.

More specifically, as shown in FIG. 4, the fixing bar 270 of the clamp jig 200 is formed in a hole 241 formed at a lower portion of the clamp arm 240 connected to the sliding part 230. It is connected through a screw to function to fix the gap between the clamp arm (240). Here, the fixing bar 270 may be fixed to the body of the crucible 10 transfer apparatus through the fixing member 260.

Therefore, the portion of the clamp arm 240 connected to the fixing bar 270 is to keep the distance between the clamp arm 240 is always constant, when the sliding portion 230 is moved, the lower end of the clamp arm 240 Is moving in the direction of the arrow opposite to the moving direction of the sliding unit 230.

Therefore, when the spacing between the sliding portion 230 is narrowed, the spacing between the clamp jogs 250 is widened, and when the spacing between the sliding portions 230 is widened, the spacing between the clamp jogs 250 is narrowed. It can be lost.

5 is a view for explaining an example of the clamp jig 300 of another embodiment different from FIGS.

As shown in FIG. 5, the clamp jig 300 includes a driving shaft 310, a sliding portion 330, a clamp arm 340, a clamp jog 350, and a pad portion 360, and a driving shaft 310. May include a first driving shaft 310a and a second driving shaft 310b.

Here, since the basic functions of the sliding part 330, the clamp arm 340, and the clamp jog 350 except for the driving shaft 310 are the same as those described with reference to FIG. 3, a detailed description thereof will be omitted.

5A is a plan view of the clamp jig 300 viewed from above, (b) is a front view of the clamp jig 300 viewed from the K1 direction, and (c) is a clamp jig 300 viewed from the K2 direction. Side view.

As shown in FIG. 5A, the first driving shaft 310a of the clamp jig 300 is rotated by a direct rotational force supplied from the outside, and the second driving shaft 310b is connected to the first driving shaft 310a. It is disposed on both sides in the vertical direction, it can be rotated in a staggered direction by the rotation of the first drive shaft (310a).

As described above, the first driving shaft 310a and the second driving shaft 310b of the driving shaft 310 of FIG. 5 have the same structure as the bevel gears, so that the rotational movement of the first driving shaft 310a is similar thereto. It can be converted to the rotational movement of the second drive shaft 310b disposed in the vertical direction.

Therefore, when the operator closely attaches the clamp jog 350 to the lower edge of the crucible 10, the clamp jig 300 visually confirms that the clamp jog 350 is closely attached to the lower edge of the crucible 10 from the front. ), The clamp jig 300 according to Figure 5 serves to help the operator to work more easily.

In addition, as shown in (a), the clamp jig 300 of FIG. 5 has two clamp arms 340 connected to one sliding part 330, and the two clamp arms 340 are ( It may be formed integrally with each other as shown in c). This is to more stably transfer the crucible 10 by fixing the crucible 10 through two clamp jogs 350 formed on the two clamp arms 340 at the lower edges of each side of the crucible 10.

Such a clamp arm and clamp jog of FIG. 5 may be equally applied, although not shown in FIGS. 3 and 4.

On the other hand, the clamp jog described above can be changed by attaching and detaching the clamp jog in a corresponding form according to the shape of the lower edge of the crucible 10.

For example, as shown in (a) of FIG. 6, when the lower edge shape of the crucible 10 is linearly formed in a diagonal form from side to bottom, the protrusion 150b is oblique from the trunk portion 150a. Clamp jogs formed in a linearly increasing width from d1 to d2 in the direction can be attached to the clamp arm.

In addition, as shown in (b) of Figure 6, when the lower edge shape of the crucible 10 is formed non-linearly rounded from the side to the bottom, the protrusion 151b is a width in the diagonal direction from the trunk portion 151a The clamp jog formed in the form of nonlinear increase from d1 to d2 can be attached to the clamp arm for use.

The above description is merely illustrative of the technical idea of the present invention, and various modifications, changes, and substitutions may be made by those skilled in the art without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by the embodiments and the accompanying drawings. . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

Claims (13)

In the apparatus for transferring the crucible used for melting the silicon,
A drive shaft, part of which is fixed to the body of the crucible transfer apparatus and rotated by a rotational force supplied from the outside;
Sliding parts disposed on both driving shafts in the center of the driving shaft and moving along the driving shaft by rotation of the driving shaft;
An upper end connected to each of the sliding parts, the clamp arm being narrowed or widened to each other according to the movement of the sliding part; And
A clamp jog formed at a lower portion of the clamp arm and disposed at each other end of the clamp arm such that the protrusion is in close contact with both lower edges of the crucible as the gap between the clamp arms is narrowed;
Crucible conveying apparatus comprising a. The method of claim 1,
The sliding part of the drive shaft is disposed is formed of a male screw, the sliding portion is formed of a female screw,
Crucible transfer apparatus characterized in that the direction of the male screw and the female screw is formed to move in a direction in which the distance between the sliding portion is narrowed or widened as the drive unit rotates. The method of claim 1,
The crucible transfer device
Crucible conveying apparatus further comprises a pad portion for fixing the side portion of the crucible inside the upper portion of the clamp arm is arranged in the clamp arm.
The method of claim 1,
The clamp jog is a crucible conveying apparatus, characterized in that detachable to the clamp arm. The method of claim 4, wherein
The clamp jog
A body portion fastened to the clamp arm; and
Crucible conveying apparatus having a width greater than the width of the body portion and including the protrusion formed to protrude than the body portion. The method of claim 5, wherein
Crucible conveying apparatus, characterized in that the body portion and the protrusion is formed integrally. The method of claim 5, wherein
Crucible transfer apparatus characterized in that the protrusion is formed to correspond to the shape of the lower edge of the crucible. The method of claim 5, wherein
The protrusion of the protrusion is a crucible conveying apparatus, characterized in that the width increases linearly from the body in the oblique direction. The method of claim 5, wherein
The protrusion of the protrusion is a crucible conveying apparatus, characterized in that the width non-linearly increases in a diagonal direction from the body portion. The method of claim 1,
The crucible transfer device
Crucible conveying apparatus further comprises a fixed bar connected to the lower portion of the part connected to the sliding portion in each of the clamp arms to fix the gap between the clamp arms. The method of claim 10,
The fixing bar is a crucible conveying apparatus, characterized in that fixed to the body of the crucible conveying apparatus. The method of claim 10,
When the gap between the sliding portion is narrowed, the gap between the clamp jog is widened,
Crucible transfer apparatus characterized in that the gap between the clamp jog is narrowed if the interval between the sliding portion is widened. The method of claim 1,
The drive shaft is
A first drive shaft rotated by a direct rotational force supplied from the outside; and
A second drive shaft disposed on both sides of the first drive shaft in a vertical direction and rotated in a staggered direction by the rotation of the first drive shaft;
Crucible conveying apparatus comprising a.

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