KR100948368B1 - Bending mold of case for computer - Google Patents

Abstract

The present invention relates to a case bending mold for a computer, and more particularly, by bending multiple ends of a metal plate supplied between an upper and a lower holder in one step to shorten a process and a manufacturing time, thereby improving productivity and The present invention also relates to a case bending mold for a computer, which can manufacture a product which requires multiple steps of bending at each end, such as a computer case, in a single process.

Accordingly, the present invention is a computer case bending mold for forming a computer case by bending a metal plate 105 supplied between the upper holder 250 and the lower holder 210, the upper holder 250 and the lower holder ( A first bending part 200a installed at both sides of the 210 to face the multi-stage bending mold 200 to bend the both ends of the metal plate 105 in a multi-stage direction, and in a direction perpendicular to the first bending part 200a. The second and second bending parts 200 are installed on the upper and lower holders 210 and bend the other end of the metal plate 105 in an inclined manner, wherein the multi-stage bending mold 200 is formed of the lower holder 210. The elastic member 223 is installed on the top to be elastically movable horizontally, and an inclined surface 221 is formed at one side thereof, and a recess 222 is formed at an opposite side thereof with a horizontal surface 222b and an upper side inclined surface 222a. Cam die 220 and the lower side of the cam die 220 An inclined surface 211a is formed on the upper end of the holder 210 so as to be elastically moved up and down via an elastic means 212 and at one end thereof in sliding contact with the inclined surface 221 of the cam die 220. A lower pad 211 for horizontally moving the cam die 220 and an upper end of the lower holder 210 spaced a predetermined distance to the other side of the cam die 220 and facing the cam die 220. The cam driver 230 having the inclined surface 231 formed on the side surface and the lower side of the upper holder 250 are installed to be able to be moved up and down elastically through the elastic means 261. The upper pad 260 for pressing and lowering the lower pad 211 and the lower side of the upper holder 250 of one side of the upper pad 260 are slidably installed in the horizontal direction and the cam driver 230 on one side thereof. Sliding contact with the inclined surface 231 An inclined surface 271 is formed, and an opposite side is formed with an inclined surface and a protruding portion 272 extending downward in a horizontal plane so as to be inserted into the groove portion 222 so that the lower surface of the upper holder 250 with the cam die 220. It comprises a cam punch 270 for bending the metal plate 105 in between, and the second bending portion 300 is elastic through the elastic means 212 on the upper end of the lower holder (210). The lower pad 211 having an inclined surface 211a formed at one end and the lower pad 210 which is spaced at a predetermined distance to one side of the lower pad 211 and the lower pad Cam driver 310 having an inclined surface 311 formed on one side facing the 211 and the lower holder of the upper holder 250 via the elastic means 261 is installed to be able to lift and lower elastically and the upper holder When lowering the 250, the lower pad 211 An upper pad 260 for pressing down and a lower side of one upper holder 250 of the upper pad 260 to be slidable in a horizontal direction, and on one side of the inclined surface 311 of the cam driver 310. An inclined surface 321 is formed in sliding contact with the upper surface of the upper holder 250 and includes a cam punch 320 for bending the metal plate 105 along the inclined surface 211a of the lower pad 211. It is characterized by.

Multi-stage, Bending, Mold, Upper Pad, Lower Pad, Cam Die, Cam Punch, Cam Driver

Description

BENDING MOLD OF CASE FOR COMPUTER}

The present invention relates to a case bending mold for a computer, and more particularly, by bending multiple ends of a metal plate supplied between an upper and a lower holder in one step to shorten a process and a manufacturing time, thereby improving productivity and The present invention also relates to a case bending mold for a computer, which can manufacture a product which requires multiple steps of bending at each end, such as a computer case, in a single process.

Generally, a bending mold is a metal mold for bending a plate-like material such as a metal plate to produce a predetermined product.

The conventional bending mold 1 has a lower holder 2 provided with a die 3, a pad 7 rising and falling elastically and a punch 8 provided at one side of the pad 7 as shown in FIG. It consists of an upper holder (6) having a).

Therefore, when the upper holder 6 is lowered after the metal plate 5 is supplied between the die 3 and the pad 7, the pad 7 is placed on the die 3. In the state where the metal plate 5 is fixed by pressing the punch 8, the punch 8 continues to descend to bend one end of the metal plate 5 protruding to one side of the die 3 to 90 °.

In addition, the bending mold as shown in FIG. 2 is used to bend the portion bent by 90 ° to the bending mold 1 of FIG. That is, the upper end of the lower holder 10 is provided with a die 11 having a groove portion 11a formed on one side, and is slidably installed in a horizontal direction at a position spaced apart from the die 11 at one side. A protrusion 12a is inserted into the groove 11a of the die 11 and a cam die 12 having an inclined surface is installed on the other side.

In addition, the lower end of the upper holder 20 is provided with a pad (21) to elastically move up and down and the punch 22 in one side of the pad 21, the cam die (1) on one side of the punch (22) An inclined surface 22a is formed to move the cam die 12 in the horizontal direction while being in sliding contact with the inclined surface of 12).

Accordingly, when the metal plate 5, one end of which is bent at 90 ° through the bending mold 1 of FIG. 1, is placed on the die 11 of the bending mold of FIG. 2, the upper holder 20 is lowered. The punch 22 continues to descend while the pad 21 presses the metal plate 5 mounted on the die 11 to fix the metal plate 5. At this time, the punch 22 causes the cam die ( 12) is slid to the die (11) side.

In this process, the protruding portion 12a of the cam die 12 is inserted into the groove portion 11a of the die 11 while bending the metal plate 5 positioned between the cam die 12 and the die 11. The part is bent again in the shape of the groove 11a.

However, in the conventional bending mold described above, since the punch 8 moves only in the vertical direction as shown in FIG. 1 or the cam die 12 moves only in the horizontal direction as shown in FIG. In order to multi-end the end of the metal plate 5 in a “Z” shape, it is necessary to pass both the process of FIG. 1 and the process of FIG. 2, thereby increasing the process and manufacturing time, thereby lowering productivity.

In addition, since the bending molds as shown in FIGS. 1 and 2 must be provided, there is a problem in that the cost increases.

In addition, when all ends of the metal plate 5 are bent in multiple stages, the process as described in FIGS. 1 and 2 must be repeated, thereby increasing the process and manufacturing time.

An object of the present invention for solving the above problems is to shorten the end of the metal plate supplied between the upper and lower holders in one step in a single step to shorten the process and manufacturing time to improve productivity and reduce the number of molds It is possible to reduce the cost, which is to provide a case bending mold for a computer that can be manufactured in one process for products that need to be bent in multiple stages, such as a computer case.

The present invention for achieving the above object is a computer case bending mold for forming a computer case by bending a metal plate 105 supplied between the upper holder 250 and the lower holder 210, the upper holder ( A first bending part 200a installed at both sides of the 250 and the lower holder 210 so as to face the multi-stage bending mold 200 to bend both ends of the metal plate 105, and the first bending part 200a. The second and second bending parts 200 are installed in the upper and lower holders 210 in a direction perpendicular to each other, and bend the other end of the metal plate 105 in an inclined manner. It is installed on the upper end of the lower holder 210 to elastically move horizontally through the elastic means 223 and the inclined surface 221 is formed on one side and the lower side is the horizontal surface 222b and the upper side is the inclined surface 222a. The cam die 220 with the groove 222 formed thereon, and The upper side of the lower holder 210 of the cam die 220 is installed to elastically move up and down via the elastic means 212, and one end sliding contact with the inclined surface 221 of the cam die 220 An inclined surface 211a is formed to be installed at an upper end of the lower pad 211 for horizontally moving the cam die 220 and the lower holder 210 spaced a predetermined distance to the other side of the cam die 220 and the The cam driver 230 having an inclined surface 231 formed on one side facing the cam die 220 and the lower end of the upper holder 250 are installed to be elastically lifted and lowered via an elastic means 261. When the upper holder 250 is lowered, the upper pad 260 for pressing and lowering the lower pad 211 and the lower side of one upper holder 250 of the upper pad 260 is slidably installed in a horizontal direction. In addition, the inclined surface 231 of the cam driver 230 on one side ), The inclined surface 271 is formed in sliding contact with the other side, and an opposite side is formed with an inclined surface so as to be inserted into the groove portion 222 and a protrusion 272 extending downward in a horizontal plane so that the cam when the upper holder 250 descends. It comprises a cam punch 270 to bend the multi-stage flat plate-shaped metal plate 105 between the die 220, the second bending portion 300, the elastic means on the upper end of the lower holder (210) A lower pad 211 having an inclined surface 211a formed at one end thereof and being elastically movable up and down via 212 and an upper end of the lower holder 210 spaced a predetermined distance to one side of the lower pad 211. In addition to being installed in the cam driver 310, the inclined surface 311 is formed on one side facing the lower pad 211, and the elastic lifting up and down via the elastic means 261 at the lower end of the upper holder 250 Upper holder (25) The upper pad 260 for pressing down the lower pad 211 and the lower pad 211 and the lower side of the upper holder 250 of the upper pad 260 to be slidable in the horizontal direction, and at one side The inclined surface 321 is formed in sliding contact with the inclined surface 311 of the cam driver 310, the metal plate 105 along the inclined surface 211a of the lower pad 211 when the upper holder 250 is lowered. It characterized in that it comprises a cam punch 320 for bending.

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In the present invention, by bending the ends of the metal plate supplied between the upper and lower holders in one step, the process and manufacturing time can be shortened, productivity can be improved, and the number of molds can be reduced, thereby reducing costs.

In addition, since a product having to be bent in multiple stages such as a computer case can be manufactured in a single process, productivity is improved and manufacturing cost is reduced.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

Repeated descriptions of the same parts as in the prior art are omitted.

3 is a plan view of a lower holder and a bottom view of an upper holder showing a case bending mold for a computer according to the present invention, and FIG. FIG. 5 is a view illustrating AA and BB lines of a multi-stage bending mold in FIG. 3 and a state in which the upper holder is lowered, and FIG. 6 is a line CC and DD in FIG. 3, in which the upper holder is raised. 7 is a view illustrating the CC and DD lines of the second bending part in FIG. 3 and a state in which the upper holder is lowered, FIG. 8 is a view illustrating the cam die in the multi-stage bending mold according to the present invention. 9 is a view showing a cam punch in a multi-stage bending mold according to the present invention, Figure 10 is a view showing a cam driver in a multi-stage bending mold according to the present invention, Figure 11 is a foot FIG. 12 is a plan view illustrating a metal plate supplied to a case bending mold for a computer according to the present invention, and FIG. 13 illustrates a metal plate in a case bending mold for a computer according to the present invention. It is a perspective view which shows the state of bending.

The multi-stage bending mold 200 according to the present invention is a die for multi-stage bending (bending) the end of the metal plate 105 supplied between the upper holder 250 and the lower holder 210 in the form of "Z". Here, the multi-stage bending means bending the end of the metal plate 105 twice in one process.

The multi-stage bending mold 200 is as shown in Figure 4 and 5, between the lower holder 210 is fixed to the bottom and the upper holder 250 is installed to be lowered from the upper side to the lower holder 210 The cam die 220, the lower pad 211, the cam driver 230, the upper pad 260, and the cam punch 270 are installed.

The cam die 220 is installed on the upper end of the lower holder 210 to elastically move horizontally through the elastic means 223 and an inclined surface 221 is formed on one side thereof. In addition, a groove portion 222 is formed on the other side of the cam die 220.

Here, the groove 222 is formed of an inclined surface 222a formed to be inclined downward from the upper end of the cam die 220 and a horizontal surface 222b formed horizontally from the lower end of the inclined surface 222a.

On the other hand, not only the elastic means 223 but also all the elastic means to be described below it is preferable to use a coil spring, in addition to the coil spring can be used a variety of means having elasticity, can also be used as a cylinder.

Therefore, the cam die 220 is capable of horizontally moving forward and backward elastically through the elastic means 223 installed in the horizontal direction at the upper end of the lower holder 210.

Meanwhile, in order for the cam die 220 to be coupled to the upper end of the lower holder 210, as shown in FIG. 8, protrusions 223 are formed at both ends of the cam die 220 and the lower holder 210. The upper end of the rail unit 224, which is slidingly coupled with the protrusion 223 of the cam die 220 is coupled.

In addition, the lower pad 211 is installed on the upper end of one side lower holder 210 of the cam die 220 via elastic means 212 to be able to be lifted and lowered elastically and at one end of the cam die 220. An inclined surface 211a is formed to be in sliding contact with the inclined surface 221 of FIG. 2) to horizontally move the cam die 220.

In addition, the lower pad 211 is slidably supported in the vertical direction by a guide post 214 vertically coupled to the upper end of the lower holder 210.

In addition, the lower holder 210 is provided with a guide bolt 213 to limit the lift height when the lower pad 211 ascends in the upward direction by the elastic means (212). The lower end of the guide bolt 213 is fixedly coupled to the upper end of the lower holder 210, the upper end is slidably coupled to the lower pad 211, the bolt head (213a) portion of the lower pad 211 It is caught by the formed groove 211b.

The guide bolt 213 limits the maximum distance between the lower pad 211 and the lower holder 210.

On the other hand, since the lower pad 211 is elastically supported by the elastic means 212 is normally raised to a predetermined height above the lower holder 210, the lower pad 211 is the upper holder 250 Lowered by the upper pad 260 when descending.

In addition, a block 215 is installed on the upper end of the lower holder 210 so that the lower pad 211 in the raised state does not descend more than a predetermined distance, and the lower pad 211 is provided by the block 215. And the minimum distance between the lower holder 210 is limited.

That is, the lower pad 211 elastically moves up and down within the minimum distance between the lower holder 210 by the block 215 and the maximum distance between the lower holder 210 by the guide bolt 213. .

As such, the lower pad 211 is lowered by the pressing of the upper pad 260 when the upper holder 250 descends, and the upper pad 260 is raised by the rising of the upper holder 250. In this case it is raised by the elastic means (212).

In this case, when the lower pad 211 descends, the inclined surface 211a formed at one end of the lower pad 211 and the inclined surface 221 of the cam die 220 slide, so that the cam die 220 is horizontal. The cam die 220 is moved to the initial position by the elastic means 223 when the lower pad 211 is raised.

In addition, the cam driver 230 is installed on the upper end of the lower holder 210 spaced apart by a predetermined distance to the other side of the cam die 220 and the inclined surface 231 on one side facing the cam die 220. Is formed.

In addition, as shown in Figure 10, the upper end of the cam driver 230 to prevent interference with the elastic means 273 for elastically supporting the cam punch 270 when the cam punch 270 to be described below is lowered Interference prevention grooves 232 are formed.

In addition, the upper pad 260 is installed on the lower end of the upper holder 250 via an elastic means 261 so as to be elastically lowered and lowered when the lowering of the upper holder 250. It is pressed down.

In this case, a block 262 is installed at the lower end of the upper holder 250 to limit the minimum distance between the upper pad 260 and the upper holder 250. That is, when the upper holder 250 is lowered, the upper pad 260 presses the lower pad 211. When the upper pad 260 contacts the block 262, the upper holder is pressed. 250 no longer descends.

In addition, the guide bolt 263 is coupled to the upper end of the upper pad 260 is coupled to the upper holder 250 so as to slide upward and downward. Here, the lower end of the guide bolt 263 is fixedly coupled to the upper pad 260, the upper end is slidably coupled through the upper holder 250, the upper portion of the bolt head (263a) formed at the end is The upper side of the holder 250 is caught.

The guide bolt 263 limits the maximum distance between the upper pad 260 and the upper holder 250.

Accordingly, the upper pad 260 is elastically moved up and down within the minimum distance between the upper holder 250 by the block 262 and the maximum distance between the upper holder 250 by the guide bolt 263. .

In addition, the cam punch 270 is installed to be slidable in the horizontal direction at the lower end of the one side upper holder 250 of the upper pad 260 and sliding on the inclined surface 231 of the cam driver 230 on one side. An inclined surface 271 is formed to contact the multi-stage bending of the metal plate 105 with the cam die 220 when the upper holder 250 is lowered.

In addition, a protrusion 272 is formed on the other side of the cam punch 270, and the protrusion 272 is formed in a shape corresponding to the groove 222 of the cam die 220.

That is, when the upper holder 250 is lowered by forming grooves 222 and protrusions 272 of which the upper side is an inclined surface and the lower side is a horizontal surface, respectively, on the opposing surfaces of the cam die 220 and the cam punch 270. In the process of inserting the protrusion 272 of the cam punch 270 into the groove 222 of the cam die 220, the flat metal plate 105 is formed along the shape of the protrusion 272 and the groove 222. It will be multi-stage bending.

In addition, the upper holder 250 is provided with an elastic means 273 for elastically supporting the cam punch 270 in the opposite direction of the cam die 220.

The elastic means (273) is coupled to the sliding shaft (273c) to be slidable in the horizontal direction to the cam block (273a) to be protruded in the lower direction to the lower end of the upper holder 250, the sliding shaft (273c) One end of the cam punch 270 is coupled to the other end of the cam block 273a between the cam spring 273b via the coil spring 273b to elastically support the cam punch 270.

That is, the cam punch 270 is usually elastically supported in the opposite direction of the cam die 220 by the elastic means (273).

When the upper holder 250 descends, the sliding shaft 273c of the elastic means 273 is inserted into the interference preventing groove 232 formed at a predetermined width at the upper end of the cam driver 230 so that the sliding shaft ( 273c) and the cam driver 230 does not cause interference.

Meanwhile, in order for the cam punch 270 to be slidingly coupled to the lower end of the upper holder 250, as shown in FIG. 9, protrusions 274 are formed at both ends of the cam punch 270, and the upper holder 250 is disposed. At the top of the rail portion 275 is slidingly coupled with the protrusion 274 of the cam punch 270 is installed.

Hereinafter, the operation of the multi-stage bending mold 200 according to the present invention will be described.

First, the initial state of the multi-stage bending mold 200 is a state in which the upper holder 250 is raised, as shown in Figure 4, the lower pad 211 is the lower holder 210 by the elastic means 212 It is elastically supported at a position spaced apart from the block 215 by a predetermined height, and the inclined surface 221 of the cam die 220 is in close contact with the inclined surface 211a of the lower pad 211.

In addition, the upper pad 260 is also elastically supported at a position spaced apart from the block 262 of the upper holder 250 by the elastic means 261, at this time, the inclined surface 271 of the cam punch 270 Is spaced apart from the inclined surface 231 of the cam driver 230.

In the initial state as described above, the cam die 220 and the cam punch 270 are spaced apart from each other in the vertical and horizontal directions.

Thereafter, the metal plate 105 is supplied between the upper and lower holders 210 so that the metal plate 105 is placed on the upper end of the lower pad 211. At this time, the end of the metal plate 105 is the cam die ( It is supplied to protrude more than the end of the 220.

Subsequently, when the supply of the metal plate 105 is completed, the upper holder 250 is lowered and the upper pad 260 and the cam punch 270 are also lowered together, wherein the upper pad 260 is lowered. The lower pad 211 is lowered while the metal plate 105 is fixed while first contacting the metal plate 105 mounted on the pad 211.

Here, when the lower pad 211 is lowered, the cam die 220 in sliding contact with the inclined surface 211a of the lower pad 211 is moved in the horizontal direction.

As such, when the lower pad 211 descends by the lowering of the upper holder 250 and the upper pad 260, the cam die 220 moves in a horizontal direction, and the lower pad 211 moves to the lower holder ( When it is seated on the block 215 of 210, the lower pad 211 stops falling and the cam die 220 also stops moving in the horizontal direction.

In this case, the upper pad 260 is in a state of being fixed while continuously pressing the metal plate 105 mounted on the lower pad 211 by the elasticity of the elastic means 261.

Subsequently, even after the lowering of the lower pad 211 is completed and the horizontal movement of the cam die 220 is completed, the upper holder 250 continues to descend.

When the upper holder 250 is continuously lowered, the upper pad 260 continues to press the elasticity of the elastic means 261 to the lower pad 211, the cam punch 270 is the upper holder 250 Descending with).

Here, the cam punch 270 is in contact with the end of the metal plate 105 protruding to one side of the cam die 220 in the process of descending in the vertical direction, at this time the end of the metal plate 105 is the cam Bend at a right angle with respect to the edge portion of the die 220, and at the same time the inclined surface 271 of the cam punch 270 is sliding along the inclined surface 231 of the cam driver 230.

Subsequently, when the cam punch 270 slides along the inclined surface 231 of the cam driver 230, the protrusion 272 of the cam punch 270 advances in the downward inclined direction while the cam die 220 moves forward. It is inserted into the groove portion 222 of the), in this process the end bent at a right angle of the metal plate 105 is multi-stage bending along the shape of the groove portion 222.

In the present invention, since the groove portion 222 is formed of the inclined surface 222a and the horizontal surface 222b, the end of the metal plate 105 is multi-stage bent in the form of a "Z".

On the other hand, when the protrusion 272 of the cam punch 270 is fully inserted into the groove 222 of the cam die 220, the upper end of the upper pad 260 is the block 262 of the upper holder 250 In contact with the upper holder 250 is no longer lowered.

In addition, after the metal plate 105 is bent in multiple stages, the upper holder 250 is raised. At this time, the upper pad 260 keeps pressing the lower pad 211 with a predetermined elasticity. The punch 270 is raised.

Here, the cam punch 270 is slid to the initial position along the inclined surface 231 of the cam driver 230 by the elastic means 273, the projection 272 of the cam punch 270 is the cam It exits from the groove 222 of the die 220.

Thereafter, when the upper holder 250 continues to rise, the upper pad 260 is caught by the bolt head 263a of the guide bolt 263 of the upper pad 260 on the upper end of the upper holder 250. ) Also rises, and when the upper pad 260 is raised, the fixing of the metal plate 105 is released and the lower pad 211 and the cam die 220 are returned to their initial positions.

After the upper holder 250 is raised to the initial position, the metal plate 105 may be taken out.

3 is a plan view of a lower holder showing a case bending mold for a computer using the multi-stage bending mold and a bottom view of the upper holder. First, the case for a computer is a rectangular metal plate 105 as shown in FIG. 12 to surround the outside of the computer. ) Is bent in the form of "형태", before the bending of the metal plate 105 in the form of "┌┐", as shown in Figure 13, the other side of the computer on three sides (three ends) of the metal plate 105 Multistage bending should be performed first to form a coupling for engaging with the outer case.

As such, the case bending mold 100 for a computer according to the present invention may multistage three surfaces (three ends) of the metal plate 105 supplied between the upper holder 250 and the lower holder 210 in one step. The first bending part for bending the both ends of the metal plate 105 by installing the multi-stage bending mold 200 to face both sides of the upper holder 250 and the lower holder 210 as a mold capable of bending. 200a,

The second bending part 300 is installed on the upper and lower holders 210 in a direction perpendicular to the first bending part 200a and also bends one end of the metal plate 105 in an inclined manner.

Here, the first bending part 200a is omitted because it has the same configuration and operation as the multi-stage bending mold 200 described above.

In addition, the first bending part 200a and the second bending part 300 are installed between the upper holder 250 and the lower holder 210.

6 and 7, the second bending part 300 is installed on the upper end of the lower holder 210 via an elastic means 212 to be able to be lifted and lowered elastically and at one end thereof has an inclined surface ( A lower pad 211 formed with 211a);

A cam driver 310 installed at an upper end of the lower holder 210 spaced to one side of the lower pad 211 and having an inclined surface 311 formed at one side facing the lower pad 211;

An upper pad 260 that is installed at the lower end of the upper holder 250 to elastically move up and down via an elastic means 261 and presses and lowers the lower pad 211 when the upper holder 250 descends. Wow,

An inclined surface 321 is formed at the lower end of one upper holder 250 of the upper pad 260 to be slidable in the horizontal direction and at one side thereof to be in sliding contact with the inclined surface 311 of the cam driver 310. The lower portion of the upper holder 250 is made of a cam punch 320 for bending the metal plate 105 along the inclined surface 211a of the lower pad 211.

Here, the cam driver 310 has the same structure as the cam driver 230 of the multi-stage bending mold 200 which is the first bending part 200a, and the lower pad 211 and the upper pad 260. Is common with the lower pad 211 and the upper pad 260 of the multi-stage bending mold 200.

In addition, the inclined surface 322 of the same angle as the inclined surface 211a of the lower pad 211 is formed on the other side surface of the cam punch 320.

In addition, the upper holder 250 is provided with an elastic means 323 for elastically supporting the cam punch 320 in the opposite direction of the lower pad 211. The elastic means 323 has the same structure as the elastic means 273 for elastically supporting the cam punch 270 in the multi-stage bending mold 200.

Meanwhile, in order for the cam punch 320 to be slidingly coupled to the lower end of the upper holder 250, as shown in FIG. 11, protrusions 324 are formed at both ends of the cam punch 320 and the upper holder 250. The upper end of the rail portion 325 is slidingly coupled with the protrusion 324 of the cam punch 320 is installed.

Hereinafter, the operation of the computer case bending mold 100 according to the present invention will be described.

First, when the metal plate 105 is supplied between the upper holder 250 and the lower holder 210, the three surfaces of the metal plate 105 through the first bending portion 300 and the second bending portion 200a ( Three ends) are bent simultaneously. That is, the multi-stage bending mold 200, which is the first bending portion 200a, may be multi-stage bending both ends of the metal plate 105, and the second bending portion 300 may incline the other end of the metal plate 105. Will bend.

On the other hand, since the action of the multi-stage bending mold 200, which is the first bending portion 200a, is the same as described above, a detailed description thereof will be omitted and only the operation of the second bending portion 300 will be described.

When the metal plate 105 is supplied between the upper holder 250 and the lower holder 210 so that the metal plate 105 is placed on the upper end of the lower pad 211, an end of the metal plate 105 is placed on the lower pad. It protrudes more than the end of 211.

Subsequently, when the supply of the metal plate 105 is completed, the upper holder 250 is lowered, and the upper pad 260 and the cam punch 320 are lowered together, wherein the upper pad 260 is lowered. The lower pad 211 is lowered while the metal plate 105 is fixed while first contacting the metal plate 105 mounted on the pad 211, and the lower pad 211 is a block of the lower holder 210. When seated on 215, the lower pad 211 stops descending.

In this case, the upper pad 260 is in a state of being fixed while continuously pressing the metal plate 105 mounted on the lower pad 211 by the elasticity of the elastic means 261.

Subsequently, even after the lowering of the lower pad 211 is completed, the upper holder 250 continues to descend.

When the upper holder 250 is continuously lowered, the upper pad 260 continues to press the elasticity of the elastic means 261 to the lower pad 211, the cam punch 320 is the upper holder 250 Descending with).

Here, the cam punch 320 is in contact with the end portion of the metal plate 105 protruding to one side of the lower pad 211 in the process of descending in the vertical direction, the end of the metal plate 105 Bend at a right angle with respect to the edge of the lower pad 211, and at the same time the inclined surface 321 of the cam punch 320 is sliding along the inclined surface 311 of the cam driver 310.

At this time, the inclined surface 322 protruding to the other side of the cam punch 320 is bent inclined along the inclined surface 211a of the lower pad 211 at the end bent at a right angle of the metal plate 105.

Meanwhile, when bending of the metal plate 105 is completed by the protruding inclined surface 322 of the cam punch 320, the upper end of the upper pad 260 contacts the block 262 of the upper holder 250. The upper holder 250 is no longer lowered.

In addition, after the metal plate 105 is bent obliquely, the upper holder 250 is raised. At this time, the upper pad 260 keeps pressing the lower pad 211 with a predetermined elasticity. The punch 320 is raised.

Here, the cam punch 320 is slid to the initial position along the inclined surface 311 of the cam driver 310 by the elastic means 323 protruding inclined surface 322 of the cam punch 320 It is spaced apart from the inclined surface 211a of the lower pad 211.

Subsequently, when the upper holder 250 continues to rise, the upper pad 260 is caught by the bolt head 263a of the guide bolt 263 of the upper pad 260 on the upper end of the upper holder 250. In addition, as the upper pad 260 is raised, the fixing of the metal plate 105 is released and at the same time the lower pad 211 is returned to the initial position.

As described above, in the case bending mold 100 for a computer, both ends of the metal plate 105 supplied between the upper holder 250 and the lower holder 210 may be the first bending part 200a. 200 is multi-stage bending, and the other end of the metal plate 105 is bent obliquely to the second bending portion 300, thereby bending and obliquely bending three surfaces (three ends) of the metal plate 105 in one step. You can do it.

As a result, the process and manufacturing time can be shortened to improve productivity and reduce the number of molds, thereby reducing costs. In addition, not only computer cases but also electric / telephone terminal boxes, front doors, various metal cases, etc. Products that need to be bent at multiple stages can be manufactured in a single process.

1 is a view showing a conventional bending mold,

2 is a view showing another conventional bending mold,

3 is a plan view of a lower holder and a bottom view of an upper holder showing a case bending mold for a computer according to the present invention;

4 is a view showing a state in which the upper holder is raised and the A-A and B-B lines of the multi-stage bending mold in FIG.

FIG. 5 is a view showing lines A-A and B-B of a multi-stage bending mold in FIG. 3 and showing a state where an upper holder is lowered;

FIG. 6 is a view illustrating C-C and D-D lines of a second bending part in FIG. 3 and showing a state in which an upper holder is raised;

FIG. 7 is a view illustrating C-C and D-D lines of the second bending part in FIG. 3 and illustrating a state in which the upper holder is lowered;

8 is a view showing a cam die in a multi-stage bending mold according to the present invention;

9 is a view showing a cam punch in a multi-stage bending mold according to the present invention;

10 is a view showing a cam driver in a multi-stage bending mold according to the present invention;

11 is a view showing a cam punch in a second bending part according to the present invention;

12 is a plan view showing a metal plate supplied to a case bending mold for a computer according to the present invention;

FIG. 13 is a perspective view illustrating a state in which a metal plate is bent in a case bending mold for a computer according to the present invention. FIG.

<Description of Signs of Major Parts of Drawings>

100: case bending mold 200a: first bending part

210: lower holder 211: lower pad

211a, 221,231,271,311,321,322: slope

212,261,273,323: elastic means

220: cam die 222: home part

230, 310: Cam driver 250: Upper holder

260: upper pad 270, 320: cam punch

272: protrusion 300: second bending portion

Claims (7)

delete delete delete delete In the case bending mold for a computer for forming a computer case by bending the metal plate 105 supplied between the upper holder 250 and the lower holder 210, A first bending part 200a installed at both sides of the upper holder 250 and the lower holder 210 so as to face the multi-stage bending mold 200 so as to bend the both ends of the metal plate 105 in multiple stages; The second bending part 300 is installed on the upper and lower holders 210 in a direction perpendicular to the first bending part 200a and bends the other end of the metal plate 105 inclinedly. The multi-stage bending mold 200, The inclined surface 221 is formed on one side of the lower holder 210 and is elastically movable horizontally through the elastic means 223. The lower side is the horizontal surface 222b and the upper side is the inclined surface 222a. Cam die 220 is formed with the in groove 222, The cam die 220 is installed on the upper end of the lower holder 210 of the cam die 220 via the elastic means 212 to elastically move up and down, and one end of the cam die 220 in sliding contact with the inclined surface 221 of the cam die 220. An inclined surface 211a is formed so that the lower pad 211 which horizontally moves the cam die 220, A cam driver 230 installed at an upper end of the lower holder 210 spaced a predetermined distance to the other side of the cam die 220, and having an inclined surface 231 formed on one side facing the cam die 220; An upper pad 260 that is installed at the lower end of the upper holder 250 to elastically move up and down via an elastic means 261 and presses and lowers the lower pad 211 when the upper holder 250 descends. Wow, An inclined surface 271 is formed to slide in a horizontal direction at a lower end of one upper holder 250 of the upper pad 260 and to make sliding contact with the inclined surface 231 of the cam driver 230 on one side thereof. On the opposite side, a protrusion 272 having an upper side inclined and a lower side extending in a horizontal plane is formed on the opposite side to be inserted into the groove 222 so that when the upper holder 250 descends, a flat plate-shaped metal plate ( It comprises a cam punch 270 for bending the step 105, The second bending part 300, A lower pad 211 which is installed on the upper end of the lower holder 210 via an elastic means 212 to elastically move up and down, and has an inclined surface 211a formed at one end thereof; A cam driver 310 installed at an upper end of the lower holder 210 spaced to one side of the lower pad 211 and having an inclined surface 311 formed at one side facing the lower pad 211; An upper pad 260 that is installed at the lower end of the upper holder 250 to elastically move up and down via an elastic means 261 and presses and lowers the lower pad 211 when the upper holder 250 descends. Wow, An inclined surface 321 is formed at the lower end of one upper holder 250 of the upper pad 260 to be slidable in the horizontal direction and at one side thereof to be in sliding contact with the inclined surface 311 of the cam driver 310. Computer case bending mold, characterized in that it comprises a cam punch 320 for bending the metal plate 105 along the inclined surface (211a) of the lower pad (211) when the lowering of the upper holder (250). delete The method of claim 5, wherein The upper holder 250 is a case bending mold for a computer, characterized in that the elastic means for supporting the cam punch 320 in the opposite direction of the lower pad 211 (323) is installed.

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