KR101427288B1 - Forging equipment - Google Patents

Abstract

The present invention relates to forging equipment. According to the present invention, a layout of a supplying unit, which supplies a material to a forging module, is simplified. In addition, when a processed product is withdrawn, damage to the product can be minimized. According to the present invention, the forging equipment includes: a forging module including a forging mold which processes the product by forging a material; a material supplying device which supplies the material to the forging module; and a withdrawal device which withdraws the product forged by the forging module to the outside. The material supplying device is formed to supply the material cut in the shape of a cylinder to a side of the forging module and includes: a supplying case; a transferring unit which is installed inside the supplying case to transfer the material from a lower side to an upper side; and a charging unit which charges the material into the supplying case.

Description

FORGING EQUIPMENT

The present invention relates to a forging equipment, and more particularly, to a forging equipment which simplifies the layout of a supply unit for supplying a material to a forging module, .

Forging is a kind of machining method that makes solid metal material into a certain shape by mechanical method of kneading or pressing with a hammer or the like. Forging temperature may be room temperature, but it is necessary to heat a forging material having a high melting point There are many times. The forging at a temperature higher than the temperature at which the recrystallization proceeds in the forging material is referred to as hot forging and forging at a lower temperature is referred to as cold forging do.

Such forging equipment includes a forging module having a forging die and a cooling unit, a material supply device for supplying the material to the forging module, and a take-out device for taking out the forged product by the forging module.

On the other hand, a material supply device for a forging equipment for manufacturing a cylindrical product such as a suspension part, a screw part, and a piston of an automobile includes a coil injector for injecting a coil material wound in a coil shape, and a coil material fed through the coil injector And an uncoiler that straightens and uncoiler is transported. The uncoiler calibrating rollers are linearly calibrated for the coil material, and the calibrated coil material is cut in a shearing manner by a shearing cutter and then transported to a forging mold (see Patent No. 10-0280894).

As described above, in the conventional forging equipment, when the diameter of the product to be machined is large, the diameter of the coil material must be correspondingly increased. However, the diameter of the coil material is limited, and when the diameter of the coil material is more than a predetermined value Coil feeder, uncoiler, etc., and the breakage of the forging die frequently occurs, resulting in a very low productivity.

Further, since the conventional forging equipment is required to cut the coil material through a cutter after straightening the coil material, the coiler material dispenser, the uncoiler and the cutter must be arranged in line on the supply side of the forging module, .

Also, in the conventional forging equipment, the take-out device for taking out the product processed by the forging module is configured to take out the product to the packaging container by a free-fall method, so that the product is seriously damaged.

KR 10-0280894 B1 (Nov. 14, 2000)

SUMMARY OF THE INVENTION The present invention has been made to overcome the above-mentioned disadvantages of the prior art, and it is an object of the present invention to provide a method and apparatus for rapidly and stably supplying a cut material to a forging module instead of a coil material, It is an object of the present invention to provide a forging equipment which occupies less installation space by simplifying the layout.

It is another object of the present invention to provide a forging equipment capable of minimizing damage to a product during the taking out of the processed product from the forging module.

In order to accomplish the above object, according to the present invention,

A forging module having a forging die for working a product by forging the material, a material supplying device for supplying the material to the forging module, and a take-out device for taking out the forged product by the forging module,

The material supply device is configured to supply a cylindrical material having a height shorter than the width thereof to the forging module side,

Wherein the material supply device includes a supply case, a transfer unit provided in the supply case for transferring the material from the lower part to the upper part, and a charging unit for charging the material into the supply case,

Wherein the transfer unit comprises a plurality of step members provided in a stepped structure in which the positions of the respective upper ends are increased from the front to the rear in the inside of the supply case and a plurality of transfer members provided so as to be vertically movable between the plurality of step members Including,

The bottom dead center of the vertically moving distance of each of the conveying members corresponds to the top rearward point of the step member adjacent to the lower side thereof and the top dead center of the vertical moving distance corresponds to the top forward point of the step member adjacent to the top side,

The upper end of the conveying member and the upper end of the step member are each formed with an inclined surface inclined downward in the feeding direction,

The inclined surface of the conveying member and the inclined surface of the step member are inclined at the same inclination angle.

The charging unit includes a charging frame disposed adjacent to the front end of the supply case and a charging hopper provided rotatably through the charging frame via the hinge.

Wherein the take-out apparatus includes a take-out guide unit for guiding products taken out of the forging module and a drop buffering unit disposed at a lower end of the take-out guide unit,

The take-out guide unit includes a guide frame which is inclined downward at a discharge portion of the forging module, and a plurality of guide members provided inside the guide frame.

The plurality of guide members are spaced apart from each other so as to form a take-out passage in the guide frame, and are disposed in a diagonal direction.

The dropping shock absorbing unit includes a movable frame provided on a support frame so as to be movable up and down, a drop buffer frame provided at a lower end of the movable frame, and a plurality of buffer blades rotatably provided inside the drop buffer frame .

According to the present invention, it is possible to quickly and stably supply the material cut in a cylindrical shape instead of the wire-like material to the forging module side, and more particularly, to simplify the layout of the material supply device supplied to the forging module, .

Further, the present invention has an advantage that the damage of the product can be minimized while taking out the processed product from the forging module.

1 is a plan view showing a forging equipment according to an embodiment of the present invention.
Fig. 2 is a view from the direction of arrow A in Fig.
Fig. 3 is a view showing a material to be transferred and forged by the present invention. Fig.
FIG. 4 is a side view showing a transfer unit installed in the supply case of FIG. 2, and shows the transfer members of the transfer unit moving downward.
FIG. 5 is a view showing a state in which the conveying members are moved upward in the state of FIG. 4. FIG.
6 is an enlarged view of a portion indicated by an arrow B in Fig.
Fig. 7 is a perspective view showing the equipment for taking out the forging equipment according to the present invention. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. For the sake of convenience, the size, line thickness, and the like of the components shown in the drawings referenced in the description of the present invention may be exaggerated somewhat. The terms used in the description of the present invention are defined in consideration of the functions of the present invention, and thus may be changed depending on the user, the intention of the operator, customs, and the like. Therefore, the definition of this term should be based on the contents of this specification as a whole.

1 to 7 are views showing a forging equipment according to an embodiment of the present invention.

1, the forging equipment according to the present invention includes a forging module 10 having a forging die 11 for processing a product by forging the material, a material supplying unit (not shown) for supplying the material to the forging module 10, An apparatus 20, and a take-out device 30 for taking out a product forged by the forging module 10 to the outside.

A forging die 11 for processing a material and a cooling unit (not shown) for cooling the product to be processed by the forging die 11 are built in the forging module 10. A material conveying pipe 13 for conveying the material m to the inlet portion of the forging die 11 is disposed inside the forging module 10.

The material supply device 20 is configured to supply the material m previously cut toward the forging module 10. The material m is made of a material coated after the annealing heat treatment after it is cut in advance. As shown in Fig. 3, as the round bar of a certain length is cut, the work m has a cylindrical structure having a height H shorter than the width W thereof, as shown in Fig. ≪ / RTI >

An aligning mechanism 40 is disposed between the material supplying device 20 and the forging module 10 and aligns the materials to be fed in a line. To the forging die (11) of the mold (10).

The material supply device 20 includes a supply case 21, a transfer unit 50 installed in the supply case 21 to transfer the material from the lower part to the upper part, and an input unit 60).

A feed slope 25 is formed in the inner front of the feed case 21 and a feed slope 25 is formed on the front side of the feed unit 50 And can naturally guide the fed materials m to the transfer unit 50.

A feed passage 26 is formed at one side of the feed case 21 so that materials that are not aligned in the aligning mechanism 40 can be conveyed through the return passage 26 and returned to the inside of the feed case 21 have.

4 to 6, the transfer unit 50 is provided with a plurality of step members 51 provided inside the supply case 21 and a plurality of step members 51 which are installed so as to be movable up and down between the plurality of step members 51 And includes a plurality of conveying members 52.

A plurality of step members 51 are vertically installed in the interior rear of the supply case 21 so that the step members 51 are spaced apart from each other. Are vertically movable.

The plurality of step members 51 are fixedly installed in a stepwise structure in which the upper end position thereof increases from the front to the rear. At the upper end of each step member 51, an inclined surface 51a inclined downward toward the supply direction is formed.

The plurality of conveying members 52 are vertically movable between the step members 51 and are vertically movable by an actuator (not shown) such as a cylinder mechanism or a transmission mechanism. Particularly, each of the conveying members 52 moves up and down by a certain distance S between the step members 51 adjacent to the lower side and the step members 51 adjacent to the upper side.

6, the bottom dead center S1 of the vertical movement distance S of each of the conveying members 52 corresponds to the rear upper rear point of the step member 51 adjacent to the lower side, Is configured to correspond to an upper front point of the step member 51 adjacent to the upper side.

The inclined surface 52a of the conveying member 52 and the inclined surface 51a of the step member 51 are formed at the same inclination angle with respect to each other at the upper end of each conveying member 52 .

The operation in which the material m is transported by the structure of the transfer unit 50 will be described in detail as follows.

4, the inclined surfaces 52a of the respective conveying members 52 are positioned in correspondence with the inclined surfaces 51a of the step members 51 adjacent to the lower side of the conveying members 52. In addition, The inclined surface 52a of the conveying member 52 located in the supply case 21 is positioned corresponding to the conveying slope 25 of the supply case 21. [ In this state, the materials m input by the input unit 60 are raised on the inclined surface 52a of the conveying member 52 positioned at the lowermost end.

5, when all the conveying members 52 are moved upward and the inclined surfaces 52a of the respective conveying members 52 are positioned corresponding to the inclined surfaces 51a of the step members 51 adjacent to the upper side, The materials m are slid and conveyed on the inclined surface 51a of the step member 51 at the inclined surface 52a of the conveying member 52. [ 6, when the conveying member 52 is moved upward (see the dotted line) after the material m is raised on the inclined surface 52a of the downwardly moved conveying member 52, Is slid and conveyed from the inclined surface (52a) of the member (52) to the inclined surface (51a) of the step member (51).

 The work m moves from the inclined surface 52a of the lowermost conveying member 52 to the inclined surface 51a of the step member 51 positioned at the next stage.

The material m located on the inclined surface 51a of the step member 51 is continuously moved to the inclined surface 52a of the conveying member 52 located at the next stage As a result of this operation being repeated, the plurality of workpieces m are moved stepwise through the inclined surface 52a of the conveying member 52 and the inclined surface 51a of the stepped member 51, and then stepwise.

Thus, as the conveying members 52 repeat the downward movement and the upward movement between the step members 51, the materials m are conveyed stepwise from the bottom to the top.

The inclined angle of the conveying inclined surface 25 may be equal to or slightly smaller than the inclined surfaces 52a and 51a of the conveying member 52 and the step member 51. In particular, And the inclined surfaces 52a and 51a of the step member 51 so that the materials m to be fed can be more smoothly guided to the conveying unit 50 side.

5, the inclined surface 51a of the conveying member 51 is inclined downward in the state that the lowermost conveying member 51 is moved downward, And is positioned corresponding to the transport slope 25. The materials m put in by the input unit 60 naturally slide and move along the inclined surface 25 of the conveying member 51 at the lowermost stage along the conveying inclined surface 25. [

The charging unit 60 includes a charging frame 61 disposed adjacent to the front end of the supply case 21 and a charging hopper 64 provided rotatably through the charging frame 61 via a hinge 63 .

A plurality of materials m are supplied to the feed hopper 64 when the hopper 64 is rotated through the hinge 63 so that a plurality of materials m are accommodated in the hopper 64, And is introduced into the conveying slope 25 of the casing 21. [

As shown in Figs. 1 and 7, the take-out device 30 is configured to take out forged products from the forging module 10, and in particular, the take-out device 30 includes a take-out guide unit 31 and a drop buffering unit 35 disposed at the lower end of the take-out guide unit 31.

The takeout guide unit 31 includes a guide frame 32 which is inclined downward from the discharge portion 15 of the forging module 10 and a plurality of guide members 33 provided inside the guide frame 32 .

A discharge opening 32a is formed in the lower end of the guide frame 32. A plurality of guide members 33 are spaced apart from each other so as to form a takeout passage 34 in the guide frame 32, .

7, the dropping shock absorbing unit 35 includes a movable frame 37 provided to the support frame 36 so as to be movable up and down by a drive unit 39 and a movable frame 37 provided at the lower end of the movable frame 37 And includes a buffer frame 38 and a plurality of cushioning blades 38a rotatably provided in the drop cushion frame 38.

The movable frame 37 is configured to move up and down with respect to the support frame 36 by a drive unit 39 composed of a drive motor 39a and a drive strip 39b.

 As shown in Fig. 7, the fall buffer frame 38 is structured such that its interior is opened up and down. As shown in FIG. 1, a plurality of cushioning blades 38a are symmetrically rotatably provided at the lower end opening of the dropping cushion frame 38. Each cushioning blade 38a is pivoted by a hinge 38b Lt; / RTI >

With the configuration of the take-out device 30, products forged in the forging module 10 are guided by the plurality of guide members 33 in the guide frame 32 of the takeout guide unit 31 while being buffered. The products thus guided are sufficiently buffered when the products taken out as the buffering wings 38a of the dropping cushion frame 37 rotate while the moving frame 35 is moved up and down are dropped onto the packaging container P, Can be minimized.

According to the present invention as described above, since the material supply device 20 has a structure in which the material m is sequentially fed and fed from the lower part to the upper part in a stepwise manner, the layout can be further simplified, 20 can be installed in various directions in a direction orthogonal to the inserting portion of the forging module 10 or diagonally without requiring the module 20 to be arranged in a row in the forging module 10, There are advantages.

While the present invention has been described in connection with what is presently considered to be practical 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. .

10: forging module 11: forging mold
20: Material supply device 21: Supply case
25: feed slope 30: take-out device
50: transfer unit 51: step member
52: conveying member 60: input unit

Claims (5)

A forging module having a forging die for working a product by forging the material, a material supplying device for supplying the material to the forging module, and a take-out device for taking out the forged product by the forging module,
The material supply device is configured to supply a cylindrical material having a height shorter than the width thereof to the forging module side,
Wherein the material supply device includes a supply case, a transfer unit provided in the supply case for transferring the material from the lower part to the upper part, and a charging unit for charging the material into the supply case,
Wherein the transfer unit comprises a plurality of step members provided in a stepped structure in which the positions of the respective upper ends are increased from the front to the rear in the supply case and a plurality of transfer members provided so as to be vertically movable between the plurality of step members Including,
Wherein the take-out apparatus includes a take-out guide unit for guiding products taken out of the forging module and a drop buffering unit disposed at a lower end of the take-out guide unit,
The dropping shock absorbing unit includes a movable frame provided on a support frame so as to be movable up and down, a drop buffer frame provided at a lower end of the movable frame, and a plurality of buffer blades rotatably provided inside the drop buffer frame Forging equipment. The method according to claim 1,
Wherein the charging unit includes a charging frame disposed adjacent to a front end of the supply case and a charging hopper rotatably mounted to the charging frame via a hinge. The method according to claim 1,
Wherein the takeout guide unit comprises a guide frame which is inclined downward at a discharge portion of the forging module, and a plurality of guide members provided inside the guide frame. The method of claim 3,
Wherein the plurality of guide members are spaced apart from each other in a diagonal direction so as to form a take-out passage inside the guide frame. delete

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