KR20210081493A - Press device - Google Patents

Abstract

The present invention relates to a press device including: a plurality of pillars positioned to face each other; and a mold module spaced apart from the pillars between the pillars, having a work object located therein, and cooling the work object. The press device according to the present invention can increase the cooling speed and prevent deformation by a mold during cooling.

Description

press device {PRESS DEVICE}

The present invention relates to a press apparatus, and more particularly, to a press apparatus that increases the cooling rate and prevents deformation by a mold during cooling.

In general, a press device refers to a machine or tool that bends a plate material, that is, a work object at room temperature, or molds it into a mold to transform it into an intended shape and size, and is divided into mechanical presses and hydraulic presses, etc. can be divided

In addition, heat treatment is performed on the work object through a press device, and such heat treatment is subjected to quenching and tempering. Quenching is to increase the hardness and strength of steel, and tempering is a process in which the quenched steel is heated to a suitable temperature and then cooled again in order to impart a suitable toughness to the material.

However, the conventional press apparatus as described above has a problem in that the cooling rate is slow when cooling the molded product, and the molded product is easily deformed when cooling.

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-1560831 (registered on Oct. 8, 2015, title of invention: hot press device).

The present invention has been devised to solve the above-described problems, and an object of the present invention is to provide a press device that increases the cooling rate and prevents deformation by a mold during cooling.

A press device according to the present invention, a plurality of pillars positioned to face each other; and a mold module positioned to be spaced apart from the pillars between each of the pillars, and a work object is positioned therein to cool the work object.

In addition, the mold module may include a connection member to which the mold member is connected; and a mold member connected to the connection member, having a cooling water flow passage formed therein so that the coolant moves, and cooling the work object through the coolant moving the coolant flow passage.

In addition, the mold member has at least one injection hole formed to penetrate from the cooling water flow passage toward the work object and allowing the coolant flowing into the cooling water flow passage to be sprayed onto the work object.

In addition, the cooling water flow path includes: a cooling water inlet into which the cooling water is introduced; a first coolant moving part formed concentrically from the coolant inlet to the mold member to move the coolant; a second cooling water moving unit bent from the first cooling water moving unit to move the cooling water; a third cooling water moving part located outside the first cooling water moving part and formed concentrically from the second cooling water moving part to the mold member to move the cooling water; and a cooling water discharge unit extending from the third cooling water moving unit and discharging the cooling water to the outside of the mold member.

In addition, the injection hole may be provided to penetrate from the first coolant moving part toward the work object.

In addition, the injection hole may be provided to penetrate from the third coolant moving unit toward the work object.

In addition, a cooling water inflow control valve for controlling the cooling water to flow into the mold member is connected to the cooling water inlet, and a cooling water discharge control valve for controlling the cooling water to be discharged to the outside of the mold member to the cooling water outlet characterized in that it is connected.

As described above, the press apparatus of the present invention has the effect of allowing the work object to be cooled through the mold module, so that the work object is cooled faster in the mold even if it is not naturally cooled in a state in which the work object is exposed to the outside.

In addition, by providing a cooling water flow path inside the mold member, the work object is cooled through the cooling water, so that the work object is cooled faster in the mold even if it is not naturally cooled in a state in which the work object is exposed to the outside.

In addition, a spray hole is provided in the mold member to penetrate from the cooling water flow path toward the work object, and the cooling water is directly sprayed on the work object through the injection hole, thereby increasing the cooling rate of the work object.

In addition, since the first coolant moving part is formed concentrically on the mold member inside the mold member, the coolant sufficiently cools the center of the mold member.

In addition, the third cooling water moving unit is formed concentrically from the second cooling water moving unit to the mold member, so that the cooling water sufficiently cools the area away from the center of the mold member.

In addition, the injection hole is passed from the first coolant moving unit toward the work object, so that the cooling water is sufficiently sprayed to the work object located at the center of the mold member through the injection hole.

In addition, by allowing the injection hole to penetrate from the third coolant moving unit toward the workpiece, cooling water is sufficiently injected to the workpiece in a region spaced apart from the center of the mold member through the injection hole.

In addition, by connecting the cooling water inflow control valve to the cooling water inlet and the cooling water discharge control valve to the cooling water discharge unit, it is possible to effectively control whether the coolant flows into the mold member or the coolant is discharged to the outside of the mold member.

1 is a front view showing a press device according to an embodiment of the present invention.
2 is a conceptual view illustrating a state in which a cooling water flow passage is formed in a mold member in a press apparatus according to an embodiment of the present invention.
3 is a conceptual view illustrating a state in which a cooling water flow passage and a spray hole are formed in a mold member in a press apparatus according to an embodiment of the present invention.
4 is a conceptual view illustrating a state in which coolant is sprayed through a spray hole in the press apparatus according to an embodiment of the present invention.
5 is a perspective view showing a state in which a cooling water flow path is formed in a mold member in a press apparatus according to an embodiment of the present invention;
6 is a perspective view illustrating a state in which a cooling water flow passage and a spray hole are provided in a mold member in a press apparatus according to an embodiment of the present invention;
7 is a block diagram showing a cooling device provided in the press device according to an embodiment of the present invention.

Hereinafter, a press device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing a press apparatus according to an embodiment of the present invention, FIG. 2 is a conceptual view showing a state in which a cooling water flow path is formed in a mold member in a press apparatus according to an embodiment of the present invention, and FIG. 3 is this view It is a conceptual diagram showing a state in which a cooling water flow path and a spray hole are formed in a mold member in a press device according to an embodiment of the present invention, and FIG. 4 is a state in which coolant is sprayed through the spray hole in the press device according to an embodiment of the present invention 5 is a perspective view showing a state in which a cooling water flow path is formed in a mold member in a press device according to an embodiment of the present invention, and FIG. 6 is a mold member in the press device according to an embodiment of the present invention. It is a perspective view showing a state in which the cooling water flow path and the injection hole are provided, and FIG. 7 is a configuration diagram showing the cooling device provided in the press device according to an embodiment of the present invention.

1 to 7 , the press apparatus 100 according to an embodiment of the present invention may include a plurality of pillars 110 and a mold module 130 .

A plurality of pillars 110 may be positioned to face each other in the press apparatus 100 .

The mold module 130 may be positioned to be spaced apart from the column 110 between each column 110 , and a plurality of mold modules 130 may be sequentially positioned up and down in the press apparatus 100 .

In addition, the mold module 130 has the work object 101 therein, so that the work object 101 can be cooled.

In the present invention, rather than naturally cooling the work object 101, cooling water C is supplied to the mold member 135 to cool the work object 101 or cooling water C is supplied to the mold member 135. The work object 101 can be cooled by being sprayed on the work object 101 .

Meanwhile, the mold module 130 may include a connection member 133 and a mold member 135 .

The connecting member 133 may be positioned such that the mold member 135 is connected and the mold member 135 faces each other.

The mold member 135 is connected to the connection member 133 , and a coolant flow passage 140 is formed therein so that the coolant C moves, and the coolant C that moves the coolant flow passage 140 works through The object 101 can be cooled.

On the other hand, the mold member 135 may be provided with at least one injection hole 150 to penetrate from the coolant flow passage 140 toward the work object 101 .

The injection hole 150 is formed to penetrate from the coolant flow passage 140 toward the work object 101 , and the coolant C is supplied to the mold member 135 to pass through the coolant flow passage 140 and then the coolant (C) to be directly sprayed onto the work object 101 so that the work object 101 is rapidly cooled.

Meanwhile, the cooling water flow path 140 includes a cooling water inlet 141 , a first cooling water moving unit 143 , a second cooling water moving unit 145 , a third cooling water moving unit 147 , and a cooling water discharging unit 149 . may include.

The coolant inlet 141 may allow the coolant C to flow into the mold member 135 from the outside.

The first cooling water moving unit 143 is connected to the cooling unit inlet 141 , and is formed concentrically from the cooling water inlet 141 to the mold member 135 so that the cooling water C flows into the mold member 135 . make it moveable

The second coolant moving part 145 is bent and formed to extend from the first coolant moving part 143 so that the coolant C can move.

The third cooling water moving unit 147 is located outside the first cooling water moving unit 143 , and is formed concentrically from the second cooling water moving unit 145 to the mold member 135 so that the cooling water C is transferred to the mold member 135 . ) can be moved inside.

The cooling water discharge unit 149 is formed to extend from the third cooling water moving unit 147 so that the cooling water C moves inside the mold member 135 and then is discharged to the outside of the mold member 135 . .

Meanwhile, the injection hole 150 may be provided to penetrate from the first coolant moving unit 143 toward the work object 101 . In addition, the injection hole 150 may be provided to penetrate from the third coolant moving unit 145 toward the work object 101 .

Accordingly, the injection hole 150 causes the cooling water C to flow into the mold member 135 to firstly cool the mold member 135 and then secondarily to be directly sprayed onto the work object 101 , the work object 101 . allow it to cool quickly.

Here, the coolant inflow control valve 205 for controlling the coolant C to flow into the mold member 135 may be connected to the coolant inlet 141 .

Also, a cooling water discharge control valve 207 for controlling the cooling water C to be discharged to the outside of the mold member 135 may be connected to the cooling water discharge unit 149 .

Therefore, when the coolant (C) flows into the mold member 135 through the coolant input passage 201 , the coolant inflow control valve 205 is opened to control the coolant (C) to flow into the mold member 135 . have.

In addition, when the mold member 135 is sufficiently cooled through the cooling water C, the cooling water discharge control valve 207 and the vacuum control valve 209 are opened to discharge the cooling water C to the outside through the cooling water discharge passage 213 . can make it

Hereinafter, a process in which the cooling water C is supplied to the mold member 135 through the cooling device 200 in the press device 100 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, when the coolant C flows through the coolant input passage 201 , the coolant control valve 203 is opened to allow the coolant C to flow into the mold member 135 .

At this time, each mold member 135 is provided with a cooling water inflow control valve 205 , and when the cooling water inflow control valve 205 is opened, the cooling water C is supplied to the mold member 135 , and the cooling water C is supplied to the mold member 135 . The work object 101 positioned between each mold member 135 is cooled through.

Thereafter, when the cooling water (C) is to be discharged to the outside, the vacuum control valve 209 is adjusted to an open state while the cooling water discharge control valve 207 is opened, and a discharge valve 211 connected to the vacuum control valve 209 is performed. The cooling water C is discharged to the outside through the cooling water discharge passage 213 through the

According to the present invention configured and operated as described above, by allowing the work object 101 to be cooled through the mold module 130, even if the work object 101 is not naturally cooled in a state in which the work object 101 is exposed to the outside, it is faster in the mold let it cool

In addition, by providing the cooling water flow path 140 inside the mold member 130, the work object 101 is cooled through the cooling water C, so that the work object 101 is naturally cooled in a state in which the work object 101 is exposed to the outside. Even if it is not done, it cools faster in the mold

In addition, the mold member 130 is provided with a spray hole 150 to penetrate from the coolant flow passage 140 toward the work object 101 , and the coolant C is directly applied to the work object 101 through the spray hole 1500 . By spraying, the cooling rate for the work object 101 is increased.

In addition, since the first coolant moving part 143 is formed concentrically on the mold member 135 inside the mold member 135 , the coolant C sufficiently cools the central portion of the mold member 135 .

In addition, the third cooling water moving unit 147 is formed concentrically from the second cooling water moving unit 145 to the mold member 135 so that the cooling water C is sufficiently cooled in a region away from the center of the mold member 135 . make it

In addition, the injection hole 150 is made to penetrate from the first coolant moving unit 143 toward the workpiece 101 , and through the injection hole 150 to the workpiece 101 located in the center of the mold member 135 . Make sure the coolant is sufficiently sprayed.

In addition, by allowing the injection hole 150 to penetrate from the third coolant moving part 145 toward the workpiece 101 , the workpiece 101 in an area spaced apart from the center of the mold member 135 through the injection hole 150 . ) so that the coolant (C) is sufficiently sprayed.

In addition, by connecting the cooling water inflow control valve 205 to the cooling water inlet 141 and the cooling water discharge control valve 207 to the cooling water discharge unit 149 , the cooling water C is transferred to the inside of the mold member 135 . It is possible to effectively control that the cooling water (C) is discharged to the outside of the mold member (135).

Although a preferred embodiment of the present invention has been described above, it is clear that the present invention can use various changes, modifications and equivalents, and can be equally applied by appropriately modifying the above embodiments. Accordingly, the above description is not intended to limit the scope of the present invention, which is defined by the limits of the following claims.

100: press device C: coolant
101: work object 110: column
130: mold module 133: connecting member
135: mold member 140: cooling water flow path
141: coolant inlet 143: first coolant moving part
145: second cooling water moving unit 147: third cooling water moving unit
149; Cooling water discharge unit 150: injection hole
200: cooling device 201: cooling water input flow path
203: coolant control valve 205: coolant inflow control valve
207: cooling water discharge control valve 209: vacuum control valve
211: discharge valve 213: coolant discharge flow path

Claims (7)

a plurality of pillars positioned to face each other; and
A press apparatus comprising a mold module positioned to be spaced apart from the pillars between the respective pillars, and a work object is positioned therein to cool the work object.
According to claim 1,
The mold module is
a connecting member to which the mold member is connected; and
and a mold member connected to the connection member, a cooling water flow passage formed therein so that the coolant moves, and cooling the work object through the coolant moving the coolant flow passage.
3. The method of claim 2,
The mold member is provided with at least one injection hole formed to penetrate from the cooling water flow passage toward the work piece and the coolant flowing into the cooling water flow passage is sprayed onto the work object.
4. The method of claim 3,
The cooling water flow path,
a cooling water inlet through which the cooling water is introduced;
a first coolant moving part formed concentrically from the coolant inlet to the mold member to move the coolant;
a second cooling water moving unit bent from the first cooling water moving unit to move the cooling water;
a third cooling water moving unit located outside the first cooling water moving unit and formed concentrically from the second cooling water moving unit to the mold member to move the cooling water; and
and a cooling water discharge unit extending from the third cooling water moving unit and discharging the cooling water to the outside of the mold member.
5. The method of claim 4,
The injection hole is a press device, characterized in that provided to penetrate from the first coolant moving unit toward the work object.
5. The method of claim 4,
The injection hole is a press device, characterized in that it is provided to penetrate from the third coolant moving part toward the work object.
5. The method of claim 4,
A cooling water inflow control valve for controlling the cooling water to flow into the mold member is connected to the cooling water inlet;
A cooling water discharge control valve for controlling the cooling water to be discharged to the outside of the mold member is connected to the cooling water discharge unit.

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