KR101462922B1 - Insulation device for hot stamping press - Google Patents

Abstract

An adiabatic device for a hot stamping press is disclosed. The heat insulating apparatus for a hot stamping press according to an embodiment of the present invention includes a lower die having a blank holder and a lower mold disposed thereon, an upper die mounted on an upper slider from an upper portion of the lower die, A hot stamping press apparatus comprising a top mold for press-molding a material to be inserted between the bottom mold and the bottom mold, wherein the molding of the material is performed while the bottom mold and the top mold are heated to high temperature, Wherein the blank holder is slidably movable left and right on the lower die corresponding to the front of the lower die at a position spaced forward from the outer circumferential surface of the blank holder, And when the material is loaded into and taken out from the lower mold, the front of the lower mold is selectively opened , When the material pressed in the mold, the movable heat insulating portion is configured to slide, by said upper die; And upper and lower portions of the lower die in such a manner as to cover the left side, the right side and the rear side of the lower die at positions spaced apart to the left, right, and rear sides of the outer circumferential surface of the blank holder corresponding to both sides and rear of the movable heat insulating portion And a fixed heat insulating portion that is configured to be slidable by the upper die when the upper mold is pressurized.

Description

TECHNICAL FIELD [0001] The present invention relates to an insulation device for hot stamping presses,

The present invention relates to an adiabatic device for a hot stamping press, and more particularly to an adiabatic device for a hot stamping press for maintaining adiabatic heat during warm forming through a press device so that molding of the magnesium alloy sheet material is performed in a warm state .

In general, magnesium alloy sheet is attracting attention as a new material to replace iron or aluminum as lightweight material because density of metal structure is lower than aluminum.

In recent years, in North and Central America, magnesium alloy sheet materials have been applied to automobiles for the purpose of weight reduction, and various press forming techniques for forming such magnesium alloy sheet materials are required.

However, such a magnesium alloy sheet material is excellent in thermal conductivity, and is excellent in fatigue and moldability at high temperatures, but the development of a press molding method corresponding thereto has not been universal.

That is, a general press apparatus is disadvantageous in that it can always be subjected to press molding of a material only at room temperature, and is not suitable for press molding of a material having excellent thermal conductivity and high temperature moldability like a magnesium alloy plate material.

In recent years, a warm-forming press apparatus has been applied in which a mold made of a magnesium alloy sheet material is molded at a high temperature, and a heating line and a cooling line are provided in the mold to hold the mold at a high temperature to perform press molding .

However, since the conventional warm-forming press apparatus is installed so as to be exposed to the outside, even in the cooling by the outside air, in order to maintain the mold at a high temperature until the completion of molding of the material, There is a problem that the power consumption is increased due to an increase in the power consumption.

In addition, the cooling of the press apparatus by the outside air increases the preheating time and the heating time of the mold, thereby decreasing the productivity due to an increase in the time required for completion of molding of the material, And the quality is deteriorated.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a press apparatus in which, during warm forming through a press apparatus such that a magnesium alloy sheet material is molded in a warm state, By improving the preheating and heating effect of the material by wrapping the outside of the press mold to maintain the heat insulation, productivity can be improved by preheating the mold and shortening the heating time, and the press apparatus can be maintained at a predetermined temperature for the time of molding, To thereby improve the molding quality of the hot stamping press.

According to an aspect of the present invention, there is provided an adiabatic device for a hot stamping press, comprising: a lower die having a blank holder and a lower mold disposed thereon; an upper die mounted on a slider at an upper portion of the lower die; And a top die for press-molding a material to be inserted between the lower die and the lower die, wherein the lower die and the upper die are heated to a high temperature, Wherein the upper die and the upper die in a high temperature state during a forming time of the blank holder are separated from each other at a position spaced forward from the outer circumferential surface of the blank holder, And when the material is loaded into and taken out from the lower mold, Selectively open to the front, and when the material pressed in the mold, the movable heat insulating portion is configured to slide, by said upper die; And upper and lower portions of the lower die in such a manner as to cover the left side, the right side and the rear side of the lower die at positions spaced apart to the left, right, and rear sides of the outer circumferential surface of the blank holder corresponding to both sides and rear of the movable heat insulating portion And a fixed heat insulating part that is installed on the upper die and slidable by the upper die when the upper mold is pressurized, and the movable thermal insulating part is disposed in front of the fixed thermal insulating part, A guide rail mounted on both sides of the upper portion of the guide rail, respectively; A movable case slidably mounted to left and right sides of the lower die through the guide rails; A first slide member slidably mounted on an upper portion of each of the movable cases to the inside of the movable cases; A first insulating plate mounted on the inner side of the movable case and the first slide member facing the lower die, respectively; A moving unit installed on each of the movable cases and slidably moving the movable cases on the respective guide rails; And a second slide member mounted on the outer side of the movable case and the first slide member to interconnect the movable case and the first slide member and to provide an elastic force to the first slide member while guiding movement of the first slide member. 1 cushion unit.

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Wherein the movable unit comprises: a rack gear having a predetermined section formed outside the guide rails; A driving motor that is mounted on the rack case so that a rotating shaft is downwardly directed from the lower side of the outer side of the movable case to the rack gear corresponding to the rack gear; And a pinion gear mounted on a rotary shaft of the driving motor and engaged with the rack gear.

The driving motor may be a stepping motor capable of adjusting the rotational direction and the rotational speed thereof.

The first cushion unit includes a first housing mounted on an outer side of the movable case; A first guide rod having one end slidably inserted into the first housing and the other end fixed to the outside of the first slide member; And a first elastic member interposed between the first housing and the first guide rod inside the first housing.

The first elastic member may have a coil spring whose one end is supported by the inner surface of the first housing and the other end is supported by the other end of the first guide rod.

The movable case may have a rectangular frame shape having an opening facing the lower mold and an upper opening facing the upper mold, respectively.

The fixing means may include a permanent magnet mounted on at least one of outer sides of the guide rails and fixing the guide rails to the lower die using a magnetic force.

Wherein the fixed heat insulating portion is fixedly mounted to the lower die on the left, right, and rear sides of the outer periphery of the blank holder, respectively; A second slide member slidably mounted on an upper portion of each of the fixing cases to the inside of each of the fixing cases; A second insulating plate mounted on the inner side of the stationary case and the second slide member facing the lower die, respectively; And a second slide member mounted on the outer side of the fixed case and the second slide member to interconnect the fixed case and the second slide member and to provide the elastic force to the second slide member while guiding the movement of the second slide member. Two cushion units.

The second cushion unit includes: a second housing mounted on an outer side of the fixed case; A second guide rod having one end slidably inserted into the second housing and the other end fixed to the outside of the second slide member; And a second elastic member interposed between the second housing and the second guide rod inside the second housing.

The second elastic member may include a coil spring having one end supported on the inner surface of the second housing and the other end supported on the other end of the second guide rod.

The fixing case may be formed in a rectangular frame shape having an inner side facing the lower mold and an upper side facing the upper mold, respectively.

The fixing means may include a permanent magnet mounted on at least one outer side of the fixed case and fixing the fixed case to the lower die using a magnetic force.

As described above, according to the adiabatic device for a hot stamping press according to the embodiment of the present invention, when warm forming is performed through a press device so that the material of the magnesium alloy sheet material is molded in a warm state, Thereby improving the preheating and heating effect of the material, thereby improving the productivity by preheating the mold and shortening the heating time.

Further, since the press apparatus can be maintained at a high temperature without the influence of outside air through the heat insulation of the heated mold during the press molding of the material, the moldability and the molding quality of the material can be improved and the power for preheating and heating the mold There is also an effect of reducing the usage and the cost.

1 is a front view of an adiabatic apparatus for a hot stamping press according to an embodiment of the present invention.
2 is a side view of an adiabatic device for a hot stamping press according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA in Fig.
4 is a front elevational view of a movable heat insulating part applied to an adiabatic device for a hot stamping press according to an embodiment of the present invention.
5 and 6 are projection views of a fixed heat insulating portion applied to an adiabatic device for a hot stamping press according to an embodiment of the present invention.
7 is an enlarged cross-sectional view of part B of Fig.
8 is a step-by-step operation diagram of an adiabatic apparatus for a hot stamping press according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory only and are not restrictive of the invention, It should be understood that various equivalents and modifications may be present.

1 and 2 are a front view and a side view of an adiabatic device for a hot stamping press according to an embodiment of the present invention, Fig. 3 is a sectional view taken along the line AA in Fig. 1, 5 and 6 are a projection view of a fixed heat insulating portion applied to an adiabatic device for a hot stamping press according to an embodiment of the present invention, and Fig. 7 is a plan view of a movable heat insulating portion applied to a heat insulating device for a stamping press, And Fig.

Referring to the drawings, an adiabatic apparatus 100 for a hot stamping press according to an embodiment of the present invention basically comprises a lower die 7 on which a blank holder 3 and a lower die 5 are provided, An upper die 11 mounted on an upper slider 9 at an upper portion of the lower die 7 and a lower die 11 attached to a lower portion of the upper die 11 to press the work 15, Is applied to a hot stamping press apparatus 1 which includes an upper die 13 for forming a lower die 5 and a lower die 13 and for forming the lower die 5 and the upper die 13 at a high temperature.

In the hot stamping press apparatus 1, the lower mold 5 and the upper mold 13 are provided with a heating line and a cooling line, which are not shown in the figure, and are heated by a heating line at the time of molding the material 15, After the completion of the molding, it is cooled by the cooling line.

Here, the heat insulating device 100 for a hot stamping press according to an embodiment of the present invention is a heat insulating device for a hot stamping press, in which the molding material 15 of the magnesium alloy sheet material is molded in a warm state, The preheating and heating effect of the material 15 is improved by wrapping the outside of the press mold so as to maintain the heat insulation of the press die 1, thereby improving the productivity by preheating the mold and shortening the heating time, And can be maintained at a constant temperature so that the molding quality of the material can be improved.

1 to 3, the heat insulating device 100 for a hot stamping press according to an embodiment of the present invention includes a lower mold 5 and a lower mold 5, And a movable thermal insulating part 110 and a fixed thermal insulating part 150 for insulating the upper mold 13.

The movable heat insulating part 110 is slidably movable left and right on the lower die 7 corresponding to the front of the lower die 5 at a position spaced forward from the outer circumferential surface of the blank holder 3 Respectively.

The movable heat insulating part 110 selectively opens the front of the lower mold 5 when the work 15 is put in and taken out from the lower mold 5 and when the work of the upper mold 13 is pressed, (11) so as to be slidable downward.

3 and 4, the movable heat insulating portion 110 includes a guide rail 111, a movable case 113, a first slide member 115, a first heat insulating plate 117, A unit 119, and a first cushion unit 127. As shown in Fig.

First, the guide rail 111 is disposed on the front side of the fixed heat insulating part 150. The guide rail 111 is fixed to both sides of the lower die 7 with the fixing device 112 Respectively.

Here, the fixing means 112 is made of a permanent magnet, which is mounted on at least one outer lower portion of each of the guide rails 111 and fixes the guide rails 111 to the lower die 7 using a magnetic force .

In this embodiment, the movable case 113 is slidably mounted to the left and right sides of the lower die 7 through the guide rails 111, respectively.

The first slide member 115 is slidably mounted on the movable case 113 from above the movable case 113.

That is, the first slide member 115 remains protruded from the upper portion of the movable case 113, and the upper die 11 is lowered toward the lower die 7 through the operation of the slider 9 And is inserted into the movable case 113 by the upper die 11.

The first heat insulating plate 117 is mounted on the inner side of the movable case 113 and the first slide member 115 facing the lower die 5, respectively.

The first heat insulating plate 117 functions to prevent heat from being radiated to the outside from the lower mold 5 and the upper mold 15 heated to a high temperature state during the molding of the material 15.

In the present embodiment, the mobile unit 119 is installed in each of the movable cases 113 to slide the movable cases 113 on the guide rails 111, respectively.

Here, the moving unit 119 includes a rack gear 121, a driving motor 123, and a pinion gear 127.

First, the rack gear 121 is formed outside the guide rails 111 at predetermined intervals.

The driving motor 125 is mounted on the lower side of the outer side of the movable case 113 so as to correspond to the rack gear 121 such that the rotating shaft 123 faces the rack gear 121.

Here, the driving motor 125 may be a stepping motor capable of adjusting the rotational direction and the rotational speed thereof.

The pinion gear 127 is mounted on the rotating shaft 123 of the driving motor 125 and meshes with the rack gear 121.

That is, when the material 15 is inserted or taken out, the rotation unit 123 of the drive unit 125 is rotated in the reverse direction to rotate the pinion gear 127 in the reverse direction .

In this case, each of the movable cases 113 is fixed to the left and right sides of the lower die 7 along the guide rail 111 by a pinion gear 127 rotated in a reverse direction while engaged with the rack gear 121 To open the front of the lower die 5, respectively.

In this state, when the insertion of the blank 15 into the lower mold 5 is completed, the driving motor 125 is rotated in the forward direction to rotate the pinion gear 127 in the forward direction.

The movable case 113 is guided along the guide rail 111 by the pinion gear 127 rotated in the forward direction while being engaged with the rack gear 121 so that the lower die 7 So as to close the front of the lower die 5, respectively.

The first cushion unit 129 is mounted on the outer side of the movable case 113 and the first slide member 115 to interconnect the movable case 113 and the first slide member 115 .

The first cushion unit 129 guides the movement of the first slide member 115 to be lowered into the movable case 113 by the upper die 11, , Elastic force is applied to the first slide member 115 to return to the initial position.

The first cushion unit 129 includes a first housing 131, a first guide rod 133, and a first elastic member 135.

First, the first housing 131 is formed in a cylindrical shape and is mounted at the center of the outer side of the movable case 113.

One end of the first guide rod 133 is slidably inserted into the first housing 131 and the other end is fixed to the outside of the first slide member 115.

One end of the first guide rod 133 fixed to the first slide member 115 may be bent toward the first slide member 115 and fixed to the first slide member 115 .

The first elastic member 135 is interposed between the first housing 131 and the first guide rod 133 in the first housing 131, Thereby providing an elastic force.

The first elastic member 135 may be a coil spring whose one end is supported by the inner surface of the first housing 131 and the other end is supported by the other end of the first guide rod 133.

When the first slide member 115 is pushed by the upper die 11 and inserted into the movable case 113, the first cushion unit 129 configured as described above is pushed by the first guide rod 133 The first slide member 115 is inserted into the first housing 131 to guide the downward movement of the first slide member 115.

At this time, the first elastic member 135 is compressed by the first slide member 115 inserted into the first housing 131, and the upper mold 13 is pressed against the molding The first slide member 115 is moved upward to return to the initial position by providing the elastic force to the first guide rod 133 when the upper die 11 is lifted.

As shown in FIGS. 3 and 5 to 6, the fixed thermal insulating part 150 is formed on the left and right sides of the outer circumferential surface of the blank holder 3 in correspondence with both sides and rear of the movable thermal insulating part 110, And a fixing means 152 at the upper portion of the lower die 7 so as to surround the left, right and rear sides of the lower die at a rearwardly spaced position.

The fixed die-bonding portion 150 is configured to be slidable downward by the upper die 11 when the upper die 13 is pressed.

The fixed heat insulating part 150 includes a fixed case 151, a second slide member 153, a second heat insulating plate 155, and a second cushion unit 157.

The fixing case 151 is fixedly mounted to the lower die 7 via fixing means 152 on the left, right, and rear sides of the outer circumferential surface of the blank holder 3, respectively.

Here, the fixing means 152 may include a permanent magnet, which is mounted on at least one outer side of the outer side of the fixed case 151 and fixes the fixed case 151 to the lower die 7 using a magnetic force. have.

Although the fixing means 112 and 152 for fixing the guide rails 111 and the fixed case 151 to the lower die 7 are made of permanent magnets in the present embodiment, However, the present invention is not limited thereto, and the fixing means 112 and 151 can be applied by selecting a bolt fastening method using a bracket or a block, welding, or the like.

In this embodiment, the second slide member 153 is slidably mounted on the upper portion of each of the fixed cases 151 to the inside of the respective fixed cases 151.

That is, when the upper die 11 is lowered toward the lower die 7 through the operation of the slider while the second slide member 153 is protruded from the upper portion of the fixed case 151, And is inserted into the interior of the stationary case 151 by means of the die 11.

The second heat insulating plate 155 is mounted on the inner side of the fixed case 151 and the second slide member 153 facing the lower die 5 as shown in Fig.

The second heat insulating plate 155 prevents heat from being radiated to the outside from the lower mold 5 and the upper mold 13 heated to a high temperature while the material 15 is being molded, .

The second cushion unit 157 is mounted on the outer side of the fixed case 151 and the second slide member 153 to interconnect the fixed case 151 and the second slide member 153 .

The second cushion unit 157 guides the movement of the second slide member 153 to return the elasticity of the second slide member 153 to the initial position when the upper die 11 is moved up and down do.

The second cushion unit 157 includes a second housing 159, a second guide rod 161, and a second elastic member 163.

First, the second housing 159 is formed in a cylindrical shape, and is mounted at the center of the outer side of the fixed case 151.

One end of the second guide rod 161 is slidably inserted into the second housing 159 and the other end is fixed to the outside of the second slide member 153.

One end of the second guide rod 161 fixed to the second slide member 153 may be bent toward the second slide member 153 and fixed to the second slide member 153 .

The second elastic member 163 is interposed between the second housing 159 and the second guide rod 161 in the second housing 159 and is inserted into the second guide rod 161 Thereby providing an elastic force.

The second elastic member 163 may be a coil spring whose one end is supported by the inner surface of the second housing 159 and the other end is supported by the other end of the second guide rod 161.

When the second slide member 153 is pushed by the upper die 11 and inserted into the fixed case 151, the second cushion unit 157 configured as described above moves the second guide rod 161 The second slide member 153 is inserted into the second housing 159 to guide the downward movement of the second slide member 153.

At this time, the second elastic member 163 is compressed by the second slide member 161 inserted into the second housing 159, and the upper mold 13 is pressed against the molding When the upper die 11 is lifted up, an elastic force is applied to the second guide rod 161 to raise the second slide member 153 to return to the initial position.

7, the movable case 113 and the fixed case 151 are formed so that the inner side toward the lower die 5 and the upper side toward the upper die 13 are open to the openings, respectively, And can be formed into a rectangular frame shape.

Accordingly, the first heat insulating plate 117 and the second heat insulating plate 155 are mounted on the opened inner side surfaces of the movable case 113 and the fixed case 151.

Hereinafter, the operation and operation of the heat insulating device 100 for hot stamping press according to the embodiment of the present invention will be described in detail.

8 is a step-by-step operation diagram of an adiabatic apparatus for a hot stamping press according to an embodiment of the present invention.

First, the movable thermal insulating part 110 operates the driving motor 125 of the moving unit 119 in the opposite direction to feed the work 15 into the lower mold 5 as shown in S1 of FIG. 8 The movable cases 113 are slid along the guide rails 111 toward the left and right sides of the lower die 7.

Thus, the front of the lower mold 5 is opened, and the material 15 is put into the upper portion of the lower mold 5 through an operator or a robot.

At this time, the lower mold 5 and the upper mold 13 are heated through a heating line (not shown) to maintain a high temperature state. When the filling of the material 15 is completed, The respective driving motors 125 are operated in the forward direction to slide the movable cases 113 toward the center of the lower die 7 to close the front of the lower mold 5, do.

In this state, the upper die 13 is brought into contact with the upper die 11 which is lowered by the upper slider so as to press and form the work 15 seated on the lower die 5, as shown in (S3) And is lowered toward the lower mold (5).

The upper die 11 is provided with the first and second slide members 115 and 153 in contact with the upper ends of the first slide member 115 and the second slide member 153, And the inside of the fixed case 151.

At this time, the first and second slide members 115 and 153 are stably fixed to the inside of the movable case 113 and the fixed case 151 by the first and second cushion units 129 and 157 Slide is moved.

In this state, the material 15 is placed on the lower mold 5 at a high temperature and is molded under a high temperature condition by the pressing force of the upper mold 13 pressing the material 15 at a high temperature The movable thermal insulating part 110 and the fixed thermal insulating part 150 wrap the outer sides of the lower mold 5 and the upper mold 13 so that the lower mold 5 and the upper mold 13 are cooled by the outside air In this state, it is insulated.

Then, when the forming of the blank 15 is completed, the upper die 13 is lifted together with the upper die 11 raised by the slider 9 as shown in (S4) of Fig. 8, The first and second elastic members 135 and 163 of the first and second cushion units 129 and 157 provide elastic forces to the first and second guide rods 133 and 161, 115, and 153 are raised from the movable case 113 and the fixed case 151 to return to the initial position.

When the elevation of the upper die 11 is completed and the first slide member 115 and the second slide member 153 are completely lifted up, as shown in (S5) of FIG. 8, Thereby rotating the driving motor 125 in the reverse direction.

The pinion gear 127 mounted on the rotary shaft 123 of each driving motor 125 is rotated in a state of meshing with the rack gear 121 so that the movable cases 113 are moved along the guide rails 111 And slide to the left and right sides of the lower die 7 to open the front of the lower die 5, respectively.

When the front side of the lower mold 5 is opened, the operator or the robot takes out the molded product from the lower mold 5, inserts another material 15 requiring molding, and then repeats the above- The material 15 is formed.

Therefore, when the heat insulating device 100 for a hot stamping press according to the embodiment of the present invention as described above is applied, the press device 1 is formed so that the material 15 of the magnesium alloy sheet material is molded in a warm state It is possible to improve the productivity by preheating the mold and shortening the heating time by improving the preheating and heating effect of the material by wrapping the outside of the press mold so as to maintain the heat insulation of the press apparatus 1 during warming.

In addition, the press apparatus 1 can be kept at a high temperature without being influenced by outside air through heat insulation of the heated mold during the press forming of the material 15, thereby improving the moldability and molding quality of the material 15 , Saving power by reducing power consumption for pre-heating and heating of molds.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

1: Press apparatus 3: Blank holder
5: Lower mold 7: Lower die
9: Slider 11: Upper die
13: Hexagon 15: Material
100: heat insulating device 110: movable heat insulating part
111: guide rail 113: movable case
115: first slide member 117: first insulating plate
119: mobile unit 121: rack gear
123: rotation shaft 125: drive motor
127: Pinion gear 129: First cushion unit
131: first housing 133: first guide rod
135: first elastic member 150: fixed-
151: fixed case 153: second slide member
155: second heat insulating plate 157: second cushion unit
159: second housing 161: second guide rod
163: second elastic member

Claims (13)

A lower die having a blank holder and a lower die at an upper portion thereof, an upper die mounted on a slider at an upper portion of the lower die, and a top die mounted at a lower portion of the upper die to press- The hot stamping press apparatus according to claim 1, wherein the lower die and the upper die are heated to a high temperature. The hot stamping press apparatus includes a hot stamping press for inspecting the lower die and the upper die at a high temperature during the material forming time In the apparatus,
Wherein the lower die is provided so as to be slidable to left and right on the lower die corresponding to the front of the lower die at a position spaced forward from the outer circumferential surface of the blank holder, A movable heat insulating part which is selectively opened and slidable by the upper die when the upper mold is pressed; And
Right side, and rear side of the lower die at positions spaced apart from the left, right, and rear sides of the outer periphery of the blank holder in correspondence to both sides and rear of the movable heat insulating portion, A fixed heat insulating part configured to be slidable by the upper die when the upper mold is pressurized;
Lt; / RTI >
The movable heat insulating portion
A guide rail mounted on both sides of the upper portion of the lower die with respect to the lower die through the fixing means, respectively, in a state of being disposed in front of the fixed heat insulating portion;
A movable case slidably mounted to left and right sides of the lower die through the guide rails;
A first slide member slidably mounted on an upper portion of each of the movable cases to the inside of the movable cases;
A first insulating plate mounted on the inner side of the movable case and the first slide member facing the lower die, respectively;
A moving unit installed on each of the movable cases and slidably moving the movable cases on the respective guide rails; And
A first slide member mounted on an outer side of the movable case and the first slide member to interconnect the movable case and the first slide member and to provide an elastic force to the first slide member while guiding movement of the first slide member; A cushion unit;
And a heat insulating member for heat sealing the hot stamping press. delete The method according to claim 1,
The mobile unit
A rack gear having a predetermined section formed outside the guide rails;
A driving motor that is mounted on the rack case so that a rotating shaft is downwardly directed from the lower side of the outer side of the movable case to the rack gear corresponding to the rack gear; And
A pinion gear mounted on a rotating shaft of the driving motor and engaged with the rack gear;
Wherein the heat insulating member is made of a thermoplastic resin. The method of claim 3,
The drive motor
And a stepping motor capable of adjusting the rotational direction and the rotational speed of the stepping motor. The method according to claim 1,
The first cushion unit
A first housing mounted on an outer side of the movable case;
A first guide rod having one end slidably inserted into the first housing and the other end fixed to the outside of the first slide member; And
A first elastic member interposed between the first housing and the first guide rod in the first housing;
And a heat insulating member for heat sealing the hot stamping press. 6. The method of claim 5,
The first elastic member
Wherein one end is supported by the inner surface of the first housing and the other end is formed by a coil spring supported at the other end of the first guide rod. The method according to claim 1,
The movable case
Is formed in a rectangular frame shape in which an inner side facing the lower die and an upper side facing the upper die are respectively opened. The method according to claim 1,
The fixing means
Wherein at least one of the guide rails is mounted on an outer lower portion of the guide rails, and the permanent magnets fix the guide rails to the lower die using magnetic force. The method according to claim 1,
The fixed-
A fixed case fixedly mounted on the left and right sides of the outer periphery of the blank holder;
A second slide member slidably mounted on an upper portion of each of the fixing cases to the inside of each of the fixing cases;
A second insulating plate mounted on the inner side of the stationary case and the second slide member facing the lower die, respectively; And
A second slide member mounted on an outer side of the stationary case and the second slide member to interconnect the stationary case and the second slide member and to guide the movement of the second slide member while providing an elastic force to the second slide member, A cushion unit;
And a heat insulating member for heat sealing the hot stamping press. 10. The method of claim 9,
The second cushion unit
A second housing mounted on the outside of the fixed case;
A second guide rod having one end slidably inserted into the second housing and the other end fixed to the outside of the second slide member; And
A second elastic member interposed between the second housing and the second guide rod in the second housing;
And a heat insulating member for heat sealing the hot stamping press. 11. The method of claim 10,
The second elastic member
Wherein one end is supported by the inner surface of the second housing and the other end is formed by a coil spring supported at the other end of the second guide rod. 10. The method of claim 9,
The fixed case
Is formed in a rectangular frame shape in which an inner side facing the lower die and an upper side facing the upper die are respectively opened. 10. The method of claim 9,
The fixing means
Wherein at least one of the permanent magnets is mounted on an outer lower portion of the fixed case, and the fixed case is fixed to the lower die using a magnetic force.

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