KR102285728B1 - Contact heating apparatus for material heat treatment - Google Patents

Abstract

The present invention relates to a conductive heating device for heat treatment of a material. The upper and lower heating elements are in contact with the upper and lower surfaces of the material in a state of resistance heating to the target temperature, and conduction heating of the material. Upper and lower insulators block heat to each periphery of upper and lower heating elements. The upper and lower tension adjustment mechanism adjusts the tension of the upper and lower heating elements respectively while the upper and lower heating elements conduct and heat the material. The upper and lower lifting mechanism lifts the upper and lower heating elements, respectively. The upper and lower current supplies apply current to the upper and lower heating elements. The control panel controls the upper and lower tension adjustment mechanisms, the upper and lower lifting mechanisms, and the upper and lower current supplies.

Description

Conductive heating apparatus for material heat treatment

The present invention relates to an apparatus for heating a material such as a blank for heat treatment in a hot stamping process or the like.

Recently, in the vehicle industry, high-strength steel materials such as boron steel, which have high strength-to-weight ratio, are being widely applied to reduce vehicle weight and improve stability. However, since high-strength steel has low formability and causes excessive springback, it is difficult to manufacture a mold for molding high-strength steel. A hot stamping process may be used as a forming technique to solve these difficulties. Hot stamping has the advantage of improving the formability of high-strength steel and reducing springback to a minimum.

Hot stamping is a process for manufacturing a molded product by heating a material to 900°C or higher and then rapidly cooling it at the same time as molding in a mold. The core technology is material heating and cooling technology. In the current hot stamping process, a heating device configured to heat a material by using a high-temperature atmospheric gas has an excessive installation area due to an enlargement of the material, and inefficient use of energy is a problem because the heating time of the material is quite long.

An object of the present invention is to provide a conductive heating device for material heat treatment that can increase energy efficiency and reduce production cycle time, and can uniformly heat a material regardless of the shape of the material.

Conductive heating device for material heat treatment according to the present invention for achieving the above object is an upper and lower heating element, upper and lower insulation materials, upper and lower tension adjusting mechanism, upper and lower lifting mechanism, upper and lower current supply, and a control panel. The upper and lower heating elements are in contact with the upper and lower surfaces of the material in a state of resistance heating to the target temperature, and conduction heating of the material. Upper and lower insulators block heat to each periphery of upper and lower heating elements. The upper and lower tension adjustment mechanism adjusts the tension of the upper and lower heating elements respectively while the upper and lower heating elements conduct and heat the material. The upper and lower lifting mechanism lifts the upper and lower heating elements, respectively. The upper and lower current supplies apply current to the upper and lower heating elements. The control panel controls the upper and lower tension adjustment mechanisms, the upper and lower lifting mechanisms, and the upper and lower current supplies.

According to the present invention, it is possible to increase the energy efficiency and reduce the production cycle time by shortening the heating time of the material compared to the atmospheric heating device that heats the material in a convection manner by the high-temperature atmospheric gas, and installation according to the increase in space utilization efficiency It has an advantageous effect on area reduction.

In addition, according to the present invention, since it is possible to uniformly heat the material regardless of the shape of the material rather than directly energizing the material, there is an advantageous effect in expanding the application range.

1 is a front view of a conductive heating device for material heat treatment according to an embodiment of the present invention.
FIG. 2 is a front view in which a part is extracted and shown in FIG. 1 .
3 is a bottom view of the upper heating element in FIG. 1 .
Fig. 4 is a bottom view showing a partial region in Fig. 3;
FIG. 5 is a side view of FIG. 1 ;
FIG. 6 is a plan view of an example of a lower lifting motion converter in FIG. 1 .

The present invention will be described in detail with reference to the accompanying drawings as follows. Here, the same reference numerals are used for the same components, and repeated descriptions and detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. The embodiments of the present invention are provided in order to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer description.

1 is a front view of a conductive heating device for material heat treatment according to an embodiment of the present invention. FIG. 2 is a front view in which a part is extracted and shown in FIG. 1 . 3 is a bottom view of the upper heating element in FIG. 1 . Fig. 4 is a bottom view showing a partial region in Fig. 3; FIG. 5 is a side view of FIG. 1 ; 6 is a plan view of an example of the lower lifting motion converter in FIG. 1 .

1 to 6, the conductive heating apparatus 100 for material heat treatment according to an embodiment of the present invention includes upper and lower heating elements 111 and 116, upper and lower heat insulating materials 121 and 126, and upper , It includes a lower tension adjusting mechanism (131, 136), and upper and lower lifting mechanisms (141, 146), and upper and lower current supplies (151, 156), and a control panel (160).

The upper and lower heating elements 111 and 116 are respectively in contact with the upper and lower surfaces of the material 10 in a state where resistance is heated to a target temperature to conduct heating of the material 10 . Here, the material 10 may be a blank in which a plate material such as bronze steel, aluminum, or magnesium is cut to a set size.

The upper and lower heating elements 111 and 116 may each have a plate-shaped structure. The upper and lower heating elements 111 and 116 are disposed in a state in which both wide surfaces face each other in an upward and downward direction. The upper and lower heating elements 111 and 116 may each have a larger area than the material 10 .

Accordingly, the upper and lower heating elements 111 and 116 are in contact with the upper and lower surfaces of the material 10 in a wide area as possible to conduct and heat the material 10 in accordance with the heat conduction principle. The upper and lower heating elements 111 and 116 may each have a combined structure in which a plurality of divided pieces are arranged in a line. The upper and lower heating elements 111 and 116 may form a pair.

The upper and lower heating elements 111 and 116 may be made of a material that can be used within a maximum range of 1,800°C. For example, the upper and lower heating elements 111 and 116 may each be made of a metal material such as Kanthal. Kanthal is a brand name for an alloy composed mainly of iron and chromium and aluminum. Kanthal can withstand high temperatures and has high electrical resistance. Accordingly, the upper and lower heating elements 111 and 116 enable effective conduction heating of the material 10 by energizing heating.

The lower heating element 116 is loaded by placing the material 10 input from one side on the upper surface. The upper heating element 111 is disposed above the lower heating element 116 with the lower surface facing the upper surface of the material 10 . In this state, the upper and lower heating elements 111 and 116 can be maintained in contact with the upper and lower surfaces of the material 10 by vertically moving close to each other by the upper and lower lifting mechanisms 141 and 146 .

The upper and lower heat insulators 121 and 126 block heat to each periphery of the upper and lower heating elements 111 and 116 . After the heating temperature of the upper and lower heating elements 111 and 116 reaches the target temperature, radiation and convective heat may cause malfunction of peripheral devices. The upper and lower insulators 121 and 126 minimize the effect of radiation and convective heat by the upper and lower heating elements 111 and 116 on peripheral devices.

The upper and lower insulators 121 and 126 allow the upper and lower heating elements 111 and 116 to more effectively conduct and heat the material 10 through the contact portion of each material 10 in a state where heat loss is minimized. In addition, the upper and lower insulators 121 and 126 may insulate the periphery while current is applied to heat the upper and lower heating elements 111 and 116 .

The upper insulator 121 may be disposed on the upper surface of the upper heating element 111 . The lower insulator 126 may be disposed on a lower surface of the lower heating element 116 . The upper and lower insulators 121 and 126 are sized to cover the upper surfaces of the upper and lower heating elements 111 and 116 as wide as possible. The upper and lower insulators 121 and 126 may be made of fire bricks, respectively. Of course, the upper and lower insulators 121 and 126 may be made of various materials such as ceramics having excellent heat resistance/insulation performance.

The upper and lower tension adjustment mechanisms 131 and 136 respectively adjust the tension of the upper and lower heating elements 111 and 116 while the upper and lower heating elements 111 and 116 conduct and heat the material 10 . The upper and lower heating elements 111 and 116 thermally expand as the temperature increases from a low temperature to a high temperature, and thermally contract as the temperature decreases from a high temperature to a low temperature. In this process, the flatness of the upper and lower heating elements 111 and 116 is changed.

The upper and lower tension adjusting mechanisms 131 and 136 adjust the tension of the upper and lower heating elements 111 and 116 according to the thermal expansion/thermal contraction of the upper and lower heating elements 111 and 116, thereby adjusting the tension of the upper and lower heating elements 111 and 116. ) to maintain the flatness at a certain level. Accordingly, the upper and lower heating elements 111 and 116 are uniformly in contact with the upper and lower surfaces of the material 10 while conducting the heating of the material 10 , thereby effectively conducting heating.

The upper tension adjusting mechanism 131 may include a plurality of upper tension adjusting units 131a for independently adjusting the tension for each region of the upper heating element 111 . The upper tension adjusting units 131a are arranged to correspond to the divided pieces of the upper heating element 111 by a predetermined number to adjust the tension of the divided pieces. Each upper tension adjusting unit 131a may include an upper gear motor 132 , a motion converter 133 for adjusting upper tension, and an upper load cell 134 .

The upper gearmotor 132 is controlled by the control panel 160 . The upper gear motor 132 is formed in a form having a gear on the rotational drive shaft. The upper gear motor 132 is configured to generate forward and reverse rotational force. The upper gear motor 132 has a body fixed to the upper lifting frame 102 .

The motion converter 133 for adjusting the upper tension converts the rotational motion of the upper gear motor 132 into a linear motion to extend or contract the corresponding area of the upper heating element 111 . The motion converter 133 for adjusting the upper tension may include a screw (133a), intermediate gears (133b, 133c), a horizontal moving block (133d), a linear guide (133e), and a horizontal movable body (133f). there is.

The screw 133a is rotatably supported by a bearing or the like on the upper elevating frame 102 in a state in which it is horizontally arranged in parallel with the tension adjustment direction of the upper heating element 111 . The intermediate gears 133b and 133c are sequentially meshed with the gears of the upper gearmotor 132 to transmit the rotational force of the upper gearmotor 132 to the screw 133a.

The horizontal moving block 133d is screw-coupled to the screw 133a and linearly reciprocates to be close to or spaced apart from the upper heating element 111 according to the rotation direction of the screw 133a. The linear guide 133e guides the horizontal moving block 133d to linearly reciprocate in the horizontal direction with respect to the upper lifting frame 102 .

One side of the horizontal movable body (133f) is fixed to the horizontal moving block (133d) and linearly reciprocates according to the linear reciprocation of the horizontal moving block (133d). Here, one end of the upper heating element 111 is fixed to the horizontal movable body 133f via the first upper electrode among the upper electrodes 153 , and the other end of the upper heating element 111 is the upper electrode 153 . Among them, it may be fixed to the upper lifting frame 102 via the second upper electrode. Accordingly, the horizontal movable body 133f makes it possible to adjust the tension of the upper heating element 111 by pulling or pushing one end of the upper heating element 111 as it linearly reciprocates.

The upper load cell 134 measures the stress in the corresponding region of the upper heating element 111 and provides it to the control panel 160 . The control panel 160 feedback-controls the upper gearmotor 132 based on the stress value measured from the upper load cell 134 to adjust the tension of the upper heating element 111 , so that the upper heating element 111 has a certain level of flatness. make it possible to maintain

The control panel 160 drives the upper gearmotor 132 to extend the upper heating element 111 until the stress value measured from the upper load cell 134 reaches a reference stress value during thermal expansion of the upper heating element 111 . can In addition, the control panel 160 operates the upper gear motor 132 to contract the upper heating element 111 until the stress value measured from the upper load cell 134 reaches the reference stress value during thermal contraction of the upper heating element 111 . can be driven

The lower tension adjusting mechanism 136 may include a plurality of lower tension adjusting units for independently adjusting the tension for each region of the lower heating element 116 . The lower tension adjusting units may be arranged to adjust the tension of the divided pieces of the lower heating element 116 by a predetermined number. Each lower tension adjustment unit may include a lower gear motor 137 , a motion converter 138 for lower tension adjustment, and a lower load cell 139 .

The lower gearmotor 137 is controlled by the control panel 160 . The lower gear motor 137 is configured in the same way as the upper gear motor 132 and may be mounted on the lower lifting frame 103 . The lower tension adjustment motion converter 138 converts the rotational motion of the lower gear motor 137 into a linear motion to extend or contract the corresponding area of the lower heating element 116 . The lower tension adjustment motion transducer 138 is configured in the same manner as the upper tension adjustment motion transducer 133 , and may be mounted on the lower lifting frame 103 .

The lower load cell 139 measures the stress in the corresponding region of the lower heating element 116 and provides it to the control panel 160 . The lower load cell 139 may have the same configuration as the upper load cell 134 . That is, the lower tension adjustment mechanism 136 may be paired with the upper tension adjustment mechanism 131 .

As in the upper tension adjusting mechanism 131, the control panel 160 feedback-controls the lower gear motor 137 based on the stress value measured from the lower load cell 139 to adjust the tension of the lower heating element 116, It enables the lower heating element 116 to maintain a certain level of flatness.

The upper and lower lifting mechanisms 141 and 146 raise and lower the upper and lower heating elements 111 and 116, respectively. The upper and lower lifting mechanisms 141 and 146 bring the upper and lower heating elements 111 and 116 closer to or spaced apart from each other in a vertical direction. Therefore, the material 10 is inserted between the upper and lower heating elements 111 and 116 spaced apart, and in a state in which it is placed on the lower heating element 116 and is loaded, the upper and lower heating elements 111 and 116 move upward according to the proximity movement. It is possible to maintain a state in contact with the lower heating elements (111, 116). In this state, the material 10 is conductively heated by the upper and lower heating elements 111 and 116 in the heated state.

The lower elevating mechanism 146 may be configured to quickly and macroscopically bring the lower heating element 116 located at the bottom dead center to the upper heating element 111 within a few seconds. For example, the lower lifting mechanism 146 may include a screw motor 147 and a lower lifting motion converter 148 .

The screw motor 147 is controlled by the control panel 160 . The control panel 160 may control the elevation position of the lower heating element 116 by driving the screw motor 147 based on information sensed from an encoder or a position sensor of the screw motor 147 . The screw motor 147 is formed with driving screws 147a for rotationally driving on both sides. The screw motor 147a is configured to generate forward and reverse rotational force. The screw motor 147 has a body fixed to the lower support frame 101a in a state in which the driving screws 147a are arranged to rotate about a horizontal axis.

The lower elevating motion converter 148 converts the rotational motion of the screw motor 147 into a linear motion to elevate the lower heating element 116 . The lower movement converter 148 for elevating may be configured as a rack jack (rack jack). The rack jack is supported by the lower support frame (101a), and the lifting rods (148e) are fixed to the lower lifting frame (103). The rack jack can elevate the lower heating element 116 by converting the rotational motion of the screw motor 147 into a linear motion of the elevating rods 148e and elevating the lower elevating frame 103 .

In the rack jack, two bevel gear sets 148a are connected to the drive screws 147a of the screw motor 147 by first rotating shafts 148b, and four jack modules 148c are connected to the second rotating shaft. (148d) is made in a form connected to the bevel gear sets (148a) by two. Here, the first rotation shafts 148b are respectively fixed to the driving screws 147a and are horizontally arranged, and the second rotation shafts 148d are horizontally arranged in a state orthogonal to the first rotation shafts 148b. .

The bevel gear sets 148a are supported by the lower support frame 101a with the screw motor 147 interposed therebetween. The bevel gear sets 148a are configured to transmit the rotational motion of the first rotational shafts 148b to the rotational movement of the second rotational shafts 148d. The jack modules 148c are respectively supported at the four corner portions of the lower support frame 101a.

The jack modules 148c are configured to convert the rotational motion of the second rotating shafts 148d into a linear motion of the lifting rod 148e. Each jack module 148c has a pinion gear coaxially fixed to the second rotation shaft 148d, and the lifting rod 148e to elevate the lifting rod 148e as the pinion gear and the pinion gear engage with the lifting operation. formed rack gears.

On the other hand, the lower support frame 101a may be horizontally moved by the horizontal transfer mechanism 105 under the guidance of the rail 101d with respect to the base frame 101c. The lower heating element 116 may correspond to or deviate from the upper heating element 111 according to the horizontal movement of the lower support frame 101a.

Accordingly, the lower heating element 116 may be moved to correspond to the upper heating element 111 after loading the material 10 in the standby position away from the upper heating element 111 , so that the material 10 may be heat-treated. In addition, the lower heating element 116 may be discharged from the heat-treated material 10 by returning to the standby position away from the upper heating element 111 after the heat treatment of the material 10 is completed.

The lower support frame 101a may include wheels 104 that roll along the rail 101d at the lower end. The horizontal transfer mechanism 105 may include a rotary motor 105a and a motion converter 105b for converting the rotary motion of the rotary motor 105a into a linear motion. The motion converter 105b may be configured in various known configurations, such as including pulleys and a belt.

The upper lifting mechanism 141 allows the upper heating element 111 located at top dead center to be microscopically raised and lowered. When the upper and lower heating elements 111 and 116 are in contact with the material 10, a section in which they do not contact may occur due to processing and assembly tolerances, etc., and the upper lifting mechanism 141 applies the upper heating element 111 to a constant pressure It can be pressurized so that there is no non-contact section. For example, the upper lifting mechanism 141 may include a step motor 142 and an upper lifting motion converter 143 .

The step motor 142 is controlled by the control panel 160 . The control panel 160 may control the elevation position of the upper heating element 111 by driving the step motor 142 based on information sensed from the encoder or position sensor of the step motor 142 . The step motor 142 is formed in a form in which the rotation drive shafts 142a are drawn out from both sides. The step motor 142 is configured to generate forward and reverse rotational force. The step motor 142 has a body fixed to the upper support frame 101b in a state in which the rotational driving shafts 142a are arranged to rotate about a horizontal axis.

The upper elevating motion converter 143 converts the rotational motion of the step motor 142 into a linear motion to elevate the upper heating element 111 . The upper lifting motion converter 143 may be made of a rack jack in the same way as the lower lifting motion converter 148 . The rack jack is supported by the upper support frame (101b), and the lifting rods (143e) are fixed to the upper lifting frame (102). The upper support frame 101b may be supported by the base frame 101c. The rack jack can elevate the upper heating element 111 by converting the rotational motion of the step motor 142 into a linear motion of the lifting rods 143e to elevate the upper lifting frame 102 .

The upper elevating mechanism 141 changes the elevating stroke of the upper heating element 111 according to the amount of thermal expansion of the material 10 while the upper and lower heating elements 111 and 116 conduct and heat the material 10. It is possible to adjust the contact pressing force applied to the upper surface of the Accordingly, the material 10 can be prevented from surface damage by adjusting the contact pressing force by the upper and lower heating elements 111 and 116 .

Here, the correlation between the amount of thermal expansion of the material 10 and the adjustment value of the contact pressing force can be obtained in advance through experiments or simulations, and the upper lifting mechanism 141 is the thermal expansion of the material 10 based on the previously obtained correlation. The contact pressing force can be adjusted according to the amount. For example, the upper lifting mechanism 141 may reduce the contact pressing force in inverse proportion to the increase in the amount of thermal expansion of the material 10 .

The upper and lower current supply units 151 and 156 apply current to the upper and lower heating elements 111 and 116 to energize and heat the upper and lower heating elements 111 and 116 . That is, the upper and lower current supplies 151 and 156 heat the upper and lower heating elements 111 and 116 by joule heat generated when current flows through the upper and lower heating elements 111 and 116 having electrical resistance. do.

The upper current supply 151 may include upper bar busbars 152 , upper electrodes 153 , and upper braided busbars 154 . The upper rod busbars 152 receive current from a current source (not shown). The current source may be controlled by the control panel 160 . For example, the current source may supply current to heat the upper heating element 111 to a target temperature of 1,200° C. within 30 minutes. Of course, the current source may supply the upper heating element 111 with a current set according to conditions such as process conditions and the type of material 10 .

The upper bar busbars 152 apply current to the upper electrodes 153 through the upper braided busbars 154 , thereby enabling the upper heating element 111 to generate resistance heat. The upper bar busbars 152 may be water cooled by the water cooling jacket 152a. The upper bar bus bar 152 is made of a conductive metal material.

The upper electrodes 153 are respectively electrically connected to both ends of the upper heating element 111 to apply a current to the upper heating element 111 . The upper electrodes 153 are made of a conductive metal material. The upper electrodes 153 may be arranged to correspond to the divided pieces of the upper heating element 111 by a predetermined number to apply a current.

Among the upper electrodes 153 , first upper electrodes located at one end of the upper heating element 111 are connected to the upper tension adjusting mechanism 131 . Here, the first upper electrodes may be respectively fixed to the horizontal movable bodies 133f of the upper tension adjusting units 131a. Among the upper electrodes 153 , second upper electrodes located at the other end of the upper heating element 111 are fixed to the upper lifting frame 102 . Accordingly, the first and second upper electrodes are connected to both ends of the upper heating element 111 , and the tension of the upper heating element 111 can be adjusted by the upper tension adjusting mechanism 131 .

The upper braided busbars 154 electrically connect the upper electrodes 153 to the upper bar busbars 152 , respectively. The upper braided busbars 154 transmit current supplied to the upper bar busbars 152 to the upper electrodes 153 . The upper braided busbar 154 is made of a conductive metal material. The upper braided bus bar 154 has a structure that can be elastically deformed. Accordingly, the upper braided busbars 154 are elastically deformed accordingly when the tension of the upper heating element 111 is adjusted, so that the upper heating element 111 can be smoothly stretched and contracted.

The lower current supply 156 may include lower bar busbars 157 , lower electrodes 158 , and lower braided busbars 159 . The lower rod busbars 157 receive current from a current source. The lower electrodes 158 are electrically connected to both ends of the lower heating element 116 , respectively. The lower braided busbars 159 electrically connect the lower electrodes 158 to the lower bar busbars 157 , respectively. The lower current supply 156 may be paired with the same configuration as the upper current supply 151 .

The control panel 160 controls the upper and lower tension adjustment mechanisms 131 and 136 , the upper and lower lifting mechanisms 141 and 146 , and the upper and lower current supplies 151 and 156 . That is, the control panel 160 controls the upper and lower tension adjusting mechanisms 131 and 136 to adjust the respective tensions of the upper and lower heating elements 111 and 116 . The control panel 160 controls the upper and lower lifting mechanisms 141 and 146 to raise and lower the upper and lower heating elements 111 and 116, respectively. The control panel 160 controls the upper and lower current supplies 151 and 156 to supply or block current to the upper and lower heating elements 111 and 116 .

In this way, the conductive heating device 100 for material heat treatment of this embodiment raises the temperature of the upper and lower heating elements 111 and 116 to a target temperature through energized heating, and then heats the upper and lower heating elements 111 and 116 from the material. The material (10) is heated in such a way that it is conducted to (10).

Therefore, the conductive heating apparatus 100 for material heat treatment of this embodiment shortens the heating time of the material 10 than the atmospheric heating apparatus that heats the material 10 in a convection manner by high-temperature atmospheric gas, thereby increasing energy efficiency and producing Cycle time may be reduced, and it may be advantageous to reduce the installation area due to an increase in space utilization efficiency.

In addition, the conductive heating device 100 for material heat treatment of this embodiment can uniformly heat the material 10 irrespective of the shape of the material 10 rather than directly energizing the material 10, so the scope of application is expanded can be beneficial to

A method of conducting heating of the material 10 by the conductive heating device 100 for heat treatment of the material described above will be described as follows.

First, electric current is supplied to the upper and lower heating elements 111 and 116 spaced apart from each other by the upper and lower current supplies 151 and 156 to energize and heat the upper and lower heating elements 111 and 116 to a target temperature. At this time, the upper and lower heating elements 111 and 116 can be energized and heated up to 1,200° C. within 30 minutes by the upper and lower current supplies 151 and 156 .

Next, the material 10 is inserted between the upper and lower heating elements 111 and 116 spaced apart in a state in which the supply of current to the upper and lower heating elements 111 and 116 is cut off. Then, the upper and lower heating elements 111 and 116 are brought into close contact with each other by the upper and lower elevating mechanisms 141 and 146 and brought into contact with both surfaces of the material 10 for a set time period, for example, for 12 to 15 seconds. The material 10 is conductively heated. Then, the material 10 can be heated to raise the temperature to 900 ℃.

During the conduction heating of the material 10, the respective tensions of the upper and lower heating elements 111 and 116 are adjusted by the upper and lower tension adjusting mechanisms 131 and 136, and the upper and lower heating elements 111 and 116 are adjusted to the material ( 10) can be brought into contact in a uniform state. In addition, during the conduction heating of the material 10, by adjusting the contact pressing force of the upper and lower heating elements 111 and 116 applied to the material 10 by the upper lifting mechanism 141, the material 10 according to the contact pressing force to prevent surface damage.

Next, the material 10 is taken out after the upper and lower heating elements 111 and 116 are spaced apart from each other by the upper and lower lifting mechanisms 141 and 146 . Then, current is supplied to the upper and lower heating elements 111 and 116 by the upper and lower current supplies 151 and 156 to reheat the upper and lower heating elements 111 and 116 to a target temperature. In this way, since the heating time to the target temperature is short and only reheating is required after taking out the material 10, there is an advantage of high energy efficiency.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it will be understood that this is merely exemplary, and that various modifications and equivalent other embodiments are possible therefrom by those skilled in the art. will be able Accordingly, the true scope of protection of the present invention should be defined only by the appended claims.

111..Upper heating element 116..Lower heating element
121..Upper insulation 126..Lower insulation
131..Upper tension adjustment mechanism 136..Lower tension adjustment mechanism
141..Upper lifting mechanism 146..Lower lifting mechanism
151..Upper current supply 156..Lower current supply
160..Control panel

Claims (6)

Upper and lower heating elements that are in contact with the upper and lower surfaces of the material in a state where resistance is heated to a target temperature, respectively, to conduct and heat the material;
Upper and lower insulating materials for blocking heat to each periphery of the upper and lower heating elements;
an upper and lower tension adjusting mechanism for respectively adjusting the tension of the upper and lower heating elements while the upper and lower heating elements conduct and heat the material;
upper and lower elevating mechanisms for elevating the upper and lower heating elements, respectively;
upper and lower current supplies for applying current to the upper and lower heating elements; and
A control panel for controlling the upper and lower tension adjustment mechanism, the upper and lower lifting mechanism, and the upper and lower current supply units; includes,
the upper tension adjusting mechanism includes a plurality of upper tension adjusting units for independently adjusting the tension for each area of the upper heating element;
The lower tension adjusting mechanism conduction heating device for material heat treatment, characterized in that it comprises a plurality of lower tension adjusting parts for independently adjusting the tension for each region of the lower heating element. delete According to claim 1,
Each of the upper tension adjustment unit,
An upper gearmotor controlled by the control panel, a motion converter for adjusting the upper tension that converts the rotational motion of the upper gearmotor into a linear motion to extend or contract the corresponding area of the upper heating element, and the corresponding area of the upper heating element an upper load cell that measures the stress and provides it to the control panel;
Each of the lower tension adjustment unit,
A lower gearmotor controlled by the control panel, a motion converter for adjusting the lower tension that converts the rotational motion of the lower gearmotor into a linear motion to extend or contract the corresponding area of the lower heating element, and the corresponding area of the lower heating element Conductive heating device for material heat treatment, characterized in that it includes a lower load cell that measures the stress and provides it to the control panel. According to claim 1,
The upper lifting mechanism,
Conductive heating apparatus for material heat treatment, comprising: a step motor controlled by the control panel; According to claim 1,
The lower lifting mechanism,
Conductive heating device for material heat treatment, comprising: a screw motor controlled by the control panel; According to claim 1,
The upper current supply is,
It includes upper bar busbars receiving current from a current source, upper electrodes electrically connected to both ends of the upper heating element, respectively, and upper braided busbars electrically connecting the upper electrodes to the upper bar busbars, respectively. and;
The lower current supply is
It includes lower bar busbars receiving current from a current source, lower electrodes electrically connected to both ends of the lower heating element, respectively, and lower braided busbars electrically connecting the lower electrodes to the lower bar busbars, respectively. Conductive heating device for material heat treatment, characterized in that.

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