KR20130050415A - Furnace for heating material and heating method of use it - Google Patents

Abstract

PURPOSE: A material heating furnace and a material heating method using the same are provided to partition a heating chamber and a cracking chamber, thereby quickly heating a material and regularly maintaining the temperature of the heated material. CONSTITUTION: A material heating furnace includes a heating chamber(120), a cracking chamber(130), a material transferring part(150), and a blocking unit(170). The heating chamber heats a material. The cracking chamber maintains the temperature of the material heated by the heating chamber. The material transferring part is continuously placed throughout the heating chamber and the cracking chamber, and transfers the material. The blocking unit partitions the heating chamber and the cracking chamber, and opens a gap between the heating chamber and the cracking chamber with being linked to the actuation of the material transferring part.

Description

Material Furnace and Material Heating Method Using Them {FURNACE FOR HEATING MATERIAL AND HEATING METHOD OF USE IT}

The present invention relates to a material heating furnace for maintaining and heating the material at a constant temperature for forming a product by hot press forming and a material heating method using the same.

In general, the manufacturing method of hot press forming product is to heat the material at a constant temperature and time inside the heating furnace, and then quickly transfer the material to settle in the mold and before the temperature of the seated material drops Rapidly molding the product to produce, at this time, the mold takes away the heat in the material at the same time as forming the product and increases the strength of the product.

To this end, the temperature inside the heating furnace is maintained at a constant temperature by a plurality of heaters, and the material is introduced into the heating furnace to wait for a predetermined time so that the inside of the material is uniformly heated. Subsequently, the processed material in the shape of the product is transported and seated in the inside of the furnace, and after heating for a predetermined time in the furnace, the material is uniformly heated to form a product.

1 is a perspective view showing a material heating furnace according to the prior art, Figure 2 is a cross-sectional view schematically showing the interior of the material heating furnace according to the prior art.

1 and 2, as an example of the conventional material heating furnace 10, the batch material heating furnace 10 includes a main body 12 having refractory therein. And the heater 14 for heating a raw material up and down inside this main body 12 is provided. In addition, the main body 12 is provided with a support 16 for seating the incoming material (S).

The heater 14 is heated as the power source 10 is applied to the material heating furnace 10 to maintain the atmosphere temperature by heating the inside of the furnace body 12 to a predetermined temperature.

The conventional material heating furnace 10 transfers the processed material S to the heating body main body 12 using the material transportation unit 20 to form a product by hot press forming, and then to the support 16. Settle down.

In addition, the material heating furnace 10 may be formed with an open portion 18 in which one side on the moving line of the material S is opened, and a door 19 for opening and closing the open portion 18 may be provided. .

When the material S (10) is seated on the support 16 through the opening portion 18 by the material transport unit 20, the material heating furnace 10 is closed by the door 18 to prepare for heating, the heater 14 ) To maintain the heating state inside the main body 12 for a predetermined time so that the surface and the inside of the material (S) is uniformly heated, withdraw it to complete the molding of the product.

Figure 3 is a graph showing the heat treatment temperature change of various materials used for hot press forming according to the prior art. Here, x1 is a temperature-time graph of heating of chromium (Cr) material, x ₂ is a temperature-time graph of heating of aluminum (Al) material, and x ₃ is a temperature-time of heating of glass fiber (GI) material. It is a graph. Here, the glass fiber may include a polyimide glass fiber laminate sheet.

Referring to Figure 3, the conventional heating furnace is set to a working temperature of about 800 degrees slightly different depending on the characteristics of the material when heating the material takes about 300 to 640 seconds.

In general, the heat holding time of the material utilizes heat treatment data generated by actual experiments when the same type of furnace is used.

However, in conventional heating furnaces, when the heating and holding time of the material is excessive, the working time is excessive, and the work efficiency and error rate are lowered. Since the product falls sharply, making the product may cause the product to fail because the hardness of the lowered temperature drops.

In addition, conventionally, when air is drawn in and out, external air enters into the furnace and the internal temperature of the furnace decreases, and an oxidation atmosphere is not formed due to air intrusion, causing surface scale of the workpiece. have.

An embodiment of the present invention is to be divided into a heating chamber in which the heating of the material is made and the crack chamber to maintain the heated material at a constant temperature, so that the heating of the material is made quickly, so that the temperature of the heated material is kept constant It is an object to provide a material heating furnace and a material heating method using the same.

Material heating furnace according to an aspect of the present invention the heating chamber for heating the material; A crack chamber which maintains the temperature of the material heated in the heating chamber; A material transport unit which is continuously provided to the heating chamber and the crack chamber to move the material; And a blocking unit provided to partition between the heating chamber and the crack chamber and opening between the heating chamber and the crack chamber in connection with the operation of the material transport unit.

Here, the material transport unit may include a plurality of rollers that are continuously installed in the heating chamber or the crack chamber, and a driving motor connected to drive the plurality of rollers.

In addition, the heating chamber or the crack chamber may further include a material transport unit provided to pull in or out the material.

The apparatus may further include a mobile unit for moving the heating chamber or the crack chamber to be located at an entry or withdrawal position of the material transport unit.

Here, the moving unit is provided between the rail portion provided on the moving line of the heating chamber and the crack chamber, and provided between the rail portion and the heating chamber or the crack chamber to move the heating chamber and the crack chamber by stretching. It may include an actuator to make.

In addition, each of the heating chamber and the crack chamber may include a door portion which is opened in connection with the material transport unit when the material is introduced or removed.

In addition, the blocking unit may include a partition member provided between the heating chamber and the crack chamber, and a lift actuator provided to lift the partition member.

In addition, the blocking unit may include a cooling means provided in the partition member.

For example, the cooling means may include a cooling passage provided in the partition member and a cooling water circulation unit circulating the cooling water in association with the cooling passage.

In addition, the material heating method according to another aspect of the present invention comprises a rapid heating step of initially heating the material to a temperature higher than the working temperature for hot-press forming molding; And a crack heating step of heating the material rapidly heated in the rapid heating step to a working temperature to equalize the internal temperature of the material to the working temperature.

Here, the rapid heating step may be heated to a temperature of 0 to 30% higher than the working temperature of the material.

In addition, the rapid heating step and the crack heating step may be maintained in an inert atmosphere during the heating of the material.

According to one embodiment of the invention, consisting of a two-stage structure of the heating chamber for heating the material and the crack chamber to maintain the temperature of the heated material is possible to heat the temperature difference according to the temperature of the material, accordingly required for heating the material The amount of energy consumed can be reduced. The heating furnace may be heated to a higher temperature than the working temperature of the material in the heating chamber, and then supplied to the crack chamber so that the inside of the material is sufficiently uniformly maintained at the working temperature.

Therefore, the material heating furnace of this embodiment can reduce the energy consumed when the material is heated from the normal temperature to the working temperature, it is possible to reduce the time required to heat the material. In addition, the material heating furnace of this embodiment can maintain the temperature inside the material uniformly by the crack chamber.

As described above, the material heating furnace of the present embodiment can shorten the time required for heating, waiting, and maintaining the material, thereby improving the production speed and the error rate of the product, and improving the product quality due to crack heating of the material. .

1 is a perspective view showing a material heating furnace according to the prior art.
Figure 2 is a cross-sectional view schematically showing the interior of the material heating furnace according to the prior art.
3 is a graph showing the heat treatment temperature change of various materials used for hot press forming according to the prior art.
4 is a perspective view of a material heating furnace according to an embodiment of the present invention.
5 is a cross-sectional view schematically showing the interior of the material heating furnace according to an embodiment of the present invention.
Figure 6 is a perspective view showing the separation of the partition member of the material heating furnace according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

Figure 4 is a perspective view of a material heating furnace according to an embodiment of the present invention, Figure 5 is a cross-sectional view schematically showing the interior of the material heating furnace according to an embodiment of the present invention.

4 and 5, in this embodiment, the material heating furnace 110 is installed at the front end of the press apparatus for hot press forming (Hot Press Forming) work, and supplies the material to the press apparatus in a heated state Molding and cooling of the material can proceed simultaneously.

To this end, the material heating furnace 110 may include a heating body 112.

The heating body 112 is a heating chamber 120 for heating the material to a temperature higher than the proper working temperature in order to quickly increase the temperature of the material, and the inside and outside of the material (S) heated in the heating chamber 120 It may include a crack chamber 130 to maintain the temperature by heating so as to maintain a uniform temperature.

In the present embodiment, the heating body 112, that is, the heating chamber 120 and the crack chamber 130 may be provided with a refractory material for heat resistance and heat insulation therein. As such a fireproof material, a firebrick or cerak wool may be mainly used.

In addition, the heating chamber 120 and the crack chamber 130 may be provided with heating means, for example, at least one heater (124, 134) for heating and maintaining the temperature on the upper and lower portions, respectively.

In addition, an open part is formed between the heating chamber 120 and the crack chamber 130 to open the material S.

In addition, the heating chamber 120 and the crack chamber 130 may be integrally provided by the frame 114. In addition, the frame 114 may be provided with a moving unit 140 for moving the heating chamber 120 and the crack chamber 130.

For example, the moving unit 140 may include a rail unit 142 provided on the moving line of the heating chamber 120 and the crack chamber 130. That is, in the present embodiment, the heating chamber 120 and the crack chamber 130 may be seated on the rail unit 142 via the frame 114.

For example, the frame 114 may further include a cloud member (not shown) for sliding movement when seated on the rail unit 142. The rolling member may be provided by a conventional roller, wheel, or the like.

In addition, the moving unit 140 may include an actuator 144 for moving the heating chamber 120 and the crack chamber 130 along the rail portion 142. Actuator 144 includes a cylinder 144a and a piston rod 144b that is stretched by the pressure of the fluid provided to the cylinder 144a, and the expansion and contraction of the piston rod 144b causes cracking with the heating chamber 120. The chamber 130 may be moved to the entry or withdrawal position of the material S.

In addition, in the present embodiment, the heating chamber 120 and the crack chamber 130 may be continuously provided with a material transport unit for moving the material.

For example, in the present embodiment, the material transport part may include a plurality of roller parts 126 and 136 which are continuously installed in the heating chamber 120 and the crack chamber 130. In addition, the material transport unit may include a driving motor (not shown) associated to drive the plurality of roller units 126 and 136.

To this end, the plurality of rollers 126 and 136 have one end of the rotating shaft extending outward of the heating chamber 120 or the crack chamber 130, and the extended rotating shafts are connected to the driving motor through a connecting member such as a gear. Can transmit torque.

Accordingly, the material S introduced into the heating chamber 120 or the crack chamber 130 is linked to the rotation of the roller parts 126 and 136 as the driving motor operates in a state in which it is seated on the roller parts 126 and 136. Can be moved.

That is, in the present embodiment, the raw material S may be moved into the crack chamber 130 by the rotation of the roller parts 126 and 136 after the rapid heating is performed by the heating chamber 120.

In addition, the rollers 126 and 136 may reciprocate before and after the heating and cracking process of the material S, thereby preventing the specific portions of the rollers 126 and 136 from being continuously exposed to heat. can do.

On the other hand, the material (S) may be drawn into or withdrawn from the heating chamber 120 or the crack chamber 130 by the material transport unit 150.

To this end, one side of the heating chamber 120 or the crack chamber 130 is provided with penetrating portions 128 and 138 that are open for the inlet or withdrawal of the material, and the penetrating portions 128 and 138 are provided on one side. Opening and closing may be performed by the door parts 129 and 139.

The door parts 129 and 139 may be connected to each other by the material transport unit 150 leading or pulling out the material S into the heating chamber 120 or the crack chamber 130 of the heating chamber 120 or the crack chamber 130. The through portions 128 and 138 can be opened or closed.

In this case, the door parts 129 and 139 may slide upward and downward, and may be provided to open and close the through parts 128 and 138. For example, the door parts 129 and 139 may move up and down in connection with an actuator (not shown) provided on one side of the heating chamber 120 or the crack chamber 130, and the door parts 129 and 139 may be moved. It is also possible to move up and down by a drive unit connected to one side of the gear, etc. via a medium.

In addition, the door parts 129 and 139 may be provided on one side of the heating chamber 120 or the crack chamber 130 through a rotation connecting member to be provided to open and close the through parts 128 and 138 by rotation. .

In addition, the heating chamber 120 and the crack chamber 130 is preferably maintained in an inert atmosphere to prevent the material from being oxidized during heating of the material (S). To this end, one side of the heating chamber 120 and the crack chamber 130 may be provided with a vacuum exhaust device 160 for exhausting the internal air and an inert gas supply unit (not shown) for supplying an inert gas therein. have. For example, in this embodiment, the inert gas may be representatively used as nitrogen (N ₂ ) gas or argon (Ar) gas.

In addition, the heating chamber 120 and the crack chamber 130 may be provided with temperature sensors 121 and 131 for measuring the internal temperature.

On the other hand, in the present embodiment, the heating body 112 may be provided with a blocking unit 170 for shielding the opening between the heating chamber 120 and the crack chamber 130, it is opened by the blocking unit 170 The additional shield may be partitioned into the heating chamber 120 and the crack chamber 130.

Here, the blocking unit 170 may include a partition member 172 provided between the heating chamber 120 and the crack chamber 130.

6 is a perspective view showing the separation of the partition member of the material heating furnace according to an embodiment of the present invention.

Referring to FIG. 6, the partition member 172 is connected to an actuator 174 provided at one side of the heating chamber 120 or the crack chamber 130, and the partition member 172 is connected to the operation of the actuator 174. The lift may open the opening between the heating chamber 120 and the crack chamber 130.

On the other hand, the partition member 172 may minimize the opening area in order to reduce the time required to open or close the opening.

To this end, the present embodiment may further include a lower partition member 176 that is fixedly positioned at the lower part of the roller between the heating chamber 120 and the crack chamber 130, and the partition member positioned on the upper part ( 172 may be referred to as the upper partition member 172.

In this case, the upper partition member 172 may be positioned above the lower partition member 176 and may be lifted up and down by the actuator 174.

In addition, the connecting portion of the upper partition member 172 and the lower partition member 176 is located below the moving line of the material S at a point adjacent to the moving line of the material S conveyed by the roller parts 126 and 136. Can be located.

In addition, the upper partition member 172 may further include a blocking plate 178 for sealing a gap with the lower partition member 176.

For example, in the present embodiment, the blocking plate 178 may be coupled to a lower portion of the upper partition member 172 by a fastening member such as a bolt 179 or welding or pressing.

In addition, the lower partition member 176 may be provided in an upper concave shape in contact with the upper partition member 172, more specifically, the blocking plate 178.

In addition, the blocking plate 178 may be formed in a shape corresponding to the upper surface of the lower partition member 176. Therefore, when the upper partition member 172 is in close contact with the lower partition member 176 and the opening is closed, the gap between the upper partition member 172 and the lower partition member 176 is sealed by the blocking plate 178 to move the heat. Can be blocked.

Although the upper surface of the lower partition member 176 is described as being concave downward in this embodiment, the present invention is not limited thereto and may be modified in various forms. For example, at least one uneven portion may be formed on an upper surface of the lower partition member 176, and a blocking plate may be provided with an uneven groove for accommodating the uneven portion.

In the present embodiment, the blocking unit 170 may withstand high temperatures so as to prevent the upper partition member 172 and the lower partition member 176 from being damaged by the heat of the heating chamber 120 and the crack chamber 130. It may be provided in a structure and material.

In addition, the blocking unit 170 may include cooling means for preventing the heat of the relatively high temperature heating chamber 120 is transferred to the crack chamber 130.

For example, in the present embodiment, the cooling means may include a cooling passage provided inside the upper partition member 172 and the lower partition member 176.

The cooling flow path may include pipes 173 and 177 which are bent and extended in a plurality inside the upper partition member or the lower partition member, respectively.

In this case, the pipes 173 and 177 respectively provided to the upper partition member 172 or the lower partition member 176 may have at least one water inlet 173a and 177a and water outlets 173b and 177b, respectively.

For example, in the present embodiment, the upper partition member 172 may be provided with an inlet 173a on one side of the upper portion, and the outlet 173b may be provided on the other side of the upper portion.

In addition, at least one inlet 177a or the outlet 177b of the lower partition member 176 may be connected laterally. In addition, the inlet 177a or the outlet 177b provided to the lower partition member 176 may be provided below the lower partition member 176 in consideration of a coupling relationship with other components.

Meanwhile, in the present embodiment, the pipes 173 and 177 provided to the upper partition member 172 or the lower partition member 176 are described as having a single flow path, but are not limited thereto and may be modified in various forms.

As an example, in this embodiment, the pipes 173 and 177 may be provided in plural numbers having respective inlets 173a and 177a and outlets 173b and 177b. In addition, the pipes 173 and 177 may be provided as one, and a plurality of inlets or outlets may be provided.

As such, in the present embodiment, the pipes 173 and 177 may improve the circulation rate of the cooling water to more rapidly cool or uniformly maintain the temperature of the upper partition members 172 and 176.

In addition, a cooling water circulation unit (not shown) for circulating the cooling water may be connected to the cooling passage.

In the present embodiment, the cooling water circulation unit is connected to the inlets 173a and 177a or the outlets 173b and 177b of the upper partition member 172 or the lower partition member 176 through a separate extension pipe to circulate the cooling water. Can be.

For example, the cooling water circulation unit may further include a circulation pump, and after the cooling water is introduced through the inlets 173a and 177a, the upper partition member 172 is sequentially circulated through the internal flow path and the outlets 173b and 177b. And the lower partition member 176 may be cooled.

In addition, the cooling water heated in the process of circulating the upper partition member 172 and the lower partition member 176 may be cooled through a heat exchanger, etc., and may be supplied to other subsequent processes, or used as wastewater, or the like. Can be processed.

Looking at the heating method using the material heating furnace of the present embodiment configured as described above are as follows.

First, the material heating method of the present embodiment is to heat the material (S) for hot-press forming molding, in order to obtain the optimal hot-press forming molding conditions, the material (S) than the working temperature for hot-press forming molding It may include a rapid heating step of rapid heating to a high temperature.

In the rapid heating step, the heating chamber 120 and the crack chamber 130 are positioned at the work start position to supply the material S.

For example, the rapid heating step may be heated to a temperature of about 0 to 30% higher than the working temperature of the material (S). At this time, when the heating is more than 30% above the working temperature of the material in the rapid heating step, deformation may occur in the material (S), so that a short time at a high temperature temperature during the rapid heating of the material (S) can be heated It is desirable to.

To this end, in the present embodiment, the heating chamber 120 is heated by applying power to the heater 124 to about 1,000 degrees higher than the working temperature of the material S, for example, about 20% higher.

In addition, the crack chamber 130 is heated by applying a power to the heater 134 to about 800 degrees, the working temperature of the material (S).

At this time, the heating chamber 120 and the crack chamber 130 is evacuated inside the vacuum to prevent the oxidation of the material (S), and maintains the interior in an inert gas atmosphere.

As such, when the work preparation of the material heating furnace is completed, the material S processed in a predetermined shape for hot press forming work is transferred to the roller part 126 of the heating chamber 120 using the material transfer unit 150. Settle down.

At this time, the heating chamber 120 opens the door 129 which is blocking the through part 128, and then introduces the raw material S into the heating chamber 120. At this time, the material transport unit continues the forward and backward reciprocating movement of the roller unit 126 by operating the drive motor to prevent thermal damage of the roller unit 126.

Then, the temperature of the material S injected into the heating chamber 120 is sensed using the temperature sensor 121, and heating is continued until the temperature of the material S reaches about 1,000 degrees. For example, in the present embodiment, the heating chamber 120 may take about 60 seconds until the temperature of the material S reaches about 1,000 degrees.

Next, when the material S initially heated in the heating step reaches a set temperature, that is, about 1,000 degrees, the crack heating step may be performed to heat the material S so that the internal temperature is uniformly maintained at the working temperature.

To this end, the present embodiment operates the actuator 174 of the blocking unit 170 to raise the partition member 172 to open the opening between the heating chamber 120 and the crack chamber 130.

In addition, the driving motor of the material transport unit rotates the roller units 126 and 136 to transfer the material S located in the heating chamber 120 to the crack chamber 130.

In addition, when the material S is transferred to the crack chamber 130, the actuator 174 of the blocking unit 170 is operated to lower the partition member 172 and then the material S by the temperature sensor 131. Measure the temperature of and keep the heating state for a certain time. At this time, if the material (S) is maintained in the crack chamber 130 for about 140 seconds, it is possible to obtain the optimum working conditions and physical properties (strength, hardness, etc.) for hot press forming.

For example, when the material S is maintained at about 800 degrees for 140 seconds in the crack chamber 130, the internal temperature of the material S may be uniformed at about 800 degrees.

Meanwhile, the actuator 144 of the mobile unit 140 moves the heating chamber 120 and the crack chamber 130 while the material S is maintained at the working temperature in the crack chamber 130. Accordingly, the crack chamber 130 is positioned to the material withdrawal position where the material transport unit 150 is located.

Then, when the rapid heating and crack heating operation of the material (S) in accordance with the conditions set in the crack chamber 130 is completed, open the door 139 of the crack chamber 130, the material transport unit 150 to the crack chamber ( 130) to enter the material (S) is withdrawn.

In this way, the material S drawn out by the material transport unit 150 is moved to a press for hot press forming and the work is performed.

In the material heating method of the present embodiment, the above-described process may be repeated to heat the material, and then press molding may be continuously performed.

Meanwhile, in the embodiment of the present invention, the material S is described as being moved by rotating the roller parts 126 and 136 when moving from the heating chamber 120 to the crack chamber 130, but the material S is heated in the heating chamber. The configuration of positioning the crack chamber 130 at 120 is not limited and may be variously modified.

For example, in the present embodiment, the material heating furnace 110 may have a seating portion similar to 16 shown in FIGS. 1 and 2 in the heating chamber 120 or the crack chamber 130, and Heating may occur after seating (S).

Here, the heating chamber 120 and the crack chamber 130 may be moved to the entry or withdrawal position of the material S by the actuator 144 of the moving unit 140. As such, as the heating chamber 120 and the crack chamber 130 move, relative movement with respect to the material S may be performed.

At this time, the material (S) may be in a state seated on the seating portion, the heating chamber 120 and the crack chamber 130 is moved into the heating chamber 120 as the movement, or enter the crack chamber 130 Temperature can be maintained.

In this way, the heating chamber 120 and the crack chamber 130 may not be provided with a separate material transport unit for the movement of the material, the transfer unit to prevent temperature deviations due to local heating of the material (S), etc. It is also possible for the actuator 144 of 140 to move the heating chamber 120 and the crack chamber 130 forward or backward at a predetermined interval or continuously.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. It will be clear to those who have knowledge.

110: material heating furnace 112: heating body
114: frame 120: heating chamber
121, 131: temperature sensor 124, 134: heater
126, 136: roller part 128, 138: through part
129, 139: door 130: crack chamber
140: mobile unit 142: rail portion
144: actuator 144a: cylinder
144b: piston rod 150: material transport unit
170: blocking unit 172: partition member
173, 177: pipe 174: actuator
176: lower partition member 178: blocking plate
179: Bolt

Claims (12)

A heating chamber for heating the material;
A crack chamber which maintains the temperature of the material heated in the heating chamber;
A material transport unit which is continuously provided to the heating chamber and the crack chamber to move the material; And
And a blocking unit provided to partition between the heating chamber and the crack chamber and opening between the heating chamber and the crack chamber in connection with the operation of the material transport unit.
The method according to claim 1,
The material transport unit and a plurality of rollers that are continuously installed in the heating chamber or the crack chamber,
And a drive motor that is linked to drive the plurality of rollers.
The method according to claim 1,
The material heating furnace further comprises a material transport unit which is provided to draw or withdraw the material into the heating chamber or the crack chamber.
The method according to claim 3,
And a moving unit for moving the heating chamber or the crack chamber to be located at an entry or withdrawal position of the material transportation unit.
The method of claim 4, wherein the mobile unit
A rail portion provided on the moving line of the heating chamber and the crack chamber;
And an actuator provided between the rail portion and the heating chamber or the crack chamber to move the heating chamber and the crack chamber by expansion and contraction.
The method according to claim 3,
And a door part provided in the heating chamber and the crack chamber, respectively, to open in connection with the material transport unit when the material is introduced or removed.
The method according to any one of claims 1 to 6, wherein the blocking unit
A partition member provided between the heating chamber and the crack chamber;
And a lifting and lowering actuator provided to raise and lower the partition member.
The method of claim 7,
The blocking unit is a material heating furnace, characterized in that it comprises a cooling means provided in the partition member.
The method of claim 8, wherein the cooling means
A cooling passage provided in the partition member;
And a cooling water circulation unit circulating the cooling water in association with the cooling passage.
Rapid heating step of initially heating the material to a temperature higher than the working temperature for hot-press forming molding; And
A crack heating step of heating the material initially heated in the heating step to a working temperature to equalize the internal temperature of the material to the working temperature;
Material heating method comprising a.
The method of claim 10,
The rapid heating step is a material heating method characterized in that for heating to a temperature of 0 to 30% higher than the working temperature of the material.
The method of claim 10,
The rapid heating step and the crack heating step is a material heating method characterized in that it is maintained in an inert atmosphere during the heating of the material.

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