KR102527374B1 - Hydrostatic pressure device - Google Patents

Abstract

The present invention relates to a hydrostatic pressure device, and more particularly, to a hydrostatic pressure device for compression molding an object to be processed located inside a receiving groove by using the pressure of a pressurized medium, wherein a heat exchanger for heating or cooling a pressurized medium is provided in the receiving groove. It relates to a hydrostatic pressure device capable of heating or cooling a pressurized medium as well as securing an accommodation space inside an accommodation groove by forming it outside.

Description

Hydrostatic pressure device {HYDROSTATIC PRESSURE DEVICE}

The present invention relates to a hydrostatic pressure device, and more particularly, to a hydrostatic pressure device for compressing an object to be processed with hydrostatic pressure.

The hydrostatic pressure device is a device that compresses and molds the object to be processed through the pressure of accommodating the object to be processed in the vessel and injecting a pressurized medium into the vessel.

As an example of a hydrostatic pressure device, the processing target is placed in the receiving groove of the inner vessel, sealed through the outer vessel surrounding it, and then a pressurized medium such as water is injected into the receiving groove to compress the processing target through its pressure. .

At this time, the hydrostatic pressure device includes a heat exchange unit that heats or cools the pressurized medium so that the compression molding operation is completed or the pressurized medium for compression molding of the object is maintained at a selected temperature to perform compression molding, and the heat exchange unit is pressurized. The heat exchanging means for cooling or heating the medium is located inside the receiving groove and is heated by electric energy to heat the pressurized medium or cool the pressurized medium through the flowing heat exchange medium.

The above-described conventional hydrostatic pressure device requires a certain space in the receiving groove because the heat exchange unit is located inside the receiving groove, which may interfere with compression molding through uniform pressure.

In addition, since the heat exchange unit is located inside the receiving groove, it is not provided with a large number of heat exchange means, and accordingly, it is difficult to evenly heat or cool the pressurized medium, which makes it difficult to evenly distribute the temperature in the receiving groove.

In addition, when the heat exchange unit is provided inside the accommodation groove, there is a high risk of damage to the heat exchange unit when the inside of the accommodation groove is compressed at a high pressure of 1000 atmospheres or more.

Republic of Korea Patent Registration No. 10-1638092 (2016.07.04.)

The present invention has been made to solve the above-described problems, and an object of the present invention is a hydrostatic pressure device for compression molding a processing target located inside an accommodation groove by using the pressure of a pressurized medium, heating or cooling the pressurized medium. By forming a heat exchanging unit outside the accommodating groove, it is possible to secure an accommodating space inside the accommodating groove and to provide a hydrostatic pressure device capable of uniformly heating or cooling a pressurized medium.

The hydrostatic pressure device according to the present invention is formed in a cylindrical shape to have a length selected by height, and an interior formed in a shape through which an accommodation groove 110 for receiving an object to be processed in the width direction is penetrated at a position selected in the length direction. Vessel (100); An insertion hole 210 that is slid and inserted in the longitudinal direction of the inner vessel 100 to seal or open the receiving groove 110, and the inner vessel at a position selected in the longitudinal direction of the insertion hole 210 An outer vessel 200 including a spare space 220 formed to be spaced apart from (100) by a predetermined distance; a pressurized medium supply unit 300 supplying a pressurized medium for pressurizing an object to be processed to the receiving groove 110 through operation of a pump; and a heat exchange means 400 including a heating means 410 capable of selectively heating the pressurized medium and having a selected length outside the receiving groove 110.

In addition, the heat exchanging means 400 is characterized in that arranged to be spaced apart from each other in a circumferential direction inside the inner vessel 100.

In addition, the heat exchanging means 400 is characterized in that arranged to be spaced apart from each other in a circumferential direction inside the outer vessel 200.

In addition, the heat exchanging means 400 is characterized in that it is disposed to be spaced apart from the extra space 220 in the circumferential direction.

In addition, the heat exchange means 400 further includes a cooling means 420 capable of selectively cooling the pressurized medium through heat exchange with a heat exchange medium flowing with a selected length, and the heating means 410 And it is characterized in that at least one selected from heating and cooling the pressurized medium through the cooling means 420.

In addition, the heat exchanging means 400 is characterized in that the heating means 410 and the cooling means 420 are alternately arranged with each other.

In addition, the cooling means 420 is formed of one flow path, and is formed in a zigzag shape in which ends in the longitudinal direction of the inner vessel 100 are alternately connected to avoid the heating means 410, and the heating means 420 is formed in a zigzag shape. The means 410 are characterized in that they are alternately disposed in the open area of the cooling means 420.

In addition, the receiving groove 110 includes a temperature measuring unit for measuring the temperature of the internal pressurized medium, and the temperature measuring unit includes a sensor T1 provided on one side of the receiving groove 110 in a longitudinal direction, and the receiving groove ( 110) It is characterized in that it includes the other sensor (T2) formed spaced apart from the other side in the longitudinal direction.

In addition, the pressurized medium supply unit 300 selectively supplies the pressurized medium to the pressure resistance pipe 301 connected to supply the pressurized medium to the cooling means 420, the receiving groove 110, and the cooling means 420. It includes a first switch 302 formed to supply, and the cooling means 420 includes a second switch 421 for controlling the flow of the heat exchange medium in response to the operation of the pressurized medium supply unit 300. characterized by

In addition, when the inside of the receiving groove 110 is pressurized, the hydrostatic pressure device pressurizes the receiving groove 110 and the cooling means 420 through the control of the first switch 302 and the second switch 421. When the pressurized medium accommodated in the receiving groove 110 is cooled, the pressurized medium flows through the receiving groove 110 and the receiving groove 110 through the control of the first switch 302 and the second switch 421. It is characterized in that the flow to the flow path of the cooling means 420 is prevented and the heat exchange medium is allowed to flow into the flow path of the cooling means 420.

In addition, the hydrostatic pressure device is characterized in that it further includes a sealing portion 500 formed of a material capable of sealing and sealing between the inner vessel 100 and the outer vessel 200.

The hydrostatic pressure device according to the present invention is a hydrostatic pressure device that compresses and molds a processing target located inside an accommodation groove using the pressure of a pressurized medium, by forming a heat exchange unit for heating and cooling a pressurized medium outside the accommodation groove. There is an effect of efficiently heating or cooling the pressurized medium while securing an internal accommodation space.

In addition, the hydrostatic pressure device according to the present invention can prevent the heat exchange unit and the inside of the receiving groove from interfering with each other, and thus has the advantage of being able to efficiently perform compression molding of the object to be processed.

1 and 2 are cross-sectional views of a hydrostatic pressure device according to an embodiment of the present invention.
3 is a cross-sectional view showing an example of forming a heat exchange unit of a hydrostatic pressure device according to an embodiment of the present invention.
4 is another cross-sectional view showing an example of forming a heat exchange unit of a hydrostatic pressure device according to an embodiment of the present invention;
5 is another cross-sectional view showing an example of forming a heat exchange unit of a hydrostatic pressure device according to an embodiment of the present invention.
6 and 7 are other cross-sectional views of a hydrostatic pressure device according to an embodiment of the present invention.
8 is a view showing an embodiment of a heat exchange means of a hydrostatic pressure device according to an embodiment of the present invention.
9 is another view showing a hydrostatic pressure device according to an embodiment of the present invention

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

1 is a cross-sectional view of a hydrostatic pressure device according to an embodiment of the present invention, and FIG. 2 is another view showing a hydrostatic pressure device according to an embodiment of the present invention in a cross-sectional view.

1 and 2, the hydrostatic pressure device 1000 according to an embodiment of the present invention includes an inner vessel 100 including an accommodation groove 110 in which a processing target is accommodated, and an accommodation groove of the inner vessel 100 The external vessel 200 capable of sealing the 110, the pressurized medium supply means 300 for supplying the pressurized medium to the receiving groove 110 to pressurize the processing target accommodated in the receiving groove 110, and the pressurized medium selectively It comprises a heat exchanging means 400 including a heating means 410 for heating. At this time, the pressurized medium is preferably water, but is not limited thereto.

The inner vessel 100 is typically disposed inside the outer vessel 200, and the outer vessel seals both ends of the outer vessel to prevent leakage of the pressurized medium to the outside. The inner vessel is typically formed in a cylindrical or columnar shape, but the receiving groove 110 of the inner vessel has a certain area and is formed by penetrating the inner vessel in the radial direction, so the pressure medium supplied to the inner vessel 100 is After being supplied to the receiving groove of, it comes into contact with the inside of the outer vessel 200, and the pressure transmitted by the pressurized medium is transmitted both to the inside of the outer vessel and to the inside and outside of the inner vessel.

As described above, the inner vessel is usually manufactured in a cylindrical or cylindrical shape with a certain height so that the pressure of the incoming pressurized medium is uniformly distributed, but depending on the pressure and characteristics of the applied pressurized medium, the inner vessel 100 Since it can be formed into pillars of various shapes, it is not limited thereto.

On the other hand, the receiving groove 110 is formed in the central portion of the inner vessel 100, in which the processing target is accommodated. The receiving groove is manufactured in a shape through which a certain area is penetrated in the radial direction or the width direction (direction orthogonal to the height direction). Through this, the processing target can be drawn in and out of the receiving groove 110 in the width direction of the inner vessel 100 .

The area where the receiving groove 110 of the inner vessel 100 is formed is located inside the outer vessel 200, and the inner vessel 100 and the outer vessel 200 have upper and lower ends relative to the receiving groove 110. Since it is sealed by the sealing member, it is possible to seal the receiving groove 110 with the outside.

The outer vessel 200 is formed through an insertion hole 210 so that the inner vessel 100 can slide in the height direction or the axial direction of the inner vessel 100, and the inner vessel 100 is formed through the outer vessel 200. It is moved in parallel to the insertion hole 210 to perform sealing or opening for pressurization of the processing target.

At this time, the outer vessel 200 is arranged vertically so that the height direction is formed in the vertical direction, and the inner vessel 100 is vertically moved to the outer vessel 200 having a length in the vertical direction to seal or open the receiving groove 110. In addition to being able to perform, in another embodiment, the outer vessel 200 is formed horizontally and the height direction is horizontal, and the inner vessel 100 moves horizontally to the outer vessel 200 having a length in the horizontal direction. It is possible to perform the sealing or opening of the receiving groove (110).

Of course, unlike the above-described configuration and operation, an embodiment in which the inner vessel 100 is fixed and the outer vessel 200 is moved to seal or open the receiving groove 110 of the inner vessel 100 is also possible.

In addition, in the outer vessel 200, a spare space 220 having a larger area than the outer shape of the inner vessel 100 may be formed in a selected area of the insertion hole 210 facing the inner vessel 100. . The free space 220 becomes a space in which the pressurized medium flows when the receiving groove 110 is closed or opened according to the movement of the inner vessel 100, and when a high pressure is applied to the receiving groove, the pressurized medium moves through the receiving groove 110 ) It also serves as a passageway to move to the outside.

The pressurized medium supply unit 300 is formed in the inner vessel 100 to supply a pressurized medium from the outside to the inside of the receiving groove 110, and is formed at a selected part of both ends of the inner vessel 100 in the height direction. and supply a pressurized medium.

The pressurized medium supply unit 300 may supply pressurized medium from a pressurized medium storage unit storing a separate pressurized medium to the receiving groove 110 using a pump, and in a state directly connected to the water supply facility, using a pump to supply the pressurized medium to the receiving groove ( 110) A pressurized medium may be supplied to the inside.

The heat exchanging means 400 includes a heating means 410 capable of selectively heating the pressurized medium filled in the receiving groove 110 . At this time, the heat exchanging means 410 may be located outside the receiving groove 110 and perform a heating operation on the pressurized medium filled in the receiving groove 110 .

The heating means 410 may be a heater made of a coil heated by electric energy. Of course, the heating means 411 may be formed of various means as long as it can heat the pressurized medium of the receiving groove 110 other than the above-described heater.

In addition, the hydrostatic pressure device 1000 according to an embodiment of the present invention further includes a sealing part 500 . The sealing part 500 is formed of a material capable of sealing and is formed at both ends of the insertion hole 210 of the outer vessel 200, and a spare space in which the pressurized medium is accommodated between the sealing parts 500 disposed at both ends ( 220) is formed, and since the pressurized medium cannot move in the sealing part 500, it prevents the pressurized medium from leaking out between the inner vessel 100 and the outer vessel 200.

The sealing unit 500 may be installed in the seating grooves formed at both ends of the inner vessel 100 to perform sealing, and prevent the leakage of the pressurized medium between the inner vessel 100 and the outer vessel 200. Of course, various materials and positions are possible without limitation if possible.

The hydrostatic pressure device 1000 according to an embodiment of the present invention having the above-described configuration moves the inner vessel 100 out of the outer vessel 200 in order to introduce a processing target into the receiving groove 110. Then, after introducing the processing target into the receiving groove 110, the inner vessel 100 is moved so that the outer vessel 200 seals the receiving groove 110.

The pressurized medium is introduced into the receiving groove 110 through the pressurized medium supply unit 300 in the closed receiving groove 110, and the processing target is compression-molded through the pressurized medium flowing into the receiving groove 110.

In addition, during compression molding of the object to be processed, the pressurized medium may be heated to a selected temperature. At this time, the heat exchanging means 400 is formed to be located outside the receiving groove 110, not inside the receiving groove 110, so that it is not interfered with the compression molding of the processing target by pressing, and the receiving groove 110 ) can transfer heat to the pressurized medium inside.

Various embodiments of the aforementioned heat exchanger 400 will be described.

3 is a cross-sectional view showing an example of forming a heat exchange unit of a hydrostatic pressure device according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view showing an example of forming a heat exchange unit of a hydrostatic pressure device according to another embodiment of the present invention. 5 is another cross-sectional view illustrating an example of forming a heat exchange unit of a hydrostatic pressure device according to another embodiment of the present invention.

Referring to FIG. 3 , the heat exchanging means 400 may be formed inside the inner vessel 100 . That is, the heat exchanging means 400 has at least one heating means 410 formed inside the inner vessel 100 outside the receiving groove 110, so that the pressurized medium accommodated inside the receiving groove 110 can be selectively heated. .

At this time, it is preferable that the heat exchanging means 400 be arranged spaced apart from each other in the circumferential direction of the inner vessel 100 to evenly transfer the temperature to the inside of the receiving groove 110 .

In addition, since the heat exchanging means 400 needs to heat the pressurized medium accommodated inside the accommodating groove 110, it is preferable to arrange it adjacent to the accommodating groove 110 based on the center of the inner vessel 100.

As described above, the heat exchanging means 400 is formed inside the inner vessel 100, which is outside the receiving groove 100, so that the pressurized medium can be heated without making direct contact with the pressurized medium.

In addition, since the heat exchanging means 400 is located outside the accommodating groove 110 and does not require space inside the accommodating groove 110, accurate pressurization can be achieved when pressurizing the object to be processed through the pressurized medium. . In addition, since the heat exchanging means 400 is not located inside the receiving groove 110, it is possible to prevent interference when a processing target is drawn into or removed from the receiving groove 110.

Referring to FIG. 4 , the heat exchanging means 400 may be formed inside the outer vessel 200 . That is, at least one heating means 410 is formed inside the outer vessel 200, which is outside the receiving groove 110, so that the pressurized medium can be heated without making direct contact with the pressurized medium.

At this time, the heat exchanging means 400 is preferably formed in the longitudinal direction of the outer vessel 200 at a predetermined distance in the circumferential direction of the outer vessel 200 for uniform temperature transfer to the inside of the receiving groove 110.

In addition, since the heat exchanging means 400 needs to heat the pressurized medium accommodated inside the accommodating groove 110, it is preferable to arrange it adjacent to the accommodating groove 110 based on the center of the outer vessel 200.

In addition, since the heat exchanging means 400 is located outside the accommodating groove 110, it does not require space inside the accommodating groove 110. Through this, when pressurizing the processing target through the pressurized medium, accurate pressurization can be achieved, and since the heat exchange means 400 is not located inside the receiving groove 110, the processing target is drawn into the receiving groove 110. And it can prevent interference during withdrawal.

Referring to FIG. 5 , the heat exchanging means 400 may be formed in a spare space 220 facing the inner vessel 100 among the outer vessels 200 . That is, at least one heat exchanging means 400 is formed in the spare space 220, so that the pressurized medium can be heated without direct contact with the pressurized medium.

At this time, the heat exchanging means 400 is preferably formed in the longitudinal direction of the outer vessel 200 at a predetermined distance in the circumferential direction of the outer vessel 200 for uniform temperature transfer to the inside of the receiving groove 110.

In addition, since the heat exchanging means 400 is located outside the accommodating groove 110, it does not require space inside the accommodating groove 110. Through this, when pressurizing the processing target through the pressurized medium, accurate pressurization can be achieved, and since the heat exchange means 400 is not located inside the accommodation groove 110, when the processing target is drawn into or withdrawn from the accommodation groove 110 interference can be avoided.

In particular, the heat exchange means 400 is not formed inside the inner vessel 100 or the outer vessel 200 but is formed in the spare space 220, so that the heat exchange means inside the inner vessel 100 or the outer vessel 200 ( 400) can be deleted, and in particular, since it is not located inside the inner vessel 100 or the outer vessel 200 and is formed in the free space 220, the inner vessel 100 or the outer vessel 200 ) can prevent a decrease in strength.

6 and 7 are other cross-sectional views of a hydrostatic pressure device according to an embodiment of the present invention, and FIG. 8 is a view showing an embodiment of a heat exchanging means of the hydrostatic pressure device according to an embodiment of the present invention.

6 and 7, the heat exchanging means 400 further comprises a cooling means 420 capable of selectively cooling the pressurized medium through heat exchange with the flowing heat exchanging medium having a selected length. can

At this time, since the heat exchange means 400 can selectively operate the heating means 410 and the cooling means 420, any one selected from heating and cooling the pressurized medium through the heating means 410 and the cooling means 420 can do more. That is, the pressurized medium can be heated or cooled, and both the heating operation and the cooling operation can be performed. Through this, it is easy to control the selected temperature of the pressurized medium.

Referring to (a) of FIG. 8, since the heat exchanging means 400 needs to perform simultaneous operations of heating, cooling, and heating and cooling the pressurized medium using the heating means 410 and the cooling means 420, the heating means It is preferable that the 410 and the cooling means 420 are alternately formed at regular intervals in the circumferential direction of the inner vessel 100, and as described above, for the efficiency of temperature transfer, a certain length in the longitudinal direction of the inner vessel 100 It can be formed to have.

Through this, when the pressurized medium accommodated in the receiving groove 110 is heated, cooled, or simultaneously performing heating and cooling operations, heat energy can be evenly transferred to the pressurized medium inside the receiving groove 110 .

Referring to (b) of FIG. 8 , in the cooling means 420, a flow path through which a heat exchange medium flows may be formed as one flow path. That is, when the cooling means 420 is arranged in a zigzag pattern, a plurality of passages through which the heat exchanging medium flows must also be provided, which not only increases the manufacturing process due to a complicated configuration, but also makes maintenance inconvenient. Therefore, it is preferable that the flow path of the cooling means 420 through which the heat exchange medium flows is made of one flow path so that the heat exchange medium flows.

At this time, since the heating means 410 and the cooling means 420 are formed alternately in the circumferential direction, the inner vessel 100 avoids the heating means 410 in forming one flow path of the cooling means 420. ) is preferably formed in a zigzag shape in which ends in the longitudinal direction are alternately connected.

That is, the cooling means 420 is formed in a shape that is alternately connected in the height direction, so that the heating means 410 can be avoided, and the heating means 410 made of a coil is open to the cooling means 420 on both sides in the height direction. It can be arranged alternately in the area.

In addition, the receiving groove 110 may include a temperature measuring unit for measuring the temperature of the pressurized medium inside, and by measuring the temperature of the pressurized medium using the temperature measuring unit, the heating and cooling operations of the pressurized medium are more precisely performed. can do.

Since the cooling means 420 is formed in a zigzag shape and the heating means 410 is disposed in the open area of the cooling means 420, the height direction positions of the heating means 410 are different.

Inside the receiving groove 110, a temperature difference may occur depending on the location of the receiving groove, such as an upper part and a lower part.

If a large temperature difference is generated inside the receiving groove 110, the quality of products processed by the hydrostatic pressure equipment may deteriorate.

Therefore, in order to check the occurrence of a temperature difference between the pressurized medium inside the receiving groove 110, the temperature measuring unit is formed on one side of the receiving groove 110 in the longitudinal direction (when the length is formed in the height direction, the upper part) is formed on one side sensor T1 and the other sensor T2 formed on the other side in the longitudinal direction of the receiving groove 110 (the lower part when the length is formed in the height direction), and the temperature between one sensor T1 and the other sensor T2 It is possible to confirm the occurrence of a temperature difference between the pressurized medium inside the receiving groove 110 through measurement and comparison therebetween.

When the temperature difference between the one side sensor T1 and the other side sensor T2 is out of the normal range, the one side heating means 410 and The other heating means 410 can be individually controlled.

For example, if one sensor T1 is installed on the top and the other sensor T2 is installed on the bottom, the temperature of the pressurized medium is maintained at 80 to 70 degrees, and the temperature difference is controlled so that it does not exceed 5 degrees. ,

When one side sensor (T1) is 75 degrees and the other side sensor (T2) is 70 degrees, the heating means (410) installed on the upper part is cut off from supplying power, and only the heating means (410) installed on the lower part is controlled so that power is supplied. can

To this end, a switch may be installed in the heating means 410 to enable separate control according to the installed position.

9 is another view showing a hydrostatic pressure device according to an embodiment of the present invention.

Referring to FIG. 9, as described above, the cooling means 420 is formed as a pipe-shaped passage through which heat exchanged heat exchange medium flows to cool the pressurized medium, and the receiving groove 110 of the inner vessel 100 The pressurized medium supplied to may have a pressure of 1000 bar or more, and accordingly, the flow path of the cooling means 420 may be damaged and the heat exchange medium may leak or be damaged, thereby hindering the flow of the heat exchange medium within the flow path.

Accordingly, the pressurized medium supply unit 300 is formed to selectively supply the pressurized medium to the pressure resistance pipe 301 connected to supply the pressurized medium to the cooling means 420, the receiving groove 110, and the cooling means 420. It is made including a first switch 302 to be. The corresponding cooling means 420 includes a second switch 421 that controls flow of the heat exchanging medium in response to the operation of the pressurized medium supply unit 300 .

The first switch 302 and the second switch 421 may be composed of valves capable of opening and closing pipes.

That is, when the hydrostatic pressure device 1000 according to an embodiment of the present invention supplies and pressurizes a pressurized medium for compression molding of an object to be processed, not only the receiving groove 110 but also the flow path of the cooling means 420 supplies the pressurized medium. By supplying it, it is possible to prevent the flow path of the cooling means 420 from being damaged even if the pressure in the receiving groove 110 increases as the pressure inside the flow path increases.

In other words, the pipe can be protected by preventing a large pressure difference from occurring between the receiving groove 110 and the passage of the cooling means 420 .

Referring to FIG. 9 as an example, when the inside of the receiving groove 110 is pressurized, the first switch 302 is opened and the second switch 421 is closed, so that the inside of the passage of the cooling means 420 becomes the receiving groove 110. It can be pressurized like so.

Conversely, when pressurization is stopped and the pressurized medium is cooled, the pressurized medium is supplied from the pressurized medium supply unit 300 through the control of the first switch 302 and the second switch 421 through the receiving groove 110 and the cooling means 420. It is possible to prevent flow of the heat exchange medium into the flow path of the cooling unit 420 and allow only the heat exchange medium to flow into the flow path of the cooling unit 420 according to the operation of the pump for flowing the heat exchange medium into the cooling unit 420 .

Referring to FIG. 9 as an example, when the pressurized medium accommodated in the accommodation groove 110 is cooled, the first switch 302 is closed and the second switch 421 is opened to exchange heat into the passage of the cooling means 420. The medium (refrigerant) can be circulated.

Although pumps, valves (switches), etc. are not shown in detail in drawings such as FIG. 9, it goes without saying that means for controlling the flow of fluid such as pumps or valves can be installed and used in various ways as needed.

6 to 9 have been described as an example in which the heating and cooling means are disposed inside the inner vessel, but the configuration of FIGS. 6 to 9 is the same even if the heating and cooling means are disposed inside the outer vessel or in a spare space. can be applied

The present invention is not limited to the above-described embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the art to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

1000: hydrostatic pressure device
100: inner vessel
110: receiving groove
200: external vessel
210: insertion hole
220: free space
300: pressurized medium supply unit
400: heat exchange means
410: heating means
420: cooling means
500: sealing part

Claims (10)

An inner vessel 100 formed in a cylindrical shape to have a length selected in the height direction and formed in a shape through which a receiving groove 110 for receiving an object to be processed in a radial direction is penetrated at a position selected in the height direction;
An insertion hole 210 that is slid and inserted in the height direction of the inner vessel 100 to seal or open the receiving groove 110, and the inner vessel at a position selected in the height direction of the insertion hole 210 An outer vessel 200 including a spare space 220 formed to be spaced apart from (100) by a predetermined distance;
a pressurized medium supply unit 300 supplying a pressurized medium for pressurizing an object to be processed into the receiving groove 110 through operation of a pump; and
The pressurized medium can be selectively heated, and the pressurized medium is heated through heat exchange with the heating means 410 formed outside the receiving groove 110 and having a selected length and a heat exchange medium flowing with a selected length. It includes a cooling means 420 capable of selectively cooling the medium, and heat exchange means for performing at least one selected from among heating and cooling the pressurized medium through the heating means 410 and the cooling means 420 ( 400); including,
The pressurized medium supply unit 300
A pressure resistance pipe 301 connected to supply pressurized medium to the cooling means 420, and a first switch 302 formed to selectively supply pressurized medium to the receiving groove 110 and the cooling means 420 including,
The cooling means 420 is
A hydrostatic pressure device including a second switch 421 for controlling the flow of the heat exchange medium in response to the operation of the pressurized medium supply unit 300.
According to claim 1,
The heat exchange means 400 is
A hydrostatic pressure device disposed so as to be spaced apart from each other in the circumferential direction inside the inner vessel 100.
According to claim 1,
The heat exchange means 400 is
A hydrostatic pressure device disposed so as to be spaced apart from each other in a circumferential direction inside the outer vessel 200.
According to claim 1,
The heat exchange means 400 is
Disposed to be spaced apart from the free space 220 in the circumferential direction, the hydrostatic pressure device.
delete According to claim 1,
The heat exchange means 400 is
The hydrostatic pressure device in which the heating means 410 and the cooling means 420 are arranged alternately with each other.
According to claim 1,
The cooling means 420 is
It is formed from one flow path,
It is formed in a zigzag shape in which ends in the height direction of the inner vessel 100 are alternately connected to avoid the heating means 410,
The hydrostatic pressure device wherein the heating means 410 are alternately disposed in the open area of the cooling means 420.
According to claim 7,
The receiving groove 110 is
Includes a temperature measuring unit for measuring the temperature of the internal pressurized medium,
The temperature measuring unit
A hydrostatic pressure device comprising: one side sensor (T1) provided on one side of the receiving groove (110) in the height direction and the other side sensor (T2) formed spaced apart from the other side of the receiving groove (110) in the longitudinal direction.
delete According to claim 1,
The hydrostatic pressure device
When the inside of the receiving groove 110 is pressurized, the pressurized medium flows through the receiving groove 110 and the flow path of the cooling means 420 through the control of the first switch 302 and the second switch 421, ,
When the pressurized medium accommodated in the accommodating groove 110 is cooled, the pressurized medium flows through the accommodating groove 110 and the passage of the cooling means 420 through the control of the first switch 302 and the second switch 421. A hydrostatic pressure device that prevents flow to and allows the heat exchange medium to flow into the flow path of the cooling means (420).

Images