KR20150117829A - A isostatic press be able to heating and colding, and a manufacturing method of Chip Component using the same - Google Patents

Abstract

The present invention relates to an isostatic pressing device performing a compression molding by a fluid and a gas which are filled in a pressure vessel. The isostatic pressing device according to an embodiment of the present invention corresponds to an isostatic press device comprising a pressure vessel, which has a receiving groove for receiving a workpiece to be processed and a pressurizing medium filled in the receiving groove to apply an isostatic pressure to the workpiece, wherein the isostatic pressing device comprises a heat exchanger having a heat-exchanging member disposed in the receiving groove to exchange heat with the pressurizing medium so as to heat or cool the pressurizing medium. Therefore, the isostatic pressing device can heat and cool the workpiece in a short time, and obtain a workpiece having a dense texture, thereby minimizing the defect rate of the workpiece.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an isostatic press apparatus capable of heating and cooling, and a method of manufacturing a chip component using the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an isostatic pressing apparatus for performing isostatic pressing by a pressurizing medium filled in a pressure vessel, and a method of manufacturing a chip component using the same.

Generally, an isostatic pressing apparatus is a device for performing compression molding by pressure of a gas or a fluid by injecting a gas or a fluid into a pressure vessel in a state where a workpiece is placed inside a pressure vessel, and recently, It is widely used.

A conventional isostatic pressing apparatus is disclosed in Korean Patent Laid-Open No. 10-2007-0112718 as an " isostatic pressing apparatus ".

As shown in Fig. 1, the isostatic pressing device of the conventional isometric pressure applying device includes an adiabatic device 3 forming a process chamber R for receiving a workpiece W, a pressure (pressure) A heating device 25 for heating the pressure vessel 2 and a pressure medium supply device 5 for supplying a pressure medium to the inside of the pressure vessel 2, A pressure medium introducing space S capable of introducing a pressure medium is provided between the pressure vessel 2 and the pressure vessel 2 and the processing chamber R is communicated with the pressure medium introducing space 3 through the communication hole formed in the upper portion of the heat insulating body 3. [ S and is connected to the pressure medium introduction space S via a pressure medium introduction port 18 formed in the lower portion of the pressure vessel.

The iso-pressure pressurizing device having such a configuration can be compression-molded while heating the workpiece W by heating the pressure vessel 2 with the heating device 25 and heating the pressure medium.

However, since the pressure vessel 2 needs to be heated in order to heat the workpiece W in the conventional iso-pressure pressurizing device, it takes a long time to heat the workpiece W, which causes waste of heat loss However, there is a difficulty in heating the workpiece to a uniform temperature.

In addition, there has been a problem that the packing installed in the lid for sealing the pressure vessel 2 due to the heating of the pressure vessel 2 is damaged due to high temperature and high pressure.

In addition, since the conventional iso-pressure pressurizing device can only heat the pressure medium and can not perform the function of cooling, the workpiece W can not be processed so as to have a dense structure through firing and curing.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method and apparatus for heating and cooling a workpiece in a short time through a pressurizing medium for pressurizing a workpiece, And an object of the present invention is to provide an isostatic pressing apparatus capable of heating or cooling a workpiece at a uniform temperature.

Further, it is possible to perform compression molding of the workpiece so as to have a dense structure by performing cooling with heating, minimizing the defective rate of the workpiece, preventing breakage of the packing, and improving the pressure loss and airtightness. And to provide the above-mentioned objects.

It is another object of the present invention to provide a method of manufacturing a chip component capable of compressing and molding a chip component in a short period of time through heating and cooling of a pressurizing medium and producing a chip component having a compact structure and a low defect rate.

According to an aspect of the present invention, there is provided an isometric press apparatus capable of heating and cooling. The apparatus includes a receiving groove in which a workpiece is received, a pressurizing medium is filled in the receiving groove, And a heat exchanger including a heat exchanging member installed in the receiving groove and performing heat exchange with the pressurizing medium to heat or cool the pressurizing medium supplied to the receiving groove, characterized by comprising a heat exchanger .

The heat exchange member may be heated or cooled by a heat medium supplied to the heat exchange member.

The heat exchanger may include a heating unit for heating the heating medium, and a cooling unit for cooling the heating medium.

The heat exchanger may include a heating unit and a selective supplying unit that selectively supplies heat medium to be heated or cooled by the cooling unit to the heat exchanging unit.

The heat exchanger may include a heating medium storage tank for storing the heating medium.

The heat exchanging member may include an inlet through which the heating medium for cooling or heating the heat exchanging member flows, an outlet through which the heating medium introduced into the inlet is discharged, and a microchannel connecting the inlet and the outlet so as to circulate the heat exchanging member in a staggered manner .

The heating medium may include water.

The heat exchange member may include a heater that is heated by electricity.

The heat exchange member may include a cooling unit that is cooled by the refrigerant.

Wherein the heat exchange member is formed in any one of a plate shape, a cylindrical shape, and a spiral shape.

The heat exchange member may include a plurality of through holes passing through the heat exchange member or a plurality of protrusions protruding from the outer surface of the heat exchange member so that a contact area with the pressurizing medium is widened.

And a heat insulating material provided on the inner surface of the receiving groove to prevent the heat of the heat exchanging member from being transmitted to the outside of the receiving groove.

Wherein the heat insulating material comprises any one of a resin and a ceramic.

The pressure vessel may further include an upper cap and a lower cap for sealing the upper and lower portions of the pressure vessel, respectively, and a heater installed on one or both of the upper cap and the lower cap to heat the pressure medium can do.

The pressure vessel may further include an upper cap and a lower cap for sealing the upper and lower portions of the pressure vessel, respectively, and a shelf coupled to one of the upper and lower caps to seat the work.

A method of manufacturing a chip component using an isostatic pressing apparatus according to an embodiment of the present invention includes a pressure vessel in which a receiving groove for receiving a chip component is formed and a pressurizing medium is filled in the receiving groove to pressurize the chip component with iso-pressure, And a heat exchanger disposed in the receiving groove and performing heat exchange with the pressurizing medium to heat or cool the pressurizing medium supplied to the receiving groove, the method comprising the steps of: A step of supplying the pressurizing medium to the receiving groove to perform isostatic pressure compression molding of the chip component, a step of pressing the pressurizing medium to pressurize the chip component so as to heat the chip component while maintaining the pressure by the pressurizing medium, Heating the heat exchange member to heat-exchange with the medium, supplying the pressurizing medium supplied to the receiving groove The method comprising, and a step for carrying the said chip components accommodated in the receiving groove.

And cooling the heat exchanging member to heat-exchange with the pressurizing medium so that the chip component is cooled while the pressure is maintained by the pressurizing medium, before or after the step of heating the heat exchanging member that performs heat exchange with the pressurizing medium can do.

The isostatic pressing apparatus capable of heating and cooling according to the present invention can directly heat or cool the workpiece through the pressurizing medium to heat or cool the workpiece in a short period of time to minimize compression molding time and heat loss.

Further, since the fired workpiece can be immediately hardened in a state where the pressure is maintained, a workpiece having a dense structure can be obtained and the defect rate can be minimized.

In addition, a heat insulating material is provided inside the pressure vessel to prevent the heat from being transferred to the pressure vessel, thereby preventing damage to the packing, thereby improving pressure loss and airtightness.

Further, since the workpiece is cooled or heated by the pressurizing medium, the workpiece can be heated or cooled to a uniform temperature.

The method of manufacturing a chip component using an isostatic pressing apparatus according to the present invention can directly produce a chip component having a compact structure by heating or cooling the chip component within a short time by directly heating and cooling the chip component with a pressurizing medium And the defect rate of the chip component can be minimized.

In addition, since the firing or hardening step can be omitted for manufacturing the chip component, the facility cost and the manufacturing time can be greatly reduced.

1 is a side sectional view showing a conventional iso-pressure applying apparatus.
2 is a schematic view showing an iso-pressure press apparatus according to an embodiment of the present invention.
3 is a schematic view showing an iso-pressure press apparatus according to an embodiment of the present invention, showing a state in which a receiving groove is opened.
4 is a schematic view showing a heat exchanger constituting the isostatic pressing apparatus according to the embodiment of the present invention.
5 is a perspective view showing a heat exchange member constituting a heat exchanger of an isostatic pressing apparatus according to an embodiment of the present invention.
Fig. 6 is a sectional view of Fig. 5. Fig.
7 is a perspective view showing a heat exchange member formed in a cylindrical shape as a modification of the heat exchange member constituting the heat exchanger of the isopressure press apparatus according to the embodiment of the present invention.
8 is a perspective view showing a heat exchange member formed in a spiral shape as another modification example of the heat exchange member constituting the heat exchanger of the isostatic pressing apparatus according to the embodiment of the present invention.
9 is a flowchart schematically showing a method of manufacturing a chip component using an isostatic pressing apparatus according to an embodiment of the present invention.

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

First, the isostatic pressing apparatus 100 of the present invention includes a chip part made of ceramics such as a workpiece such as a chip capacitor, a chip varistor, a chip resistor, a chip inductor, a chip antenna, a chip EMI filter, It can be used in various fields of compression molding of the powder material as well as in the compression molding process to be performed.

As shown in FIGS. 2 and 3, the isostatic pressing apparatus 100 according to an embodiment of the present invention may include a pressure vessel 110. The pressure vessel 110 is formed into a hollow cylindrical shape to accommodate a workpiece to be formed into an isobaric pressure.

The upper and lower openings of the pressure vessel 110 may be filled with a pressurizing medium to pressurize the workpiece with an isostatic pressure. The cap 115 may be coupled to seal the pressure vessel 110.

Here, the pressure at which the pressurizing medium is filled in the receiving grooves 111 is several tens of bar to several thousands of bar, and isotropic pressure compression molding is performed by the pressure of the pressurizing medium.

The upper cap 113 and the lower cap 115 of the pressure vessel 110 are coupled to each other by an upper cap 113 for sealing the upper portion of the pressure vessel 110, The lower cap 115 may be threaded around the pressure vessel 110 to be tightly coupled to the pressure vessel 110. The lower cap 115 may be coupled to the pressure vessel 110 by bolts, The structure to be joined, the structure in which the cap 113 and the lower cap 115 are fitted to the frame such that the cap 113 and the lower cap 115 are not separated from the pressure vessel 110, and the like.

Here, the structure in which the upper cap 113 and the lower cap 115 of the pressure vessel 110 are coupled to each other may be any of various known methods.

One of the upper cap 113 and the lower cap 115 may be provided with a medium supply port for supplying a pressure medium to the receiving groove 111 of the pressure vessel 110, Or both the media supply port and the medium discharge port may be formed in any one of the upper cap 113 and the lower cap 115. In addition,

In addition, the shelf 114 on which the receiving object is placed may be installed in any one of the upper cap 113 and the lower cap 115. The shelf 114 is connected to the upper cap 113 or the lower cap 115 which opens the pressure vessel so that when the upper cap 113 or the lower cap 115 is opened, And may be configured to be exposed to the outside.

The isostatic pressing apparatus 100 according to the embodiment of the present invention may include a pressurizing medium supply mechanism 130. [

The pressurizing medium supply mechanism 130 can supply the pressurizing medium for pressurizing the workpiece to the receiving groove 111 of the pressure vessel 110.

The pressurizing medium supply mechanism 130 may supply the pressurized medium stored in the pressurized medium storage tank 131 to the receiving recess 111 through the medium supply port formed in the upper cap 113 or the lower cap 115, The pressurizing medium supply mechanism 130 may include a pressurizing pump 133.

The pressurizing pump 133 can pressurize the pressurizing medium to a high pressure and supply it to the receiving groove 111. [

Here, the pressurizing medium may be a fluid, such as water or oil, or a gas, but it is preferably the most commonly used fluid, and includes other components than water in order to rapidly heat, cool, or increase the pressing force .

The pressurizing medium supply mechanism 130 may include a pressurizing pump 133 and a medium supply line 135.

The pressurizing pump 133 can increase the pressure of the pressurizing medium and supply the medium to the receiving groove 111 by increasing the pressure of the fluid at the pressurizing pump 133. [

Although the medium supply line 135 is provided in the lower cap 115 so that the pressurizing medium is supplied to the receiving groove 111 in a state in which the lower cap 115 hermetically closes the receiving groove 111, The line 135 may be connected to the pressure vessel 110 or the upper cap 113 to supply the pressurized medium to the receiving groove 111.

A check valve may be provided in the medium supply line 135, and this check valve may supply the pressurizing medium to the receiving groove 111 or cut off the supply of the pressurizing medium.

The isostatic pressing apparatus 100 according to the embodiment of the present invention may include a driving mechanism (not shown).

The driving mechanism moves the upper cap 113 or the lower cap 115 to the upper or lower portion of the pressure vessel 110 in order to carry the workpiece into the pressure vessel 110 or to take out the workpiece subjected to isostatic pressing The pressure vessel 110 can be opened or closed.

The driving mechanism is configured such that the upper and lower caps 113 and 115 open and close the pressure vessel 110 in the left and right or upper and lower directions As shown in FIG.

On the other hand, the drive mechanism may be implemented as a hydraulic or pneumatic cylinder

As shown in FIGS. 5 and 6, the isostatic pressing apparatus 100 according to the embodiment of the present invention may include a heat exchanger 200.

The heat exchanger 200 may heat or cool the pressurizing medium filled in the receiving recess 111, and the heat exchanger 200 may include the heat exchanging member 210.

The heat exchange member 210 is located inside the receiving groove 111 to directly heat or cool the pressing medium filled in the receiving groove 111. The heat exchanging member 210 is disposed inside the receiving groove 111 As shown in FIG.

Meanwhile, the heat exchange member 210 may be configured to include a cooling member and a heating member.

That is, the heat exchanging member 210 is divided into a cooling member and a heating member so that the cooling member cools the pressurizing medium filled in the receiving groove 111, and the heating member heats the pressurizing medium filled in the receiving groove 111 .

Here, the heating member may be realized by a heater which is heated by electricity, and the cooling member may be realized by a cooling sink or an evaporator which absorbs heat.

In addition, the heat exchange member 210 may also be realized as a Peltier element that electrically cools one side and heats the other side.

The heat exchange member 210 may be configured to cool or heat the pressurized medium through the heat exchange member 210 as the heat transfer medium 210 passes through the heat exchange member 210, which is a fluid or a gas, as in the embodiment.

The heat exchange member 210 is formed with an inlet 211 through which the heating medium flows and a discharge port 212 through which the heating medium is discharged so that the inlet 211 and the outlet 212 pass through the heat exchanging member 210 in a zigzag manner. The heating medium flowing into the inlet 211 may be connected to each other through the micro flow path 213 formed to circulate the heat exchange member 210 as a whole through the micro flow path 213 and discharge through the outlet 212.

Here, the heat exchange member 210 may be configured to adhere and adhere two plates having a microchannel 213, an inlet 211, and an outlet 212 on one surface thereof, and the microchannel 213 may be formed of a pressurized fluid It can be formed in various depths and depths in accordance with the thickness of the plate so as to have a structure which is not collapsible.

In addition, the heat exchange member 210 may be formed in a plate shape to minimize the volume occupied in the receiving groove 111, or may be formed in a cylindrical shape as shown in FIG. 7, The fine flow path 213 may be formed in a spiral shape inside.

8, the heat exchange member 210 may be formed by bending a tube in a spiral shape.

A plurality of through holes 214 are formed in the heat exchange member 210 so that the pressurizing medium accommodated in the receiving groove 111 freely moves through the heat exchange member 210 and the contact area is widened. However, a plurality of protrusions may be formed to widen the contact area.

The heat exchanging member 210 may be provided with a temperature sensor 215 for measuring the temperature of the pressurizing medium.

The heat exchange member 210 may be installed on one or both of the upper cap 113 and the lower cap 115. The heat exchange member 210 installed on the upper cap 113 or the lower cap 115, Is preferably an electrically heated heater.

The heat exchanger 200 may include a heating medium storage tank 280. The heat medium storage tank 280 may receive a heat medium to be heat-exchanged with the pressurizing medium through the heat exchange member 210.

The heat exchanger 200 may include a heating unit 220 and a cooling unit 230. The heating unit 220 and the cooling unit 230 can receive the heating medium stored in the heating medium storage tank 280 and can heat or cool the heating medium.

That is, the heating unit 220 heats the heating medium stored in the heating medium storage tank 280, and the cooling unit 230 cools the heating medium stored in the heating medium storage tank 280.

The heating unit 220 may include a heater 221 that is heated by electricity or is heated by heating. The cooling unit 230 may include a cooling unit 231 that is cooled by a coolant. have. At this time, the cooling unit 231 may be implemented as an evaporator or a cooling sink, and the cooling unit 230 may be implemented as a chiller that circulates and circulates a general refrigerant.

When the heat exchanging member 210 is divided into a cooling member and a heating member, the heating unit 220 is connected to the heating member, the cooling unit 230 is connected to the cooling member, The heating medium cooled in the heating unit 220 may be configured to heat the pressurizing medium through the heating member.

The heat exchanger 200 may include a selective supply unit 240.

The selective supply unit 240 may selectively supply the heating medium stored in the heating medium storage tank 280 to the heat exchange member 210 through the cooling unit 230 or to the heat exchange member 210 through the heating unit 220 have.

The selective supply unit 240 may be implemented by a solenoid valve that supplies and blocks the heating medium to the heat exchanging member 210 in the cooling unit 230 or the heating unit 220.

The selection feeder 240 may include a feed pump 250. The supply pump 250 supplies the heating medium stored in the heating medium storage tank 280 to the heat exchanging member 210 through the cooling unit 230 or the heating unit 220 and supplies the heating medium supplied to the heat exchanging member 210 again The heating medium can be circulated so as to be stored in the heating medium storage tank 280.

Here, the heating medium may be a fluid or a gas, but is preferably a fluid, and when the heating medium is water, other additives may be mixed so that heat exchange can be performed quickly.

The heat exchanger 200 configured as described above is configured to supply the heating medium stored in the heating medium storage tank 280 to the heating unit 220 when the selective supply unit 240 is selected to heat the pressurized medium received in the receiving groove 111, The heat medium stored in the heat medium storage tank 280 is supplied to the cooling unit 230 so that the heat medium is supplied to the heat exchanging member 210 in a state where the heat medium is cooled, 210), the pressurizing medium can be cooled or heated in a short time.

The isostatic pressing apparatus 100 according to the embodiment of the present invention may include a heat insulating material 300. The heat insulating material 300 is provided on the inner surface of the receiving groove 111 to prevent the heat of the heat exchanging member 210 from being transmitted to the pressure vessel 110.

That is, the heat exchanger 300 can prevent the heat exchange member 210 from leaking heat out of the receiving groove 111 by inserting the heat exchanger member 210 so that heat exchange can be performed only with the pressurizing medium accommodated in the receiving groove 111.

In addition, not only the inside of the pressure vessel 110 but also the upper cap 113 and the lower cap 115 for sealing the receiving groove 111 can be provided.

The heat insulating material 300 may be formed of any one of materials such as Teflon, polyimide resin, and ceramics having high hardness and high thermal conductivity to withstand the high pressure of the pressurizing medium.

The operation and effect between the above-described respective constitutions will be described.

The isometric pressure press apparatus 100 according to the embodiment of the present invention is provided with the heat exchange member 210 in the receiving groove 111 of the pressure vessel 110 and the heat insulating material 300 is installed in the receiving groove 111 Thereby preventing the heat of the heat exchange member 210 from being transmitted to the outside of the pressure vessel 110.

The heat exchanging member 210 is disposed in the inlet 211 of the heat exchanging member 210 so that the heat exchanging member 210 is cooled or cooled by the cooling unit 230 or the heating unit 220, (230), the heating unit (220), and the heating medium supply pipe (260).

Although the heat exchanger 210 is connected to the heat exchanger 210 through the upper cap 113 to supply the heat medium to the heat exchanger 210 through the side of the lower cap 113 or the pressure vessel 110, .

The heat exchanging member 210 is connected to the heating medium storage tank 280 so that the heating medium circulating through the micro flow path 213 of the heat exchanging member 210 is discharged to the heating medium storage tank 280, And the heat medium discharge pipe 270. [

The heating unit 220 and the cooling unit 230 are provided with a selective supply unit 240 to selectively heat the heating medium heated in the heating unit 220 or the heating medium cooled in the cooling unit 230 to the heat exchange member 210 .

The upper casing 113 or the lower casing 115 is moved by the drive mechanism 120 to move the accommodating recess 111 of the pressure vessel 110 A drive mechanism 120 may be installed in the frame or pressure vessel 110 to open or close.

The lower cap 115 of the pressure vessel 110 may be connected to a pressurizing medium supply mechanism 130 for supplying the pressurizing medium to the receiving groove 111 when the receiving groove 111 is closed.

In order to perform isostatic pressing, the isostatic pressing apparatus 100 configured as described above firstly uses the driving mechanism 120 to bring the workpiece into the receiving recess 111, 115 are moved to open the pressure vessel 110.

When the shelf 114 is installed in the upper cap 113 or the lower cap 115, the workpiece is placed in the accommodating recess 111 in a state in which the workpiece is seated in the shelf 114, The upper cap 113 or the lower cap 115 is moved using the driving mechanism 120 so as to close the groove 111 and the pressure medium is supplied into the receiving groove 111 through the pressurizing medium supply mechanism 130. [ Pressure compression molding is performed.

On the other hand, when the workpiece is heated to a temperature higher than a certain temperature during the isotropic compression molding, for example, when the workpiece is fired while maintaining the pressing force, the heating medium stored in the heating medium storage tank 280 is heated 220 and supplies the heat to the heat exchange member 210. The heat exchange member 210 and the pressurizing medium exchange heat to heat the workpiece to an arbitrary temperature.

At this time, even if the heating medium is water, since the pressure of the receiving groove 111 is high, the boiling point of water in the pressurizing medium is increased, and the pressurizing medium can be heated to 100 ° C or higher. The temperature of the pressurizing medium is measured by the temperature sensor 215, .

Further, when the workpiece is to be cooled to a certain temperature or lower, for example, in a state where the pressing force is maintained on the workpiece during isometric compression molding, the heating medium stored in the heating medium storage tank 280 is cooled 230 to the heat exchange member 210 to heat exchange the heat exchange member 210 with the pressurization medium, thereby cooling the workpiece to an arbitrary temperature or lower.

At this time, the temperature of the pressurizing medium to be cooled can be measured by the temperature sensor 215 and maintained at a uniform temperature and cooled.

When the isometric compression molding is completed, the upper cap 113 or the lower cap 115 of the pressure vessel 110 is opened by using the driving mechanism 120 to pressurize the pressurizing medium filled in the receiving recess 111, Pressure compression molding operation in which the workpiece placed on the shelf 114 of the upper cap 113 or the lower cap 115 is taken out is finished .

Therefore, since the iso-pressure press apparatus 100 according to the embodiment of the present invention can directly heat or cool the heating medium, which pressurizes the workpiece with an iso-pressure, through the heat exchanger 200, Heating or cooling can minimize compression molding time and heat loss.

Further, since the workpiece is directly heated or cooled by the pressure medium, the workpiece can be heated or cooled at a uniform temperature.

Further, by heating or cooling the workpiece in a state in which the pressure is maintained, it is possible to obtain a workpiece having a dense structure, thereby minimizing the defective rate of the workpiece.

In addition, since the heat insulating material is installed inside the pressure vessel 110 to prevent the heat from being transferred to the pressure vessel 110, damage of the packing can be prevented, and pressure loss and airtightness can be improved.

Hereinafter, a method of manufacturing a chip component using the isostatic pressing apparatus 100 according to an embodiment of the present invention will be described.

Although the method of manufacturing the chip component according to the embodiment is described as using the isostatic pressing apparatus 100 according to the embodiment of the present invention described above, the known isotropic press apparatus 100 of various types may be applied to the heat exchanger 200) are installed.

First, the chip component may be subjected to a semi-finished product molding step before bringing the chip component into the isostatic pressing apparatus 100 according to the embodiment of the present invention.

In this semi-finished product forming step, a slurry having a high formability is prepared by mixing a solvent, a binder and the like in a powder, and the slurry is formed into a sheet form and laminated together with electrodes, or formed into an arbitrary shape, Can be molded.

For example, a chip capacitor and a chip varistor among chip components are manufactured by forming a slurry in a sheet form and alternately stacking an electrode and a sheet. The chip inductor forms a slurry in an arbitrary shape, And the semi-finished product can be formed differently according to each chip component such as a laminate.

Meanwhile, in the semi-finished product molding step, the powder may be a ceramic powder or a metal powder, and a ceramic resin such as polyimide or epoxy may be mixed with a ceramic powder or a metal powder, or a ceramic powder, a metal powder and a polymer resin may be mixed together to form a binder Can be prepared.

When a semi-finished product is molded into a slurry containing a binder, it is necessary to perform a burn-out process to remove the binder. However, when molding a semi-finished product with a slurry that does not require a binder including a polymer resin, There is no. Therefore, in the present invention, it is preferable to mold a semi-finished product with a slurry containing a polymer resin which does not perform the burnout process.

When the semi-finished product for manufacturing the chip component is molded as described above, compression molding is performed using the isostatic pressing apparatus 100 according to the embodiment of the present invention as follows.

As shown in FIG. 9, a method of manufacturing a chip component using the isostatic pressing apparatus 100 according to an embodiment of the present invention may include a step (S10) of loading a chip component as a workpiece.

In step S10 of carrying out the chip component, the chip component is carried into the receiving groove 111 of the isostatic pressing apparatus 100 for compression-molding the semi-finished product molded in the semi-finished product forming step.

At this time, the chip component can be carried into the receiving groove 111 with the upper cap 113 or the lower cap 115 of the pressure vessel 110 opened to carry the chip component into the receiving groove 111 The chip component can be brought into the receiving groove 111 in a state where the chip component is seated on a shelf coupled to the upper cap 113 or the lower cap 115 so that the chip component can be easily placed in and transported into the receiving groove 111 .

When the chip component is received in the receiving groove 111, the upper cap 113 or the lower cap 115 is closed to seal the pressure vessel 110. [

The method of manufacturing a chip component using the isostatic pressing apparatus 100 according to the embodiment of the present invention may include performing (S20) an isotropic compression molding of the chip component.

The step S20 of performing isotropic compression molding of the chip component is performed by supplying a pressurizing medium to the receiving groove 111 through the pressurizing medium supply mechanism 130 and applying isometric pressure compression to the chip component carried in the receiving groove 111 Molding is performed.

At this time, isometric compression molding is performed to the receiving groove 111 at a preset pressure, and isotropic compression molding is performed for a preset time.

The method of manufacturing a chip component using the isostatic pressing apparatus 100 according to an embodiment of the present invention may include a step (S30) of heating a heat exchange member 210 that performs heat exchange with a pressurizing medium.

The step (S30) of heating the heat exchange member 210 to be heat-exchanged with the pressurizing medium may heat the pressurized medium through heating of the heat exchange member 210. [ That is, the pressurizing medium can be heated to perform baking on the chip component.

Here, the step S30 of heating the heat exchanging member 210 to be heat-exchanged with the pressurizing medium is performed after the pressurizing medium is supplied to the receiving groove 111 and the isotropic pressure compression molding is finished for the predetermined period of time, The pressing medium can be heated while maintaining the pressing force of the pressing medium during the molding.

On the other hand, the pressurizing medium is a pressurized medium in which the heating medium heated through the heating unit 220 of the heat exchanger 200 is supplied to the heat exchanging member 210 and the heat exchanging member 210 heated by the heating medium performs heat exchange with the pressurizing medium. The medium can be heated.

At this time, the heating of the pressurizing medium may be performed for a preset time while maintaining a predetermined temperature through the temperature sensor 215 provided in the heat exchanging member 210.

The method of manufacturing a chip component using the isostatic pressing apparatus 100 according to an embodiment of the present invention may include a step (S40) of cooling a heat exchange member 210 that performs heat exchange with a pressurizing medium.

Step S40 of cooling the heat exchange member 210 to be heat-exchanged with the pressurizing medium may cool the chip component in such a manner that the pressurizing medium is cooled to cure the chip component.

For example, when a chip component is cooled in a heated state, a chip component having a dense structure can be manufactured. At this stage, the curing can be performed by cooling the fired chip parts using the pressurizing medium.

Here, the step of cooling the heat exchanging member 210 that performs heat exchange with the pressurizing medium may be performed after the step of heating the heat exchanging member 210 that performs heat exchange with the above-described pressurizing medium, or may be performed after heating the heat exchanging member 210, May be performed prior to the step of.

The step S40 of cooling the heat exchange member 210 to be heat-exchanged with the pressurizing medium may be performed for a preset time while maintaining a preset temperature through the temperature sensor 215 provided in the heat exchange member 210 have.

When the pressurizing medium is cooled, the heating medium is cooled through the cooling unit 230 of the heat exchanger 200, the cooled heat medium is supplied to the heat exchanging member 210, and finally the heat exchanging member 210 is heat- Thereby cooling it.

The method of manufacturing a chip component using the isostatic pressing apparatus 100 according to the embodiment of the present invention may include a step S50 of discharging a pressurizing medium supplied to the receiving groove 111 from the receiving groove 111 .

The step of discharging the pressurized medium supplied to the receiving groove 111 from the receiving groove 111 includes pressing the pressurizing medium filled in the receiving groove 111 to take out the isotropically compression- To the outside of the pressure vessel 110.

In the step S50 of discharging the pressurized medium supplied to the receiving groove 111 from the receiving groove 111, the upper cap 113 or the lower cap 115, which hermetically seals the lower portion of the pressure vessel 110, The pressurizing medium accommodated in the accommodating grooves 111 is discharged from the accommodating grooves 111 in such a manner that the pressurizing medium accommodated in the accommodating grooves 111 is moved through the drive mechanism 120 or the pressurizing medium is recovered again through the pressurizing medium supply mechanism 130 .

A method of manufacturing a chip component using the isostatic pressing apparatus 100 according to an embodiment of the present invention may include a step S60 of carrying out a chip component accommodated in the receiving groove 111.

The step S60 of carrying out the chip component accommodated in the receiving groove 111 is a step of taking out the chip component from the isostatic pressing apparatus 100 for the next step of the isotropic pressure compression molded chip component.

The lower cap 115 or the upper cap 113 which hermetically seals the pressure vessel 110 is moved by the driving mechanism 120 to move the receiving groove 111 Take out the chip components in the open state.

The chip parts taken out from the isostatic pressing apparatus 100 are cut in accordance with the size to be used, and the outer electrodes are formed so as to be easily mounted on the circuit board in a state where the stacked electrodes are polished to be exposed to the outside. Completes the manufacture of parts.

At this time, the external electrodes may be formed by electroplating with tin, nickel tin, or the like. Depending on the type of chip components, the external electrodes may be removed from the isostatic pressing apparatus 100, and then chip parts may be manufactured through different processes.

Therefore, in the method of manufacturing a chip component using the isostatic pressing apparatus 100 according to the embodiment of the present invention, it is possible to simultaneously perform firing and curing of the chip component in the isostatic pressing apparatus 100 that performs isostatic pressing Therefore, it is possible to manufacture a chip component having a dense structure to minimize the defect rate of the chip component.

In addition, since it is not necessary to provide other production facilities for firing and hardening the chip components, the production cost of the chip components can be lowered.

Further, since the chip component can be directly heated or cooled through the pressurizing medium, the time for manufacturing the chip component can be shortened by heating or cooling the chip component within a short period of time.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: isostatic pressing apparatus 110: pressure vessel
111: receiving groove 113: upper cap
114: shelf 115: bottom cap
130: Pressurizing medium supply mechanism 131: Pressurized medium storage tank
133: pressure pump 135: medium supply line
200: heat exchanger 210: heat exchange member
211: inlet 212: outlet
213: fine flow path 214: through hole
215: temperature sensor 220:
221: heater 230: cooling section
231: Cooling unit 240:
250: Feed pump 260: Heat medium feed pipe
270: Heating medium discharge pipe 280: Heating medium storage tank
300: Insulation

Claims (31)

An isometric press apparatus comprising a pressure vessel in which a receiving groove for receiving a workpiece is formed and a pressing medium is filled in the receiving groove to press the workpiece with iso-pressure,
And a heat exchanger provided in the receiving groove and including a heat exchange member for performing heat exchange with the pressurizing medium to heat or cool the pressurizing medium supplied to the receiving groove. The method according to claim 1,
The heat exchange member
And is heated or cooled by a heat medium supplied to the heat exchange member. 3. The method of claim 2,
The heat exchanger
A heating unit for heating the heating medium, and
And a cooling section for cooling the heating medium. The method of claim 3,
The heat exchanger
And a selective supply unit for selectively supplying the heating unit and the heating medium, which is heated or cooled by the cooling unit, to the heat exchange member. 3. The method of claim 2,
The heat exchanger
And a heating medium storage tank for storing the heating medium. 3. The method of claim 2,
The heat exchange member
An inlet through which the heating medium for cooling or heating the heat exchange member flows,
An outlet through which the heating medium introduced into the inlet is discharged, and
And a micro flow channel connecting the inlet and the outlet so as to circulate the heat exchange member in zigzags. 3. The method of claim 2,
The heating medium
And water. ≪ IMAGE > The method according to claim 1,
The heat exchange member
And a heater which is heated by electricity. The method according to claim 1,
The heat exchange member
And a cooling unit that is cooled by the coolant. The method according to claim 1,
The heat exchange member
And is formed in any one of a plate shape, a cylindrical shape, and a spiral shape. The method according to claim 1,
The heat exchange member
And a plurality of through holes penetrating the heat exchange member or a plurality of protrusions protruding from an outer surface of the heat exchange member so that a contact area with the pressurizing medium is widened. The method according to claim 1,
And a heat insulating material provided on an inner surface of the receiving groove to prevent the heat of the heat exchanging member from being transmitted to the outside of the receiving groove. 13. The method of claim 12,
The heat insulating material
Resin, ceramic, and the like. The method according to claim 1,
The pressure vessel
Further comprising an upper cap and a lower cap for sealing the upper and lower portions of the pressure vessel respectively,
And a heater installed on one or both of the upper cap and the lower cap to heat the pressure medium. The method according to claim 1,
The pressure vessel
Further comprising an upper cap and a lower cap for sealing the upper and lower portions of the pressure vessel respectively,
And a lathe coupled to one of the upper cap and the lower cap to receive a workpiece. A pressure vessel in which a receiving groove for receiving a chip component is formed and the pressing groove is filled in the receiving groove to press the chip component with iso-pressure; and a pressure vessel provided in the receiving groove to heat or cool the pressurizing medium supplied to the receiving groove And a heat exchanger for exchanging heat with the pressurizing medium, the method comprising the steps of:
Loading the chip component into the receiving groove,
Supplying the pressurizing medium to the receiving groove to perform isometric compression molding of the chip component,
Heating the heat exchanging member that performs heat exchange with the pressurizing medium so that the chip component is heated while the pressure is maintained by the pressurizing medium,
Discharging the pressurizing medium supplied to the receiving groove from the receiving groove; and
And carrying out the chip component accommodated in the receiving groove. ≪ Desc / Clms Page number 19 > 17. The method of claim 16,
Before or after the step of heating the heat exchange member to heat-exchange with the pressurizing medium,
And cooling the heat exchange member that is to be heat-exchanged with the pressurizing medium so that the chip component is cooled while the pressure is maintained by the pressurizing medium. 17. The method of claim 16,
The heat exchange member
Wherein the heat exchanger is heated or cooled by a heat medium supplied to the heat exchanging member. 19. The method of claim 18,
The heat exchanger
A heating unit for heating the heating medium, and
And a cooling portion for cooling the heat medium. 19. The method of claim 18,
The heat exchanger
And a selective supply unit that selectively supplies the heating medium and the heating medium to be heated or cooled by the heat exchanging member to the heating unit and the cooling unit. 19. The method of claim 18,
The heat exchanger
And a heating medium storage tank for storing the heating medium. 19. The method of claim 18,
The heat exchange member
An inlet through which the heating medium for cooling or heating the heat exchange member flows,
An outlet through which the heating medium introduced into the inlet is discharged, and
And a micro flow channel connecting the inlet and the outlet so as to circulate the heat exchange member in a staggered manner. 19. The method of claim 18,
The heating medium
Wherein the isotropic pressing apparatus comprises water. 17. The method of claim 16,
The heat exchange member
A method of manufacturing a chip component using an isostatic pressing apparatus, the apparatus comprising a heater heated by electricity. 17. The method of claim 16,
The heat exchange member
And a cooling unit that is cooled by a coolant. ≪ RTI ID = 0.0 > 11. < / RTI > 17. The method of claim 16,
The heat exchange member
Wherein the isotropic press die is formed in a plate shape, a cylindrical shape, or a spiral shape. 17. The method of claim 16,
The heat exchange member
And a plurality of protrusions protruding from the outer surface of the heat exchange member, wherein the plurality of through holes penetrate through the heat exchange member to widen the contact area with the pressurizing medium. . 17. The method of claim 16,
And a heat insulating material provided on the inner surface of the receiving groove to prevent the heat of the heat exchanging member from being transmitted to the outside of the receiving groove. 29. The method of claim 28,
The heat insulating material
Resin, and ceramics. The method of manufacturing a chip component using the isostatic pressing apparatus according to claim 1, 17. The method of claim 16,
The pressure vessel
Further comprising an upper cap and a lower cap for sealing the upper and lower portions of the pressure vessel respectively,
And a heater installed on one or both of the upper cap and the lower cap to heat the pressure medium. 17. The method of claim 16,
The pressure vessel
Further comprising an upper cap and a lower cap for sealing the upper and lower portions of the pressure vessel respectively,
And a shelf coupled to one of the upper cap and the lower cap and on which the workpiece is mounted.

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