KR101327437B1 - Isothemal cooling device - Google Patents

Abstract

The invention relates to a continuous isothermal cooling apparatus having a dual structure. The continuous isothermal cooling apparatus, which is installed between a heat treatment device and a tempering device, comprises a mesh belt part, an insulation chamber, a guide plate, a heating element, a lower heating element, an isothermal cooling frame, a cooling fan, an upper vent hole, an internal circulation fan, a discharging hood, and a cooling path part. The mesh belt part moves a material, which is provided from the heat treatment device, to the tempering device. The insulation chamber, in which a front and a rear are opened, surrounds the mesh belt part. The guide plate, in which multiple through holes are formed, is installed to adhere to a lower part of an upper side of the mesh belt part. The heating element is installed in both sides inside the insulation chamber. The lower heating element is installed in a lower part of the guide plate. The isothermal cooling frame surrounds the insulation chamber with having a regular internal space. The cooling fan, which is installed in a side of the cooling frame, injects an outside air to an inside. The upper vent hole is formed in an upper side of the insulation chamber. The internal circulation fan, which is installed in an upper part of the cooling frame, circulates an air inside the cooling frame. The discharging hood is installed to discharge an air inside the insulation chamber to an outside. The cooling path part inflows an air, which is discharged through the discharging hood, to an inside of the insulation chamber through a lower vent hole, which is formed in a lower side of the insulation chamber.

Description

Continuous isothermal cooling device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous isothermal cooling device, and more particularly, to a continuous isothermal cooling device that can cope actively with a type of forged product reheated using a double structure.

Isothermal cooling is a method of using a thermal bath as a cooling means, and then isothermally cooled and then taken out and cooled.

Isothermal cooling and relatively general cooling are called anisothermal cooling, such as austempering and marquenching.

In particular, it is widely used in the manufacturing process of forgings of mechanical parts, such as automobiles, and is widely used for improving workability required for ring gears and automobile parts, controlling deformation after heat treatment, and improving mechanical properties of products.

Prior arts related to such isothermal cooling devices include Korean Patent Application Nos. 10-2007-0022751, 10-2007-0022744, and others filed with the Korean Intellectual Property Office.

However, although the conventional isothermal cooling device is installed between the heat treatment device and the tempering device, there is a problem that it is difficult to adjust the cooling temperature and the cooling rate according to the type of forging.

Continuous isothermal cooling device having a dual structure according to the present invention has an object to provide a continuous isothermal cooling device that can efficiently control the cooling temperature and cooling rate according to the type and size of the forging.

The continuous isothermal cooling device according to the present invention is a continuous isothermal cooling device provided between a heat treatment device and a tempering device, the mesh belt part for moving a material supplied from the heat treatment device to a tempering device, and wraps the mesh belt part, front and rear The opening of the heat insulating chamber, the guide plate is provided in close contact with the upper surface of the upper side of the mesh belt portion, a plurality of through-holes, the heating element is provided on both sides of the inner side of the heat insulating chamber, and the lower heating element is provided below the guide plate An isothermal cooling frame surrounding the insulation chamber and a predetermined internal space, a cooling fan installed at a side of the cooling frame to introduce external air into the interior, an upper vent formed on an upper surface of the insulation chamber, and Installed in the upper side for internal circulation to circulate the air inside the cooling frame And a discharge hood installed to discharge the air inside the adiabatic chamber to the outside, and a cooling passage for introducing air discharged through the discharge hood into the adiabatic chamber through a lower vent formed in the lower surface of the adiabatic chamber. It is characterized by including.

Here, the isothermal frame surrounding the mesh belt portion adjacent to the cooling frame, a heating element installed on the inner surface of the isothermal frame, a discharge hood installed to discharge the internal air of the isothermal frame to the outside, and the discharge Cooling passage portion is further included in the isothermal frame through the lower air vent formed on the lower surface of the isothermal frame to discharge the air discharged through the hood.

In addition, the cooling frame is characterized in that the cooling means for cooling the mesh belt portion is provided.

Finally, the cooling means for adjusting the internal temperature is further installed on the inner surface of the cooling frame.

The continuous isothermal cooling device having a dual structure according to the present invention adopts a structure for circulating internal air through a space between the adiabatic chamber and the cooling frame, and reuses the discharged air by using a cooling passage to reduce the cooling temperature and the cooling rate. There is an advantage that the adjustment can be made efficiently.

In addition, an isothermal frame may be installed after the cooling frame to perform isothermal cooling more effectively.

1 is a plan view showing a continuous isothermal cooling device having a dual structure according to the present invention.
2 is a cross-sectional view of a continuous isothermal cooling device having a dual structure according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA ′ of FIG. 2;
4 is a cross-sectional view taken along line BB ′ of FIG. 2.
5 is a plan view showing a guide plate according to an embodiment of the present invention.

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

1 is a plan view showing a continuous isothermal cooling device having a dual structure according to the present invention.

As shown in FIG. 1, a continuous isothermal cooling device 200 having a dual structure according to the present invention is installed between a heat treatment device 100 and a tempering device 300 to perform an annealing process after reheating a forged product. The device connects a tempering device with a heat treatment device.

2 is a cross-sectional view of a continuous isothermal cooling device having a dual structure according to a preferred embodiment of the present invention.

The continuous isothermal cooling device having a dual structure according to the present invention includes a mesh belt part, a heat insulating chamber, a guide plate, a heating element, a lower heating element, a cooling frame, an upper vent, an internal circulation fan, a discharge hood, and a cooling passage part.

First, the cooling frame 201 serves as a main frame of the cooling device, and the front and rear sides are opened to allow the mesh belt part 211 to be circulated.

In particular, the front door 260 and the rear door 270 are installed at the inlet and the outlet where the mesh belt part 211 flows into the cooling frame 201 in a hinged manner, so that the temperature inside the cooling frame 201 is moved to the outside. To prevent leakage.

 Next, the mesh belt portion 211 serves to move the product to be conveyed while being rotated through the drive motor 211a, and comprises a reducer, an auxiliary drum, a coating drum and the like.

The mesh belt part 211 serves to move the material supplied from the heat treatment apparatus 100 to the tempering apparatus 300.

In addition, the mesh belt part 211 is wrapped through the cooling frame 201, and a dual structure in which the heat insulation chamber surrounds the mesh belt part 211 is adopted inside the cooling frame 201.

A cooling means 206c for cooling the mesh belt part 211 is provided below the cooling frame 201.

The cooling means 206c serves to cool the heated mesh belt part 211 in the process of transferring the heat treated product, and is cooled to an appropriate temperature to move forward.

3 is a cross-sectional view taken along line AA ′ of FIG. 2.

As shown in FIG. 3, the mesh belt part 211 to which the heat-treated product is transferred should be manufactured in a heat resistant steel structure, insulated through a ceramic module, and manufactured in a structure capable of withstanding low temperatures.

In addition, a heat generating element 206 is installed on an inner surface of the heat insulating chamber 216, and the heat generating element 206 serves to prevent quenching and maintain a constant temperature of an internal temperature during cooling of a heat treatment product such as a forged product.

In addition, the heating element 206 and the lower heating element to be described later may be controlled from the outside by measuring the internal temperature of the chamber.

Here, a cooling fan 219 for introducing external air into the cooling frame 201 and a cooling means 218 using cooling water are installed on the side of the cooling frame 201 to efficiently control the internal temperature.

Here, the cooling means 218 may lower the internal temperature through the external cooling water, and the cooling fan 219 may lower the internal temperature by introducing the internal air.

The insulation chamber 216 is installed inside the cooling frame 201, an upper vent 251 is formed on an upper surface of the insulation chamber 216, and side vents 252 are installed on both sides thereof.

In addition, a lower vent 253 is provided on the lower surface of the heat insulating chamber 216.

As shown in FIG. 3, the air inside the insulation chamber 216 is discharged upward through the upper vent 251. The space between the insulation chamber 216 and the cooling frame 201 through the internal circulation fan 205 is shown. It is moved to, and flows back into the heat insulating chamber 216 through the side vent 252.

As shown in FIG. 3, the air inside the insulation chamber 216 is discharged upward through the upper vent 251. The space between the insulation chamber 216 and the cooling frame 201 through the internal circulation fan 205 is shown. It is moved to (S), and flows back into the heat insulating chamber 216 through the side vent 252.

In addition, the discharge hood 208 is a device for discharging the internal air according to the temperature control to the outside at the time of cooling movement of the product, such as forging products through the mesh belt portion.

The cooling passage 290 serves to introduce cooling air into the heat insulation chamber 216 through the lower vent 253. Rather than inhaling the external cold air, the air discharged through the discharge hood 208 is reused to cool the product being transported through the lower vent 253. In particular, air is supplied by the pressure difference without a separate cooling fan 219.

The internal circulation fan 205 is installed on the upper side of the cooling frame 201 to circulate air in the cooling frame 201, and is installed on the upper side of the upper vent 251 as shown in FIG. 3. The internal air is moved to the space S between the heat insulation chamber 216 and the cooling frame 201.

The internal circulation fan 205 employs an inverter motor to adjust the rotation speed and the air volume from the outside to respond to changes in the internal temperature.

Next, the guide plate 280 is installed to be in close contact with the upper lower surface of the mesh belt portion is formed with a plurality of through holes, has a cross-section of the 'c' shape.

5 is a plan view showing a guide plate according to an embodiment of the present invention.

As shown in FIG. 5, the guide plate 280 serves to support the mesh belt portion to be moved from the bottom, and allows the air introduced through the cooling passage 290 to pass through the through hole 282. do.

In particular, the lower heating element 206b is installed below the guide plate 280 shown in FIG. 3. The lower heating element 206b is used to adjust the temperature of the air flowing through the cooling passage 290.

Through the heating element 206 and the lower heating element 206b described above, the proper temperature is maintained in the adiabatic chamber.

Next, as shown in FIG. 2, an isothermal frame 202 having a heating element installed therein to prevent overcooling and maintain isothermal temperature of 600 to 700 degrees Celsius product cooled in the cooling frame 201 is the cooling frame 201. It is installed adjacent to.

The isothermal frame 202 is installed to surround the mesh belt portion adjacent to the cooling frame 201. Looking at the inside of the isothermal frame 202 in more detail, FIG. 4 is a cross-sectional view of the portion B-B 'of FIG. .

As shown in FIG. 4, an inner surface of the isothermal frame 202 is provided with heating elements 206 a on the left and right sides and a lower surface, and a cooling fan 219 a is installed to adjust the cooling rate and temperature through the outside air. .

A lower vent 253a is formed on a lower surface of the isothermal frame 202, and a cooling passage 290a for introducing cooling air into the isothermal frame 202 is similar to the cooling frame. It is installed so as to be connected to the discharge hood 208a to discharge the internal air of the isothermal frame 202 to the outside.

As described above, the present invention has a main technical idea to provide a continuous isothermal cooling device, and since the embodiment described above with reference to the drawings is only one embodiment, the true scope of the present invention is determined by the claims. Should be.

100: heat treatment device
200: continuous isothermal cooling device
201: cooling frame
202: isothermal frame
205: internal circulation fan
206, 206a: heating element
206b: bottom heating element
208, 208a: discharge hood
211: mesh belt portion
216: insulation chamber
218: cooling means
219, 219a: cooling fan
251: upper vent
252: side vents
253: bottom vent
260: front door
270 rear door
280: guide plate
282: through hole
290, 290a: cooling passage section
300: tempering device

Claims (4)

In the continuous isothermal cooling device provided between the heat treatment device and the tempering device,
A mesh belt portion for moving the material supplied from the heat treatment apparatus to a tempering apparatus;
An adiabatic chamber surrounding the mesh belt part and having a front and rear opening;
A guide plate installed to be in close contact with the upper lower surface of the mesh belt part, the guide plate having a plurality of through holes;
Heating elements installed on both sides of the heat insulating chamber;
A lower heating element installed below the guide plate;
An isothermal cooling frame surrounding the insulation chamber and a predetermined internal space;
A cooling fan installed at a side of the cooling frame to introduce external air into the interior;
An upper vent formed on an upper surface of the adiabatic chamber;
An inner circulation fan installed at an upper side of the cooling frame to circulate air in the cooling frame;
A discharge hood installed to discharge air inside the adiabatic chamber to the outside;
And a cooling passage part for introducing the air discharged through the discharge hood into the heat insulating chamber through a lower vent formed in the lower surface of the heat insulating chamber. The method of claim 1,
An isothermal frame surrounding the mesh belt portion adjacent to the cooling frame, a heating element installed on an inner surface of the isothermal frame, a discharge hood installed to discharge the internal air of the isothermal frame to the outside, and the discharge hood Continuous isothermal cooling device further comprises a cooling passage portion into the isothermal frame through the lower air vent formed in the lower surface of the isothermal frame is discharged through. The method of claim 1,
Under the cooling frame,
Cooling means for cooling the mesh belt portion is provided, characterized in that the continuous isothermal cooling device. The method of claim 1,
On the inner side of the cooling frame
Continuous isothermal cooling device, characterized in that further cooling means for adjusting the internal temperature is installed.

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