KR100495267B1 - Automatic vacuum mold heat treatment apparatus - Google Patents

Abstract

The present invention relates to an automatic vacuum mold heat treatment apparatus for maximizing automation and heat treatment efficiency of mold heat treatment by allowing heating and cooling to be simultaneously performed in one heat treatment furnace. An impeller provided inside the refrigerant gas guide tank partitioned by a partition wall and rotatably installed by a driving motor fixed to an outer surface thereof; A reaction tank spaced apart from the impeller and having a first and second discharge openings inside and having an enclosed space; A first baffle connected to the cylinder means to selectively open and close the first outlet and movably disposed adjacent to the first outlet; A second baffle fixed in the reactor adjacent to the second outlet; A sliding door installed to move forward and backward by a cylinder means to selectively communicate the reaction tank with the refrigerant gas guide tank; An injection pipe, which is piped in parallel to each other so as to communicate between the refrigerant gas guide tank and the reaction tank, and is intensively sprayed with the circulating coolant gas to the side of the workpiece to be seated in the reaction tank; It comprises a plurality of cooling pipes piped between the outer peripheral surface of the reactor and the inner wall surface of the main body.

According to the present invention, heat treatment such as quenching and tempering of all molds is possible in one furnace body, and automation is easy, so that operation is simple and heat treatment time is shortened because there is no movement of a processed product, and vacuum gloss can be further increased.

Description

Automatic Vacuum Mold Heat Treatment Equipment {AUTOMATIC VACUUM MOLD HEAT TREATMENT APPARATUS}

The present invention relates to an automatic vacuum heat treatment apparatus capable of automating heat treatment and maximizing heat treatment efficiency by enabling simultaneous heating and cooling in one heat treatment furnace.

Vacuum heat treatment refers to the heat treatment performed in a vacuum enclosed space in which the metal to be treated is evacuated to a partial pressure suitable for the process. This is because a vacuum atmosphere prevents the oxidation of the metal. Applications include cutting tools, molds, rolling dies, It has a variety of applications such as slit knife, molding punching, special molds, arbors, press products, electrical and electronic products, chemical machinery, hydraulic products, anti-refrigerant gas, defense parts, heat resistant springs, special motors, and generators.

The vacuum heat treatment that performs the vacuum heat treatment is more beautiful than the other heat treatment furnaces after the heat treatment of the workpiece, the surface is beautiful, the brightness is excellent, the thermal efficiency is good and the cooling rate is fast, it is possible to achieve a short delivery time, and also excellent mechanical properties and completely pollution-free Since the process, especially in the heat treatment of the mold, tools, etc., the utilization is increasing rapidly.

However, the conventional vacuum heat treatment apparatus has a disadvantage in that the work is cumbersome and the continuous operation is not only possible, but also the unmanned automation is difficult because the structure for the heating and cooling of the material has a separate structure.

That is, when heat-treating a material such as a mold, a tool, and the like, the object was to be heated and quenched in a quenching vacuum furnace, and then transferred to the tempering furnace provided separately, and then tempered. The shortcomings were not solved.

The present invention has been made in view of the above-described problems of the prior art, and has been created to solve this problem. The heating and quenching treatment is performed in a state in which a workpiece is once inserted into a vacuum heat treatment apparatus, followed by a continuous tempering treatment. The purpose of the present invention is to provide an automatic vacuum heat treatment apparatus that can be thermally processed quickly and easily continuously to be processed to improve the productivity as well as to enable unmanned automation.

The above object of the present invention is an impeller provided in the refrigerant gas guide tank partitioned by a partition and installed rotatably by a drive motor provided on one inner surface of the main body is maintained in a vacuum and fixed to the outer surface; A reaction tank spaced apart from the impeller and having a first and second discharge openings inside and having an enclosed space; A first baffle connected to the cylinder means to selectively open and close the first outlet and movably disposed adjacent to the first outlet; A second baffle fixed in the reactor adjacent to the second outlet; A sliding door installed to move forward and backward by a cylinder means to selectively communicate the reaction tank with the refrigerant gas guide tank; An injection pipe, which is piped in parallel to each other so as to communicate between the refrigerant gas guide tank and the reaction tank, and is intensively sprayed with the circulating coolant gas to the side of the workpiece to be seated in the reaction tank; It is achieved by providing an automatic vacuum heat treatment apparatus comprising a plurality of cooling pipes piped between the outer peripheral surface of the reactor and the inner wall surface of the main body.

Hereinafter, with reference to the accompanying drawings will be described in more detail the technical spirit of the present invention.

1 is an operating state diagram showing the internal structure of the vacuum mold heat treatment apparatus according to the present invention and at the same time showing a heating process, Figure 2 is an operating state diagram showing a cooling process of the vacuum mold heat treatment apparatus according to the present invention.

1 and 2, a substantially cylindrical robon body 100 is provided, and the robon body 100 is supported and fixed to be spaced apart from the ground by a support 110 placed on the bottom surface.

The main body 100 is maintained in a vacuum having a selective degree of vacuum between atmospheric pressure and 10 ^-5 Torr, one side of the outer surface is provided with a drive motor 112, is connected to the drive motor 112 and the main body ( A rotatable impeller 120 is installed inside the refrigerant gas guide tank 160 on one inner wall surface of the side 100.

The impeller 120 sucks the refrigerant gas in front of the axis and forcibly blows it to the rear side of the impeller 120, but is not dispersed into the furnace by the partition wall 162 forming the refrigerant gas guide tank 160. It is preferable to be configured to flow in the gas guide tank 160 and branched in the injection pipe 300 to be described later to be distributed and blown in both directions.

Here, the refrigerant gas guide tank 160 has a structure sealed by the partition wall 162 formed of a material having a heat insulating performance, and has a structure in which the inlet 164 is formed in the center of one side thereof.

The front side of the refrigerant gas guide tank 160 is spaced apart from it, and is fixed by an inner wall surface of the main body 100 and a fixing bracket (not shown), and a cylindrical reaction tank 200 having a hollow part is provided therein.

The reaction tank 200 is formed of a material having the same heat insulating performance as the refrigerant gas guide tank 160, and the first outlet 212 is formed in the center portion of one side thereof, the other side of the first outlet 212 On the other side adjacent to the refrigerant gas guide tank 160 is a second outlet 222 is formed perforated.

At this time, the first outlet 212 is preferably formed significantly larger than the second outlet 222, which is to further promote the circulation of the refrigerant gas in the cooling process to be described later.

In addition, the second outlet 222 is formed in the same diameter as the inlet 164 of the refrigerant gas guide tank 160, in particular the cylindrical flowable sliding door 224 is inserted to open and close it. .

In addition, a part of the outer circumferential surface of the sliding door 224 is provided with a second operation cylinder 226 which is fixed to the outside of the robon body 100 and connected by a cylinder rod to move back and forth.

That is, the sliding door 224 is moved forward and backward by the second operation cylinder 226 to seal or seal between the second outlet 222 of the reaction tank 200 and the inlet 164 of the refrigerant gas guide tank 160. Open to adjust the flow of the refrigerant gas inside the main body 100.

The first and second baffles 210 and 220 are spaced apart from each other at one side of the first and second outlets 212 and 222, for example, in a direction facing the impeller 120. It is installed outside the reaction tank 200 adjacent to the first outlet 212, the second baffle 220 is installed inside the reaction tank 200 adjacent to the second outlet 222.

The first baffle 210 is operated by the first operating cylinder 216, the second baffle 220 is sliding without being moved back and forth by the second operating cylinder 226 while forming a structure that is fixed without being flown. As the door 224 comes into close contact with the second baffle 220 or falls off, the door 224 isolates the reaction vessel 200 from the internal space of the main body 100.

On the other hand, a pair of injection pipe 300 is disposed in the reaction tank 200, one end of the injection pipe 300 is disposed adjacent to the impeller 120 of the refrigerant gas guide tank 160 is forcedly sucked furnace The internal refrigerant gas of the main body 100 is disposed to smoothly flow into the injection pipe 300, and the other end penetrates through one side surface of the reaction tank 200 in parallel toward the side in which the first discharge port 212 is formed. Is extended.

In particular, a heater (heater) is integrally provided on the outer circumferential surface of the injection pipe (300). For this purpose, the injection pipe (300) is preferably made of a heat-resistant graphite material, and the injection pipe (300) itself is a heater. Phosphorus, that is, a heater and an injection pipe, may be composed of the same body.

In addition, the injection pipe 300 is connected to the electrode 400 that can generate a heater.

In particular, as shown in Figure 3, the outer circumferential surface of the injection pipe 300 is formed with a plurality of fastening holes 310 along the longitudinal direction, the injection hole 310 is a method in which the injection nozzle 320 is screwed It is separably fastened so that the convective refrigerant gas supplied through the injection pipe 300 can be intensively sprayed onto the object S.

In addition, the inside of the reaction tank 200 is supported by a pair of supporters 280, the mounting table 290 is provided with the workpiece (S) is seated.

In addition, the refrigerant circulates the known cooling equipment (compressor → condenser (capacitor) → capillary tube → evaporator → compressor) on the internal space of the main body 100 except for the refrigerant gas guide tank 160 and the reaction tank 200. Cooling pipe (P) through which the cold air or cooling water exchanged through the heat exchange facility is provided, the cooling pipe (P) is connected to the inlet pipe (296) and the outlet pipe (298) to the main body 100 It is configured to cool the inside.

Looking at the operating relationship of the present invention made of such a configuration as follows.

First, referring to FIG. 1, a heating process (when quenching or tempering heating) of a vacuum heat treatment is performed. In the heating process, the first baffle 210 maintains a state in which the first outlet 212 is closed, whereas the second baffle 210 is closed. The baffle 220 and the second outlet 222 are in an open state, and the sliding door 224 communicates with the second outlet 222 and the inlet 164 of the refrigerant gas guide tank 160 while communicating with the main body. (100) will be separated from the interior (compartment).

In this state, when the impeller 120 is operated, the refrigerant gas inside the reaction tank 200 is forcibly sucked by the impeller 120 and then one end of the injection pipe 300 connected to the refrigerant gas guide tank 160. It is introduced into the through, and the introduced refrigerant gas is heated through a heater that is heated by a current applied through the electrode 400 while moving at a high pressure high speed and then the mounting stage 290 through the injection nozzle 320 Concentrated injection to the to-be-processed object S seated at the side.

The heater is required to stabilize the quality of the heat treatment product by making the workpiece to achieve a uniform temperature distribution in the process of heating and maintaining the temperature quickly and uniformly after heating, and is made of materials such as ceramic, graphite, cantal, and molybdenum It is preferable.

At this time, the treated material is uniformly heat treated by the discharged high-temperature injection refrigerant gas, the atmosphere gas inside the reaction tank 200 required for the heat treatment can be prepared in advance before the heat treatment according to the processing object.

Since the injected high-temperature injection refrigerant gas has no place to proceed any more, the heating process is performed by repeating the circulation which is moved back to the second discharge port 222 and then sucked and discharged by the impeller 120 again.

On the other hand, during the cooling process as shown in Figure 2 (in quenching or cooling after tempering) is operated as follows.

First, while the first baffle 210 maintains a state in which the first outlet 212 is opened, the sliding door 224 is in close contact with the second baffle 220 by the operation of the second operation cylinder 226. The communication relationship between the 200 and the main body 100 is blocked.

In this state, when the impeller 120 is operated, the refrigerant gas inside the main body 100 is forcibly moved to the refrigerant gas guide tank 160 by the impeller 120, and then one end of the injection pipe 300 is provided. While being moved at a high pressure through the spray nozzle 320 is strongly discharged to the to-be-processed object (S) side is concentrated sprayed to cool it.

That is, at this time, since no current is applied through the electrode 400, the heater does not generate heat, and thus the discharged coolant gas uniformly cools the object S.

Since the injected coolant gas has no place to proceed any more, the coolant gas is moved to the first outlet 222 and then cooled with heat through the cooling pipes P through which the coolant flows. The cooling process is performed while repeatedly performing the suction and discharge process by 120).

The above-described process is configured so that the entire process is automatically controlled by a computer according to a program input in advance, and data on the temperature and pressure obtained during the heat treatment process can be transmitted in real time to plot the result.

As described in detail above, the present invention is capable of all heat treatment (hardening, tempering) in one robon body and is easy to automate, so that the heat treatment time is shortened because there is no movement of processed products and the vacuum gloss can be further increased. have.

In addition, real-time monitoring is possible to maintain the uniform quality of the heat treatment products, and the data can be accumulated according to the use of each product, it is possible to heat treatment suited to the required characteristics.

1 is an operating state showing the heating process and at the same time showing the internal structure of the vacuum heat treatment apparatus according to the present invention,

Figure 2 is an operating state showing the cooling process of the vacuum heat treatment apparatus according to the present invention,

Figure 3 is an exploded perspective view of the main part of the device of the present invention.

Explanation of symbols on main parts of the drawing

100 .... Robo 120 .... Impeller

160 .... Refrigerant Gas Guide 164 .... Inlet

200 .... Reactor 210 .... 1 baffle

212 ... 1st outlet 220 ... 2nd baffle

222 ... 2nd outlet 300. Injection pipe

320 .... Spray nozzle P .... Cooling pipe

Claims (4)

An impeller provided in one side inner surface of the main body 100 which is maintained in vacuum and rotatably installed by a driving motor fixed to the outer surface thereof and provided in the refrigerant gas guide tank 160 partitioned by the partition wall 162 ( 120); A reaction tank (200) spaced apart from the impeller (120) and having a first and second discharge ports (212, 222) inside and having an enclosed space; A first baffle 210 connected to the cylinder means to selectively open and close the first outlet 212 and movably installed adjacent to the first outlet 212; A second baffle 220 fixed to the reactor 200 adjacent to the second outlet 222; A sliding door 224 installed forward and backward by a cylinder means to selectively communicate the reaction tank 200 with the refrigerant gas guide tank 160; The refrigerant gas guiding tank 160 and the reaction tank 200 to be connected in parallel to each other and provided with a plurality of fastening holes and injection nozzles circulating refrigerant gas to the side to be processed (S) seated in the reaction tank 200 An injection pipe 300 disposed to be concentrated and sprayed on the outer circumferential surface of the heater; Automatic vacuum mold heat treatment apparatus comprising a plurality of cooling pipes (P) piped between the outer circumferential surface of the reactor 200 and the inner wall surface of the main body 100. The method of claim 1, The refrigerant gas guide tank 160 and the reaction tank 200 is an automatic vacuum mold heat treatment apparatus, characterized in that formed of a heat insulating material. The method of claim 1, The injection pipe 300 is an automatic vacuum mold heat treatment apparatus, characterized in that formed of a graphite material. An impeller provided in one side inner surface of the main body 100 which is maintained in vacuum and rotatably installed by a driving motor fixed to the outer surface thereof and provided in the refrigerant gas guide tank 160 partitioned by the partition wall 162 ( 120); A reaction tank (200) spaced apart from the impeller (120) and having a first and second discharge ports (212, 222) inside and having an enclosed space; A first baffle 210 connected to the cylinder means to selectively open and close the first outlet 212 and movably installed adjacent to the first outlet 212; A second baffle 220 fixed to the reactor 200 adjacent to the second outlet 222; A sliding door 224 installed forward and backward by a cylinder means to selectively communicate the reaction tank 200 with the refrigerant gas guide tank 160; The refrigerant gas guiding tank 160 and the reaction tank 200 to be connected in parallel to each other and provided with a plurality of fastening holes and injection nozzles circulating refrigerant gas to the side to be processed (S) seated in the reaction tank 200 An injection pipe 300 which is disposed so as to be capable of intensive injection and which is configured to be a heater and a pipe so as to simultaneously perform a pipe function and a heater function; Automatic vacuum mold heat treatment apparatus characterized in that it comprises a plurality of cooling pipes (P) piped between the outer peripheral surface of the reactor 200 and the inner wall surface of the main body 100 .