KR101627503B1 - Transfer Unit For High Temperature And Vacuum Heat Treatment Furnace - Google Patents

Abstract

The present invention relates to a device for transferring to a high temperature vacuum heat treating furnace not affected by heat, and is able to accurately control heat treatment of a processing object. More specifically, the device for transferring a processing object between a heating chamber and a cooling chamber in a high temperature vacuum heat treating furnace comprises: a containing space which consists of heat insulating walls; a heat insulating gate which closes the containing space; the heating chamber equipped with a heater to heat the processing object in the containing space; the cooling chamber equipped with a jet orifice to spray cooling gas; and a closing gate to isolate the heating chamber from the cooling chamber including a holding plate to hold the processing object, a plurality of supporting roller groups which support the holding plate, a lifting unit which vertically moves the holding plate placed into the containing space of the heating chamber, a motor arranged outside the high temperature heat treating furnace, a first driving shaft to drive a first pinion gear arranged outside the containing space of the heating chamber, a second driving shaft to drive a second pinion gear arranged in the cooling chamber, first and second clutch members which transfers a driving force to the first and second driving shafts or blocks the driving force, a rack gear part which engages with the first pinion gear or the second pinion gear to be moved in a transfer direction of the processing object, a holding plate combining unit which combines a top surface of the rack gear part and the holding plate to be able to separate, and a rack supporting unit which supports the rack gear part.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a transfer unit for a high-temperature vacuum heat treatment furnace,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a transfer device for a high-temperature vacuum heat treatment furnace, and more particularly, to a transfer device for a high-temperature vacuum heat treatment furnace which includes a heating chamber for heating a workpiece and a cooling chamber for cooling The present invention relates to a transfer device for transferring a transfer sheet.

The high-temperature vacuum heat treatment furnace which is the background of the present invention is a furnace for heating the workpiece by heating the workpiece in a vacuum state under reduced pressure and then injecting an inert gas or the like. The high temperature vacuum heat treatment furnace has no discoloration due to the heat treatment, and has less deformation of the workpiece during cooling and does not cause decarburization / carburization.

As shown in FIG. 1, the initial high-temperature vacuum heat treatment furnace has a storage space 40 in which heat is blocked by the heat insulating wall 20 in the airtight container 10 and the inside can be heated by the heater 30, The workpiece 50 is heated in the processing chamber 40 by heating the workpiece 50 and then the cooling gas cooled by the heat exchanger 60 is injected into the storage space 40 through the injection port 70 to cool the workpiece 50 .

However, in the high-temperature vacuum heat treatment furnace of FIG. 1, since both the heater and the heat insulating wall are heated at a high temperature, it is difficult to perform high-speed cooling and a heater is disposed around the workpiece, there was.

2, the heating chamber 100 for heating the workpiece 50 and the cooling chamber 200 for cooling the heated workpiece 50 are separately provided, and the heating chamber 100 And the cooling chamber 200 are isolated from each other by the blocking gate 300. A roller conveyor 150 is used to move the workpiece 50 between the heating chamber 100 and the cooling chamber 200. The roller conveyor in the heating chamber 100 must be designed to withstand the heat There is a difficulty.

3, a separate small gate 110 is provided in the heating chamber 100, a push-pull member 120 is inserted through the small gate 110, (50) is pushed or pulled to be transferred between the heating chamber (100) and the cooling chamber (200). At this time, the driving mechanism for driving the push-pull member 120 is located outside the heat insulating wall 20 of the heating chamber 100, and is less affected by heat, but the volume of the heating chamber 100 is relatively increased It is difficult to maintain the heating chamber 100 in a vacuum state and it is difficult to control the cooling rate.

JP 4645592 B, March 3, 2011, Figures 1, 3,

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems,

And it is an object of the present invention to provide a transfer device capable of controlling the heat treatment of a workpiece more precisely without being affected by heat, which is a driving mechanism of a transfer device for moving the workpiece between the heating chamber and the cooling chamber.

The transfer device for the high-temperature vacuum heat treatment furnace of the present invention

A heating chamber provided with a storage space made of a heat insulating wall, a heat insulating gate closing the storage space, and a heater for heating a workpiece in the storage space; A cooling chamber having an ejection port for ejecting a cooling gas; And a shutdown gate for isolating the heating chamber and the cooling chamber from each other. The transfer device transfers the workpiece between the heating chamber and the cooling chamber in the high-temperature vacuum heat treatment furnace,

A mounting plate for mounting the workpiece;

A plurality of support roller groups for supporting the mounting plate;

A lifting and lowering mechanism for moving up and down the mounting plate drawn into the storage space of the heating chamber;

A motor provided outside the high-temperature vacuum heat treatment furnace;

A first drive shaft for driving the first pinion gear provided outside the storage space of the heating chamber;

A second drive shaft for driving a second pinion gear provided in the cooling chamber;

First and second clutch members that transmit or interrupt the driving force of the motor to the first and second drive shafts, respectively;

A rack gear portion which is engaged with the first pinion gear or the second pinion gear and is conveyed in the conveying direction of the workpiece;

A mounting plate coupling mechanism detachably coupling the upper surface of the rack gear portion and the mounting plate;

A rack support mechanism for supporting the rack gear portion; .

Preferably, the support roller group provided in the storage space of the heating chamber among the support roller groups (groups) operates integrally with the lifting mechanism.

Preferably, a rack gear is located at the center of the lower surface of the rack gear portion, and both sides of the rack gear are provided with a support surface for contacting the rack support mechanism.

The movement of the rack gear portion is preferably controlled by a sensor for sensing the amount of rotation of the first and second drive shafts or a stopper switch provided in the heating chamber and the cooling chamber, respectively.

According to the present invention, in the high-temperature vacuum heat treatment furnace, the drive mechanism of the conveying device is not affected by heat, thereby ensuring durability, and the heat treatment of the workpiece can be controlled more precisely.

1 to 3 are diagrams showing a conventional high-temperature vacuum heat treatment furnace.
4 and 5 are views showing a high-temperature vacuum heat treatment furnace according to an embodiment of the present invention.
6 and 7 are views showing the internal structure of the heating chamber and the cooling chamber of the embodiment of the present invention.
8 is a perspective view showing the configuration of the periphery of the rack gear portion of the embodiment of the present invention.
9 to 12 are diagrams showing an operation relationship of an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings in accordance with embodiments thereof.

4, the high-temperature vacuum heat treatment furnace of the present embodiment includes a heating chamber 100 for heating the workpiece 50 and a cooling chamber 200 for rapidly cooling the heated workpiece 50 have.

The heating chamber 100 comprises a heat insulating wall 20 and has a receiving space 40 in which the workpiece 50 is received and the receiving space 40 is opened or closed by the insulating gate 130. Inside the heat insulating wall 20, a heater (not shown) for heating the work 50 is provided. The heater is installed at a position that is not disturbed by the movement of the workpiece or is removably installed. The inside of the heating chamber of the present embodiment may maintain a vacuum of about 10 ^-5 torr or may be filled with an inert gas to maintain a certain pressure. However, since the related structure is not related to the technical spirit of the present invention, Is omitted.

The cooling chamber 200 is provided with a plurality of ejection openings 70 through which the cooling gas can be ejected to the workpiece 50. In this embodiment, the pressure of the cooling chamber is maintained at about 20 bar while nitrogen is used as the cooling gas. The cooling gas whose temperature has increased due to heat exchange with the workpiece in the cooling chamber is cooled again by a heat exchanger (not shown) provided outside the cooling chamber and supplied into the cooling chamber.

The heating chamber 100 and the cooling chamber 200 can be isolated or communicated by the shut-off gate 300.

A main gate 400 is provided at one side of the cooling chamber 200 of the present embodiment, which is capable of loading and withdrawing the workpiece 50 into the high-temperature vacuum heat treatment furnace.

In another embodiment, the main gate may be further provided on the side of the heating chamber 100 so that the workpiece can be inserted into the other side.

The workpiece 50 is transferred to the mounting plate 600 supported by the plurality of supporting roller groups 510, 520, 530, and 540 installed in the heating chamber 100 and the cooling chamber 200.

In this embodiment, the support roller group includes a first group of support rollers 510 in the storage space 40 of the heating chamber 100, a second group of support rollers 520 outside the storage space 40, And third and fourth support roller groups 530 and 540 in the second and third support rollers 200 and 200, respectively. Referring to FIG. 7, the support frame 541 supporting the fourth support roller group 540 can be easily understood even if a support for supporting the second, third, and fourth support roller groups is omitted in FIG. 4 .

The first supporting roller group 510 in the storage space 40 of the heating chamber 100 can be moved up and down by the lifting mechanism 550 as shown in FIG. The ascending / descending mechanism 550 uses a straight feed mechanism such as a cylinder. The elevating and lowering mechanism 550 is coupled with the lower surface of the first supporting roller group 510 to elevate the first supporting roller group 510 and the elevation plate 600 However, it is also possible that the first supporting roller group is provided by a support member fixed in the form as shown in Fig. 7, and that the lifting / lowering mechanism lifts only the mounting plate.

Fig. 5 is a plan view of Fig. 4, which does not show a mounting plate, a group of supporting rollers, and a lifting mechanism. As shown in FIG. 5, the motor 700 is provided outside the high-temperature vacuum heat treatment furnace. The first drive shaft 715 provided outside the storage space 40 of the heating chamber 100 is provided with a first pinion gear 718 at the center thereof. Two pinion gears 728 are provided. The first and second clutch members 710 and 720, which transmit or block the driving force of the motor 700 to the first and second drive shafts 715 and 725 respectively, are also provided outside the high temperature vacuum heat treatment furnace.

A rotary encoder 730, which is a sensor for sensing the amount of rotation of the first and second drive shafts 715 and 725, is installed on the opposite side of the first and second drive shafts 715 and 725 on which the first and second clutch members 710 and 720 are installed. And serves to grasp the position of the workpiece.

The rack gear portion 800 of the linear shape is moved in the conveying direction of the workpiece by the driving force transmitted to the first and second pinion gears 718 and 728. The rack gear portion 800 is supported by a rack support mechanism 850. 8, a rack gear 810 is disposed at the center of the lower surface of the rack gear portion 800 and a pair of guide rails 810 are provided on both sides of the rack gear 810 to support the guide roller 851 of the rack support mechanism 850. [ (820).

The mounting plate 600 is detachably mounted on the upper surface of the rack gear portion 800 by the mounting plate engaging mechanism 860. [

The manner in which the conveying device operates in the high-temperature vacuum heat treatment furnace of the present embodiment will be described below with reference to Figs. 9 to 12. Fig.

The main gate 400 of the high temperature vacuum heat treatment furnace is opened and the workpiece 50 is mounted on the mounting plate 600 detachably coupled to the upper surface of the rack gear portion 800 by the mounting plate engaging mechanism 860 . (Fig. 9 (a))

Next, the main gate 400 is closed (Fig. 9 (b)), and the first and second pinion gears 718 and 728 are rotated by the driving force of the motor to move the rack gear portion 800 toward the heating chamber 100 . At this time, it is natural that the barrier gates 300 and the thermal gates 130 are maintained in an open state to prevent collision with the work 50 or the like. The mounting plate 600 is moved along the rack gear portion 800 in a rolling contact with the support roller groups 510 to 540. (Fig. 10 (a))

When the work piece 50 is completely inserted into the accommodating space 40 of the heating chamber 100, the rotation of the first pinion gear 718 is stopped and the rack gear portion 800 is stopped. At this time, whether or not the work 50 is completely inserted can be determined by the rotary encoder 730 described in Fig. 5, a stopper switch (not shown) provided in the heating chamber and the cooling chamber, and the like. (Fig. 10 (b)).

When the lifting mechanism 550 moves the first supporting roller group 510 upward, the mounting plate 600 supported by the first supporting roller group 510 is separated from the rack gear portion 800 The rack gear portion 800 is returned to the cooling chamber 200 by the rotation of the first and second pinion gears 718 and 728. As shown in Fig. (Fig. 11 (b)).

The insulating gate 130 and the blocking gate 300 are closed and the inside of the heating chamber 100 is made into a vacuum or an inert gas state and then the work 50 is heated by a heater Heat it. (Fig. 12)

After the heating is completed, an inert gas is injected into the heating chamber 100 and the cooling chamber 200 to return to the atmospheric pressure state. Then, the heating gate 100 and the shutoff gate 300 To close the cooling chamber 200. [ After the cooling chamber 200 is filled with nitrogen (cooling gas), the workpiece 50 is quenched by spraying nitrogen to the workpiece 50 through the injection port 70.

After the quenching of the workpiece 50 is completed, the cooling gas in the cooling chamber 200 is recovered, returned to the atmospheric pressure state, and then the main gate 400 is opened to recover the workpiece 50, thereby completing the heat treatment. (Fig. 9 (a))

The first and second driving shafts 715 and 725 passing through the heating chamber 100 and the cooling chamber 200 are rotatably closed or the lifting mechanism 550 is installed inside and outside the heating chamber 100, Since the explanation is not necessary, the description thereof will be omitted.

The construction and operation of the present invention have been described above with reference to an embodiment of the present invention. It is to be understood that the scope of the present invention is not limited to the above-described embodiments but is defined by the matters defined in the claims.

10: airtight container 20: heat insulating wall 30: heater 40: storage space
50: work piece 60: heat exchanger 70:
100: heating chamber 110: small gate 120: push-pull member
130: insulating gate 200: cooling chamber 300: blocking gate
400: main gate 510, 520, 530, 540: first, second,
550: lifting mechanism 600: mounting plate 700: motor
710,720: First and second clutch members 715.725: First and second drive shafts
718,728: First and second pinion gears 730: Rotary encoder
800: Rack gear portion 810: Rack gear 820: Support surface
850: rack supporting mechanism 851: guide roller 860: mounting plate engaging mechanism

Claims (4)

A heating chamber provided with a storage space made of a heat insulating wall, a heat insulating gate closing the storage space, and a heater for heating a workpiece in the storage space; A cooling chamber having an ejection port for ejecting a cooling gas; And a shutdown gate for isolating the heating chamber and the cooling chamber from each other. The transfer device transfers the workpiece between the heating chamber and the cooling chamber in the high-temperature vacuum heat treatment furnace,

A mounting plate for mounting the workpiece;
A plurality of support roller groups for supporting the mounting plate;
A lifting and lowering mechanism for moving up and down the mounting plate drawn into the storage space of the heating chamber;

A motor provided outside the high-temperature vacuum heat treatment furnace;
A first drive shaft for driving the first pinion gear provided outside the storage space of the heating chamber;
A second drive shaft for driving a second pinion gear provided in the cooling chamber;
First and second clutch members for transmitting or interrupting the driving force of the motor to the first and second drive shafts, respectively;

A rack gear portion which is engaged with the first pinion gear or the second pinion gear and is conveyed in a conveying direction of the workpiece;
A mounting plate coupling mechanism detachably coupling the upper surface of the rack gear portion and the mounting plate;
A rack support mechanism for supporting the rack gear portion; And a transfer device for transferring the high-temperature vacuum heat-treating furnace.
The method according to claim 1,
Wherein the support roller group provided in the storage space of the heating chamber among the support roller group (groups) operates integrally with the lifting mechanism.
The method of claim 1, wherein
Wherein a rack gear is disposed at the center of the lower surface of the rack gear portion and a support surface is provided at both sides of the rack gear in contact with the rack support mechanism.

The method according to claim 1,
Wherein the movement of the rack gear part is controlled by a sensor for sensing the amount of rotation of the first and second drive shafts or a stopper switch provided in the heating chamber and the cooling chamber, respectively.

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