JP2015218367A - Vacuum hardening treatment equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide vacuum hardening treatment equipment with a gas cooling chamber where cooling capacity is sufficiently reduced as possible if required, a temperature difference at the inside and outside parts of a workpiece is reduced as possible, and marquenching treatment of reducing the stain of the workpiece is possible.SOLUTION: A plurality of vacuum heating chambers 2A to 2D and a carrying device 3 charging/discharging a workpiece W to the vacuum heating chambers are stored in an enclosure 1 in which one end is opened, and a gas cooling chamber 4 is air-tightly connected to the open part of the enclosure. Cool water fed to the heat exchanger 5 of the gas cooling chamber 4 is exhausted by air purge to drop its cooling capacity, and further, hot water is fed to temporarily reduce the cooling capacity of the heat exchanger 5.

Description

  The present invention relates to a vacuum quenching treatment facility, and more particularly to a vacuum quenching treatment facility capable of appropriately controlling a gas cooling capacity.

  Patent Document 1 discloses a plurality of carburizing chambers (vacuum heating chambers) arranged in the vertical direction, a vertical lift device that can move a processed product to these carburizing chambers, and a cooling chamber that cools the processed product after carburizing. A compact vacuum carburizing and quenching treatment facility is shown.

Special table 2013-504686

  In the above-described quenching processing equipment, a plurality of workpieces are arranged on a grid-like tray in a single step so as to be quenched. The attached gas cooling chamber is equipped with a cooling gas flow guide, and appropriately controls the pressure, flow velocity, wind direction, etc. of the cooling gas with respect to the work arranged in one stage, as compared with the conventional multistage processing equipment. Realizes reduction and equalization of the distortion of each workpiece.

  By the way, in order to further reduce the distortion of the workpiece, quenching is performed so that it does not cause pearlite nose, and is held for a certain period of time at a temperature just above the martensite transformation point so as to eliminate the temperature difference between the inside and outside of the workpiece, and then cooled. Is done. However, when obtaining sufficient cooling capacity, it is difficult to control the cooling capacity to be small, and there is a problem that a temperature difference between the inside and outside of the workpiece is unavoidable.

  Therefore, the present invention has been made in view of such a demand, and can perform a marquenching process that sufficiently reduces the cooling capacity when necessary to reduce the temperature difference between the inside and outside of the work as much as possible and reduce the distortion of the work. It aims at providing the vacuum hardening processing equipment provided with the gas cooling chamber.

  In order to achieve the above object, according to the first aspect of the present invention, a plurality of vacuum heating chambers (2A to 2D) and a transfer device (3) for taking a workpiece (W) into and out of the vacuum heating chamber are opened at one end. In a vacuum quenching treatment facility in which the gas cooling chamber (4) is housed in the body (1) and the gas cooling chamber (4) is connected in an airtight manner to the open portion of the casing (1), the cooling capacity of the gas cooling chamber (4) is increased when necessary Means for reducing (2D, 45, 46, 52, 53, 61, 62, 63, 71, 75, 76, 81, 82, 84, 85, 86, 9) are provided.

  In the first aspect of the present invention, by providing means for reducing the cooling capacity of the gas cooling chamber when necessary, sufficient cooling capacity is exhibited during rapid cooling, while the cooling capacity is sufficiently reduced immediately above the transformation point. The marquenching process can be performed by reducing the temperature difference between the inside and outside of the work as much as possible.

  In the second aspect of the invention, the means for reducing the cooling capacity stops the supply of the refrigerant to the heat exchange member (5) of the gas cooling chamber (63).

  In the third aspect of the present invention, the means for reducing the cooling capacity is such that one of the plurality of vacuum heating chambers (2A to 2D) is a low temperature heating chamber (2D) having a relatively low temperature, and gas cooling is performed when necessary. The workpiece (W) is transferred from the chamber (4) to the low temperature heating chamber (D).

  The reference numerals in the parentheses indicate the correspondence with specific means described in the embodiments described later.

  As described above, according to the vacuum quenching processing equipment of the present invention, while exhibiting sufficient cooling capacity, when necessary, the cooling capacity is sufficiently reduced to reduce the temperature difference between the inside and outside of the work as much as possible. Marquenching treatment can be performed to reduce the distortion.

It is a whole schematic block diagram of the vacuum hardening apparatus in 1st Embodiment of this invention. It is a schematic side view of a conveying apparatus. It is a figure which shows the piping path | route of a heat exchanger. It is a figure which shows the time-dependent change of workpiece | work temperature. It is a schematic sectional drawing of the gas cooling chamber in 2nd Embodiment of this invention. It is a schematic sectional drawing of the gas cooling chamber in 3rd Embodiment of this invention. It is a schematic sectional drawing of the gas cooling chamber in 4th Embodiment of this invention. It is a schematic sectional drawing of the gas cooling chamber in 5th Embodiment of this invention.

(First embodiment)
FIG. 1 shows an embodiment of the present invention. In FIG. 1, the vacuum quenching treatment equipment includes a housing 1 that is open at one end, and a plurality of (four in this embodiment) vacuum heating chambers (four in this embodiment) in the longitudinal half of the closed side. 2A to 2D (hereinafter simply referred to as heating chambers) are provided, and a vertical lift 3 is installed as a transfer device in the longitudinal half of the housing 1 on the open side. Each of the heating chambers 2A to 2D is provided with a heater so that the temperature in the heating chamber can be raised to a predetermined temperature, and a vacuum exhaust pipe is connected to each of the heating chambers 2A to 2D so that the heating chamber is predetermined. The degree of vacuum can be maintained. Furthermore, a carburizing gas supply pipe such as acetylene is connected to the heating chambers 2A to 2D so that carburizing treatment can be performed. Each heating chamber 2A-2D can be opened and closed on the side facing the vertical lift 3 by a gate valve (not shown).

  The vertical lift 3 has the same structure as that described in Patent Document 1 (Special Table 2013-504686). That is, as shown in FIG. 4, the vertical lift 3 includes a pair of left and right chains 311, 312 erected in the vertical direction, and a horizontal platform 313 is mounted on the chain 312. A gear mechanism 33 is provided on the platform 313, and the input side of the gear mechanism 33 is connected to the chain 311. On the platform 32, fork bodies 34, 35 that are extendable in two stages in the lateral direction are disposed. These fork bodies 34, 35 are connected to the output side of the gear mechanism 33 and driven to extend and contract. It is like that.

  For example, a plurality of workpieces are arranged on a grid-like tray in a planar shape and placed on the fork body 35. When the workpiece is conveyed in the vertical direction, both chains 311 and 312 are operated simultaneously to raise and lower the platform 313 to a position facing the predetermined heating chambers 2A to 2D. Thereafter, the chain 312 is stopped, only the chain 311 is operated, the forks 34 and 35 are extended to the side via the gear mechanism 33, and the tray on which the workpiece is placed is inserted into the heating chambers 2A to 2D. Or the tray which mounted the workpiece | work after a process is taken out from heating chamber 2A-2D. The forks 34 and 35 can be extended into a gas cooling chamber 4 to be described later.

  In FIG. 1, a gas cooling chamber 4 is coupled to the open portion of the housing 1. The gas cooling chamber 4 is connected to a vacuum exhaust pipe and a gas supply pipe such as nitrogen. An agitating fan 42 that is rotated by a drive motor 41 is provided at the ceiling of the gas cooling chamber 4, and left and right flow guides 43 and 44 that extend symmetrically in the vertical direction are disposed below the stirring fan 42. The heat exchanger 5 is disposed at an upper position between the guides 43 and 44. The workpiece W is inserted between the flow guides 43 and 44 below the heat exchanger 5. As shown by the arrow in FIG. 1, the gas in the gas cooling chamber 4 flows downward between the flow guides 43, 44 by the stirring fan 42, and then reverses and passes through the outside of the flow guides 43, 44 again. To be circulated. A vacuum door 11 is provided at the opening between the housing 1 and the gas cooling chamber 4, and a vacuum door 12 is provided at the work loading opening of the gas cooling chamber 4.

  In this embodiment, as shown in FIG. 3, a pipe 51 is connected to the inlet side of the heat exchanger 5, and the pipe 51 branches into three on the way, and electromagnetic valves 61, 62, A normal temperature air supply pipe 52, a hot water supply pipe 53, and a cold water supply pipe 54 are connected through 63. A discharge pipe 55 is connected to the outlet side of the heat exchanger 5. The solenoid valves 61 to 63, the air supply pipe 52, and the hot water supply pipe 53 constitute a cooling capacity reducing means.

  In this embodiment, after performing a predetermined heat treatment in the vacuum heating chambers 2A to 2D, the work W is inserted into the gas cooling chamber 4, the electromagnetic valve 63 is opened, and cold water is supplied to the heat exchanger 5 to circulate the wind. Is sufficiently lowered to rapidly cool the workpiece W (A region in FIG. 4). During this rapid cooling, the temperature (line x) of the surface layer portion of the workpiece W becomes lower than the temperature (line y) of the central portion, resulting in a temperature difference.

  Therefore, when the temperature of the workpiece W has dropped to a position just above the martensitic transformation point, the electromagnetic valve 63 is closed, the electromagnetic valve 61 is opened, and cold water is discharged by air purge to lower the cooling capacity. Further, the electromagnetic valve 62 is opened to supply hot water to temporarily reduce the cooling capacity of the heat exchanger 5. Thereby, the temperature of the surface layer part and center part of the workpiece | work W approachs gradually (B area | region of FIG. 4), and there is almost no temperature difference inside and outside. Thereafter, the electromagnetic valve 62 is closed, the electromagnetic valve 61 is opened, hot water is discharged by air purge, the electromagnetic valve 63 is opened again, and cooling water is supplied to the heat exchanger 5 to perform cooling again (in FIG. 4). C region). In this way, the marquenching process can be performed.

(Second Embodiment)
A second embodiment of the present invention is shown in FIG. In the first embodiment, the heat exchanger 5 is positioned above the workpiece W. However, in this embodiment, the positions of the workpiece W and the heat exchanger 5 are switched up and down. In FIG. 5, bypass openings 431 and 441 are provided on the guide surfaces of the left and right flow guides 43 and 44 positioned below the region where the workpiece W is inserted above the heat exchanger 5, and these openings 431 and 441 are provided. Opening and closing doors 45 and 46 are installed in the door. FIG. 5 shows a state in which the opening and closing doors 45 and 46 are opened, and the opening doors 45 and 46 can rotate around the lower end to close the openings 431 and 441 as indicated by a chain line in the figure. In the present embodiment, the heat exchanger 5 is supplied with a refrigerant such as cold water to be a cooler.

  In the lower end opening 47 between the flow guides 43 and 44, a closing plate 71 having the same shape as the opening shape is disposed. The center of the lower surface of the closing plate 71 is fixed to the tip of a rod 73 extending in the vertical direction of an elevating cylinder 72 provided on the bottom wall of the gas cooling chamber 4, and a flow guide 43 as shown by a solid line in FIG. , 44 is closed by the lifting cylinder 72 from the closed state, and the opening 47 can be opened as shown by the chain line. Other structures are the same as those in the first embodiment. The open / close doors 45 and 46 and the closing plate 71 constitute cooling capacity reducing means.

  In this embodiment, the openings 431 and 441 are closed by the opening and closing doors 45 and 46, and the opening 47 is opened by lowering the closing plate 71 (chain line in FIG. 5), which is described in the first embodiment. In the same manner as described above, the work W is rapidly cooled by the circulating cooling air. After the temperature of the workpiece W has dropped to the position just above the transformation point, it is necessary to reduce the cooling capacity in order to maintain the temperature of the workpiece W and reduce the temperature difference between the inside and outside. 46 is opened and the closing plate 71 is raised to close the opening 47 (solid line in FIG. 5). As a result, the cooling air changes its direction at a position directly above the heat exchanger 5 and flows out of the flow guides 43 and 44 from the openings 431 and 414, and hardly flows in the direction of the heat exchanger 5. Accordingly, the surface layer portion of the workpiece W is not excessively cooled, and the temperature difference between the surface layer portion and the center portion of the workpiece W gradually approaches and the temperature difference is almost eliminated. Thereafter, the openings 431 and 441 are closed again by the opening and closing doors 45 and 46, and the closing plate 71 is lowered to open the opening 47 to cool the workpiece. According to this embodiment, the same effect as that of the first embodiment can be obtained.

(Third embodiment)
This embodiment is shown in FIG. In the present embodiment as well, the workpiece W is positioned above the heat exchanger 5 as in the second embodiment. In FIG. 6, an external duct 74 is provided, and the lower end of the external duct 74 passes through the side wall of the gas cooling chamber 4 and opens to the guide surface of the flow guide 44 that is located above the heat exchanger 5 and below the work W. At the same time, the upper end of the external duct 74 is opened to the side wall of the gas cooling chamber 4 outside the flow guide 44. The external duct 74 is provided with an opening / closing valve 75 and a heating device 76 on the way. A closing plate 71 having the same structure as that of the second embodiment is provided in the lower end opening 47 between the flow guides 43 and 44. In this embodiment, the closing plate 71, the on-off valve 75, and the heating device 76 constitute cooling capacity reducing means.

  In the present embodiment, when the closing plate 71 is lowered and the opening 47 is opened, the workpiece is rapidly cooled as in the second embodiment. On the other hand, when the on-off valve 75 is opened in the state where the closing plate 61 is raised and the opening 47 is closed as shown in FIG. 6, the cooling gas that has passed through the workpiece W is directed at a position directly above the heat exchanger 5 that functions as a cooler. However, it hardly flows into the heat exchanger 5, flows into the external duct 74, is warmed by the heating device 76 on the way, and is returned upward in the gas cooling chamber 4. Thus, the surface layer portion of the workpiece is not excessively cooled, and the temperature difference between the surface layer portion and the center portion of the workpiece gradually approaches and the temperature difference is almost eliminated. In this case, the supply of the refrigerant to the heat exchanger 5 may be stopped. Thereafter, the closing plate 71 is lowered again and the on-off valve 75 is closed to cool the workpiece. According to this embodiment, the same effect as that of the first embodiment can be obtained.

(Fourth embodiment)
FIG. 7 shows a fourth embodiment of the present invention. In this embodiment, the chamber wall of the gas cooling chamber 4 is a water jacket 8 which is a double wall heat exchange member. Although not shown, a stirring fan and a flow guide are provided in the gas cooling chamber 4 so that the work is cooled by circulating air generated by the stirring fan.

  In the present embodiment, an air supply pipe 81, a hot water supply pipe 82, and a cold water supply pipe 83 are connected to the water jacket 8 via electromagnetic valves 84, 85, and 86, respectively. The electromagnetic valves 84 to 86, the air supply pipe 81, and the hot water supply pipe 82 constitute cooling capacity reducing means. A discharge pipe 87 is also connected to the water jacket 8.

  In this embodiment, after performing a predetermined heat treatment in the vacuum heating chambers 2A to 2D (see FIG. 1) in the housing 1, a work is loaded into the gas cooling chamber 4, the electromagnetic valve 86 is opened, and the water jacket 8 is opened. Cold water is supplied to the chiller to sufficiently reduce the temperature of the circulating air, and the workpiece is rapidly cooled. When the temperature of the workpiece is lowered to the position just above the transformation point, the solenoid valve 86 is closed, the solenoid valve 84 is opened, and cold water is discharged by air purge to lower the cooling capacity. Further, the electromagnetic valve 85 is opened and hot water is supplied to temporarily reduce the cooling capacity of the gas cooling chamber 4. As a result, the temperatures of the surface layer portion and the center portion of the workpiece gradually approach each other, and the temperature difference between the inside and outside is almost eliminated. Thereafter, the electromagnetic valve 85 is closed, the electromagnetic valve 84 is opened, hot water is discharged by air purge, the electromagnetic valve 86 is opened again, and cooling is performed by supplying cold water to the water jacket 8. In this way, the marquenching process can be performed.

(Fifth embodiment)
In the present embodiment, as shown in FIG. 8, a sheathed heater 9 is installed around the chamber wall of the gas cooling chamber 4 as a cooling capacity reducing means. The configuration inside the gas cooling chamber 4 not shown is basically the same as that of the first embodiment, but the heat exchanger 5 (see FIG. 1) is supplied with a refrigerant such as cold water to become a cooler. .

  In such a configuration, the workpiece heated in the heating chambers 1 </ b> A to 1 </ b> D in the housing 1 is rapidly cooled in the gas cooling chamber 4 by circulating cooling air. After the temperature of the workpiece has decreased to a position just above the transformation point, it is necessary to reduce the cooling capacity in order to reduce the temperature difference between the inside and outside of the workpiece. In this case, supply of the refrigerant to the heat exchanger 5 is stopped. At the same time, the sheath heater 9 is energized to warm the entire gas cooling chamber 4 to prevent the surface layer of the workpiece from being excessively cooled. Note that the refrigerant supply to the heat exchanger 5 is not necessarily stopped. Thereby, the temperature of the surface layer portion and the center portion of the workpiece gradually approaches, and the temperature difference is almost eliminated. Thereafter, the energization to the sheathed heater 9 is stopped, the refrigerant is supplied to the heat exchanger 5, and the work is cooled again. According to this embodiment, the same effect as that of the first embodiment can be obtained.

(Sixth embodiment)
In the present embodiment, of the plurality of heating chambers 2A to 2D provided in the housing 1, the temperature of one heating chamber 2D is a temperature in the vicinity of just above the transformation point that is sufficiently lower than the other heating chambers 2A to 2C. The main heating chamber 2D is used as a cooling capacity reducing means as a low temperature heating chamber (for example, 300 ° C.) maintained at a low temperature. In this case, the configuration in the gas cooling chamber 4 is basically the same as that of the first embodiment, but the heat exchanger 5 (see FIG. 1) is a cooler supplied with a refrigerant such as cold water.

  In the present embodiment, the workpiece heated in the heating chambers 2A to 2C is rapidly cooled by the circulating cooling air in the gas cooling chamber 4, and a temperature difference is generated between the surface layer portion and the center portion of the workpiece. After the temperature of the workpiece has decreased to a position just above the transformation point, the workpiece is transferred to the heating chamber 2D that is a low-temperature heating chamber. Since the heating chamber 2D is previously held at a low temperature by a heater, the temperatures of the surface layer portion and the center portion of the workpiece gradually approach each other, and there is almost no temperature difference between the inside and outside. Thereafter, the work is cooled again in the gas cooling chamber 4. Note that the heater of the heating chamber 2D can be turned off, or a standby chamber other than the heating chamber can be used as the cooling capacity reducing means. According to this embodiment, the same effect as that of the first embodiment can be obtained.

  2D ... Heating chamber (cooling capacity reducing means), 45, 46 ... Opening / closing door (cooling capacity reducing means), 5 ... Heat exchanger (heat exchange member), 52 ... Air supply pipe (cooling capacity reducing means), 53 ... Hot water Supply pipe (cooling capacity reducing means), 61, 62, 63 ... Solenoid valve (cooling capacity reducing means), 71 ... Closing plate (cooling capacity reducing means), 75 ... Opening / closing valve (cooling capacity reducing means), 76 ... Heating device (Cooling capacity reduction means), 8 ... water jacket (heat exchange member), 81 ... air supply pipe (cooling capacity reduction means), 82 ... hot water supply pipe (cooling capacity reduction means), 84, 85, 86 ... solenoid valve ( Cooling capacity reduction means), 9 ... sheathed heater (cooling capacity reduction means).

Claims (3)

A vacuum quenching treatment facility in which a plurality of vacuum heating chambers and a transfer device for taking workpieces into and out of the vacuum heating chambers are housed in a casing that is open at one end, and a gas cooling chamber is hermetically connected to the open portion of the casing. And a means for reducing the cooling capacity of the gas cooling chamber when necessary. The vacuum quenching treatment facility according to claim 1, wherein the means for reducing the cooling capacity is to stop the supply of the refrigerant to the heat exchange member of the gas cooling chamber when necessary. The means for reducing the cooling capacity is one in which one of the plurality of vacuum heating chambers is a low temperature heating chamber having a relatively low temperature, and a work is transferred from the gas cooling chamber to the low temperature heating chamber when necessary. Item 2. The vacuum quenching treatment facility according to Item 1.

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