JP2015017798A - Rotary type heat treatment device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rotary type heat treatment furnace capable of quickly discharging a treated product after heat treatment even without changing a posture of a treatment container and capable of reducing the cycle time.SOLUTION: A rotary type heat treatment device comprises: a cylindrical treatment container 11 having a discharge port 27 for a treated product at one end in the axial direction; a heater 12 for heat treatment of the treated product in the treatment container 11; and a rotary drive part 15 which rotary-drives the treatment container 11 around the axis thereof in both forward and backward directions, and rotary-drives the treatment container 11 in one direction during the heat treatment of the treated product. The treatment container 11 has therein a transfer blade 54 which transfers the treated product to the discharge port 27 by rotation of the treatment container 11 in the other direction.

Description

  The present invention relates to a rotary heat treatment apparatus that heats an object to be processed while rotating a processing container.

  Patent Document 1 below discloses a heat treatment furnace for recycling nuclear fuel pellet scrap (processed object). This heat treatment furnace includes a cylindrical rotary drum that can accommodate an object to be processed and is rotatable around a horizontal axis, a driving device that rotates the rotary drum, and a heater that is disposed around the rotary drum. And an input part for introducing the object to be processed, an extraction part for extracting the object to be processed after the heat treatment, and a connecting part for connecting the input part and the extraction part to the rotating drum.

  The connecting portion is provided at one axial end of the rotating drum, and the charging portion includes a funnel-shaped supply container connected to the upper portion of the connecting portion. On the other hand, the take-out part includes a funnel-like take-out container connected to the lower part of the connection part. The rotating drum has a horizontal posture, a first inclined posture in which the end on the other axial end portion (anti-connecting portion) side is lowered obliquely downward, and a second inclined posture that is raised obliquely upward. The posture can be changed, and the object to be processed is allowed to flow naturally from the supply container to the rotating drum in the first tilted posture, and then heat treatment is performed with the rotating drum in a horizontal posture. The material to be processed after heat treatment is taken out from the container and allowed to flow down naturally into the container.

  Further, the connecting portion is provided with a valve that can be switched between a mode allowing the flow of the workpiece from the supply container to the rotary drum and a mode allowing the flow of the workpiece from the rotary drum to the take-out portion. ing.

JP-A-9-212164

The heat treatment apparatus described in Patent Document 1 heats the object to be processed in the rotating drum, then cools the object by introducing cool air into the rotating drum, and then tilts the rotating drum to remove the object to be processed. It is comprised so that it may discharge to a taking out container.
When the object to be processed is cooled in the rotating drum in this manner, the rotating drum becomes a low temperature at the stage of starting the next heat treatment, and the rotating drum must be heated again from a low temperature state to a predetermined heat treatment temperature. There is a problem that (cycle time) becomes long.

Even if the object to be processed is not cooled in the rotating drum, and the object to be processed is cooled after being discharged from the rotating drum, the posture of the rotating drum is changed to the second inclined posture at the time of discharging, Furthermore, since the object to be treated is allowed to flow naturally due to the inclination, it takes time to completely discharge the object to be treated from the rotating drum, and the temperature of the rotating drum during that time is unavoidable.
In addition, there is a problem that the structure for changing the posture of the rotating drum to the tilted posture is increased in size and complexity, and the cost is increased.

  The present invention has been made in view of the above circumstances, and can quickly discharge the object to be processed after the heat treatment without changing the attitude of the processing container, thereby shortening the cycle time. An object is to provide a possible rotary heat treatment furnace.

A heat treatment apparatus according to the present invention includes a cylindrical processing container having a processing object discharge port at one end in an axial direction, a heating apparatus that heats the processing object in the processing container, and the processing container. A rotational drive unit that is capable of rotationally driving in both forward and reverse directions around an axis, and that rotationally drives the processing container in one direction during heat treatment of the workpiece,
A transfer blade is provided in the processing container to transfer the object to be processed to the discharge port by rotation in the other direction of the processing container.

  The rotary heat treatment apparatus according to the present invention heat-treats an object to be processed by a heating device while rotating a processing container in one direction by a rotation driving unit, and then rotates the processing container in the other direction by a rotation driving unit. Thus, the workpiece can be transferred to the discharge port and discharged from the discharge port. Therefore, compared with the prior art which changes a processing container into the attitude | position which inclined, and to which a to-be-processed material flows down naturally, a to-be-processed object can be discharged | emitted rapidly. Therefore, the temperature drop of the processing container while discharging the workpiece can be reduced, and the cycle time can be shortened. Further, since the transfer blade discharges the object to be processed by the rotation of the processing container by the rotation drive unit, it is not necessary to separately provide a device for driving the transfer blade, and can be configured at low cost.

The transfer blade is preferably formed in a spiral shape that circulates along the inner peripheral surface of the processing container.
With such a configuration, the object to be processed can be pushed back to the anti-discharge port side by rotating the processing container in one direction, and the object to be processed can be transferred by rotating in the other direction.

It is preferable that the processing container is disposed so as to be inclined so that the discharge port side is at a low level.
According to this configuration, the object to be processed can naturally flow to the transfer blade by the inclination of the processing container, and thereafter, the transfer operation can be quickly performed by the transfer blade.

It is preferable that the rotary heat treatment furnace further includes an adjusting unit that adjusts an inclination angle of the processing container.
With this configuration, it is possible to appropriately adjust the inclination angle of the processing container according to the fluidity of the object to be processed.

The rotary heat treatment furnace preferably further includes a cooling device for cooling the heat-treated object discharged from the processing container.
With such a configuration, it is not necessary to cool the object to be processed in the processing container, and after the heat treatment, the object to be processed is immediately discharged, and the next heat treatment can be performed before the temperature of the processing container is reduced so much. .

  According to the present invention, the object to be processed after the heat treatment can be quickly discharged without changing the posture of the processing container, and the cycle time can be shortened.

It is front explanatory drawing which shows the rotary retort furnace as a rotary heat processing apparatus which concerns on embodiment of this invention. It is AA arrow sectional drawing of FIG. It is a perspective view of a spiral blade. It is sectional drawing which expands and shows a rotary joint.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is an explanatory front view showing a rotary retort furnace as a rotary heat treatment apparatus according to an embodiment of the present invention.
The rotary retort furnace 10 supports a retort 11 (processing vessel), a heating device 12 that heat-treats an object to be processed in the retort 11, a support frame 13 that supports the retort 11 and the heating device 12, and the support frame 13. A gantry 14, a rotary drive unit 15 that rotates the retort 11, a vacuum pump 16 that evacuates the retort 11, a supply unit 17 that supplies the retort 11 with an object before heat treatment, and a discharge from the retort 11. And a post-processing unit 18 for receiving and cooling the processed object after the heat treatment.

  The retort 11 is formed in a cylindrical shape, and is supported by the support frame 13 so that its axis O is in the horizontal direction. The retort 11 includes a cylindrical body 20 and a first conical part 21 and a second conical part 22 which are provided at both axial ends of the body 20 and are tapered toward the outer side in the axial direction. I have. Further, the retort 11 is supported so as to be rotatable around the axis O by a pair of support portions 23, 23 having bearings and the like. On the inner peripheral surfaces of the first conical portion 21 and the body portion 20, a stirring blade 24 for stirring the object to be processed is provided.

  The retort 11 further includes a first extension portion 25 and a second extension portion 26 that extend outward in the same direction from the axial outer end portions (small diameter portions) of the first cone portion 21 and the second cone portion 22. The supply portion 17 is connected to one (left side) first extension portion 25, and a discharge port 27 for discharging the workpiece to the outside of the retort 11 at the tip end portion of the other (right side) second extension portion 26. Is formed.

  The heating device 12 includes a furnace body 28 supported by the support frame 13 and a heater 29 provided in the furnace body 28. Inside the furnace body 28, the body part 20, the first conical part 21, and the second conical part 22 of the retort 11 are arranged, and these are heated from the outside by the heater 29, whereby the object to be processed in the retort 11. Is heat treated.

  The support frame 13 that supports the retort 11 and the heating device 12 is supported by the support portion 31 in an inclined posture with respect to the gantry 14 with a predetermined angle α. Therefore, the axis O of the retort 11 is inclined with respect to the horizontal at an angle α, and the discharge port 27 is disposed at a low level. The inclination angle α is set to about 0.1 to 20 ° according to the fluidity of the object to be processed in consideration of the ease of discharging the object to be processed which will be described later. The second conical portion 22 of the retort 11 is disposed such that the lower surface thereof is inclined upward toward the discharge port 27 side.

  The rotation drive unit 15 includes a drive body 33 attached to the support frame 13 and a power transmission mechanism 34 that transmits the power of the drive body 33 to the retort 11. In the present embodiment, an electric motor as the driving body 33 is coupled to the retort 11 via a chain or a sprocket as the power transmission mechanism 34 so that power can be transmitted. In addition, the rotation drive unit 15 is configured to be able to rotate the retort 11 in both forward and reverse directions by using an electric motor that can rotate forward and reverse or by including a transmission device in which the power transmission mechanism 34 can switch between forward and reverse. ing.

The supply unit 17 is connected to a hopper 36 for storing the workpiece, a supply pipe 37 having an upper end connected to the hopper 36, a first opening / closing valve 38 provided in the supply pipe 37, and a lower end of the supply pipe 37. The conveyor device 39 is provided.
The hopper 36 is formed in a downward tapered shape, and has a discharge port and a measuring portion (not shown) at the lower end thereof. The first opening / closing valve 38 allows or blocks the flow of the object to be processed in the supply pipe 37 by opening and closing. A gas seal is provided inside the first opening / closing valve 38, and the airtightness in the retort 11 can be maintained by closing the first opening / closing valve 38. The first opening / closing valve 38 may be configured to automatically open and close by electromagnetic or other types, or may be configured to open and close manually. The supply pipe 37 is disposed in a posture substantially perpendicular to the axis O of the retort 11.

  The conveyor device 39 includes a cylindrical body 41 connected to the lower end of the supply pipe 37 and a conveyor section 42 arranged inside the cylindrical body 41. The cylindrical body 41 includes a flexible pipe 61 and a rotary joint 60. , And is connected to the first extension 25 of the retort 11 so as to be relatively rotatable. The conveyor part 42 is a screw conveyor provided with spiral blades around the rotation axis, and is inserted into the first extension part 25 through the flexible pipe 61 and the rotary joint 60. A drive body 44 such as an electric motor is connected to the rotating shaft through a power transmission mechanism 43 formed of a chain or a sprocket so that power can be transmitted. In addition, the conveyor part 42 can use not only a screw conveyor but another type of conveyor.

  The post-processing unit 18 includes a connection unit 46 connected to the discharge port 27 of the retort 11, a crushing unit 47 connected to the lower part of the connection unit 46, and cooling agitation disposed below the crushing unit 47. A vertical flow pipe 49 connecting the crushing section 47 and the cooling and stirring section 48, and a second opening / closing valve 50 provided in the flow pipe 49.

  The connecting portion 46 is formed in a box shape or a cylindrical shape, and can receive the heat-treated workpiece discharged from the discharge port 27 of the second extension portion 26. Specifically, an opening tube 46 a into which the distal end portion of the second extension 26 is inserted protrudes from the connection portion 46, and the opening tube 46 a is second through the flexible pipe 65 and the rotary joint 64. It is connected to the extension part 26 so as to be relatively rotatable.

  The crushing unit 47 has a function of finely crushing the object to be processed so that the object to be processed solidified in the heat treatment process is not clogged with the flow tube 49. The second opening / closing valve 50 allows or blocks the flow of the object to be processed in the flow pipe 49 by opening and closing. Further, the second on-off valve 50 is provided with a gas seal, and by closing the second on-off valve 50, it is possible to maintain the airtightness in the retort 11.

  The cooling and stirring unit 48 has a function of receiving the processing object finely crushed in the crushing unit 47 through the flow pipe 49 and cooling the processing object while stirring. A processing object take-out unit 51 is provided below the cooling agitation unit 48, and the processing object can be taken out from the take-out unit 51 and collected in a separately prepared collection container 52.

  The vacuum pump 16 is installed on the gantry 14 and is connected to the connection portion 46 via the suction pipe 53. The inside of the retort 11 can be evacuated by driving the vacuum pump 16 with the first opening / closing valve 38 and the second opening / closing valve 50 closed.

  FIG. 4 is an enlarged cross-sectional view of the rotary joint 64. The rotary joint 64 includes a fixed side member 67 fixed to the flexible tube 65 and a rotation side member 66 fixed to the second extension portion 26. The rotation side member 66 extends radially outward from one end (left end) of the cylindrical shaft portion 66a that surrounds the outer periphery of the second extension portion 26, and is provided on the second extension portion 26. And a flange portion 66b that is bolted to the flange portion 26a. A seal member 74 composed of an O-ring for maintaining airtightness is provided between the flange portions 26a and 66b.

  On the other hand, the fixed-side member 67 includes an annular first boss portion 67a and a second boss portion 67b that is bolted to an axial end portion (right end portion) of the first boss portion 67a. The portion 67 b is bolted to a flange portion 65 a provided at the end of the flexible tube 65 via the relay ring 68. Seal members 75 and 76 made of O-rings are provided between the second boss portion 67b and the relay ring 68, and between the relay ring 68 and the flange portion 65a, respectively, for maintaining airtightness. The first boss portion 67a is provided with a water jacket 67c into which cooling water flows.

Two rolling bearings 69 are provided between the inner peripheral surfaces of the first and second boss portions 67a and 67b of the fixed side member 67 and the outer peripheral surface of the shaft portion 66a of the rotation side member 66. The rotation side member 66 and the fixed side member 67 are connected to each other by a rolling bearing 69 so as to be relatively rotatable.
Further, a plurality of seal members 70 are provided between the two rolling bearings 69 between the inner peripheral surface of the first boss portion 67a and the outer peripheral surface of the shaft portion 66a. Is filled with grease.

Further, a pressing plate 73 is fixed to one axial end portion (left end portion) of the first boss portion 67a, and a seal member 71 is provided between the pressing plate 73 and one (left side) rolling bearing 69. Grease is also filled in the arrangement space of the seal member 71. Similarly, a seal member 72 is also provided between the second boss portion 67 b and the other (right side) rolling bearing 69, and the space in which the seal member 72 is disposed is filled with grease. The seal members 70, 71, 72 provided between the rotation side member 66 and the fixed side member 67 and the grease filled in the arrangement space between them are provided between the rotation side member 66 and the fixed side member 67. Gas circulation is prevented, and the vacuum in the retort 11 can be maintained.
In addition, although illustration is abbreviate | omitted, it is set as the structure substantially the same also about the rotary joint 60 (refer FIG. 1) arrange | positioned at the 1st extension part 25 side.

  2 is a cross-sectional view taken along line AA in FIG. 1, and FIG. 3 is a perspective view of a transfer blade. As shown in FIGS. 1 to 3, a transfer blade 54 for transferring an object to be processed to the discharge port 27 is provided inside the retort 11 of the present embodiment. The transfer blade 54 is formed in a spiral shape that circulates along the inner peripheral surface of the retort 11. Further, the transfer blade 54 is provided inside the second conical portion 22 and the second extension portion 26, which are closer to the discharge port 27. A through hole 55 penetrating in the axial direction is formed at the center of the transfer blade 54.

As shown in FIG. 1, the transfer blade 54 provided in the second conical portion 22 has an outer diameter that decreases toward the outer side in the axial direction of the retort 11, and the transfer blade 54 provided in the second extension portion 26. Is formed with a constant outer diameter over the entire length of the second extension 26. Further, the inner diameter of the transfer blade 54 (the diameter of the through hole 55) is constant throughout the transfer blade 54.
The transfer blade 54 acts to push the internal workpiece back to the side opposite to the discharge port 27 when the rotation drive unit 15 rotates the retort 11 forward about the axis O (one direction rotation). When the reverse rotation (rotation in the other direction) is performed, the workpiece is transferred to the discharge port 27 side.

Next, operation | movement of the rotary retort furnace 10 of this Embodiment is demonstrated.
As shown in FIG. 1, the workpiece to be heat-treated is stored in a hopper 36 before the heat treatment is started. By opening the discharge port of the hopper 36 and the first opening / closing valve 38, a predetermined amount of the object to be processed is sent to the conveyor device 39, and further, by operating the conveyor device 39, the object to be processed in the body portion 20 of the retort 11. Is supplied. Further, the inside of the retort 11 is evacuated by a vacuum pump 16.

  When the workpiece is supplied into the retort 11, the retort 11 is rotated forward by the rotation drive unit 15 and the heating device 12 is operated. Thereby, the to-be-processed object in the retort 11 is heat-processed. Since the retort 11 is inclined so that the discharge port 27 side becomes lower, the object to be processed naturally flows toward the discharge port 27 side. However, the retort 11 is pushed back by the transfer blade 54, and further by the stirring blade 24. Stir properly.

  When the heat treatment is finished after a predetermined time has elapsed, the rotation driving unit 15 and the heating device 12 are stopped. Next, the retort 11 is reversely rotated by the rotation drive unit 15 and the crushing unit 47 is operated to open the second opening / closing valve 50. The object to be processed naturally flows down to the vicinity of the second conical portion 22 due to the inclination of the retort 11, and is further transferred to the discharge port 27 by the transfer blade 54 by the reverse rotation of the retort 11. The object to be processed transferred to the discharge port 27 is received by the connecting portion 46 and is finely crushed in the crushing portion 47 and immediately flows down from the vertically arranged flow pipe 49 to the cooling and stirring portion 48. Then, by driving the cooling stirring unit 48, the received workpiece is cooled while being stirred.

  With the above operation, one cycle of processing is completed. And when performing a process continuously, the above-mentioned operation | movement is performed repeatedly. Further, in order to take out the object to be processed from the cooling and agitating unit 48, the recovery container 52 is set at the lower end of the extraction part 51, and the valve 51A is opened to fill the recovery container 52 with the object to be processed.

  In the rotary retort furnace 10 of the present embodiment described above, since the transfer blade 54 is provided in the retort 11, the workpiece can be discharged from the discharge port 27 by the reverse rotation of the retort 11. Therefore, it is not necessary to change the retort 11 to the inclined posture in order to discharge the object to be processed as in the prior art, and the object to be processed can be quickly moved compared to the case where the object to be naturally flowed down by inclination. Can be discharged. Therefore, after one cycle of processing is completed, the time until the next cycle of processing can be shortened, and the temperature drop of the retort 11 during that time can be minimized. Therefore, the cycle time can be shortened and energy consumption can be reduced.

  Further, since the transfer blade 54 acts by the reverse rotation of the retort 11, it is not necessary to separately provide a drive unit for rotating the transfer blade 54. Therefore, an increase in cost associated with the provision of the transfer blade 54 can be minimized.

  Since the retort 11 is disposed so as to be inclined so that the discharge port 27 side is low, the object to be processed can flow naturally to the vicinity of the transfer blade 54, and immediately after the heat treatment, the retort 11 is immediately covered by the transfer blade 54. The processed material can be transferred.

  Moreover, since the to-be-processed object after heat processing is discharged | emitted from the retort 11, it is cooled in the cooling stirring part 48, Therefore It is not necessary to cool a to-be-processed object in the retort 11. Therefore, it is possible to shift to the heat treatment of the next cycle in a short time while maintaining the temperature of the retort 11 at a high temperature.

  Further, since the through hole 55 is formed in the axial center of the transfer blade 54, the transfer blade 54 is less likely to become an air flow resistance when the inside of the retort 11 is evacuated, and the vacuum pump 16 is loaded with low load. And the inside of the retort 11 can be quickly evacuated.

  The present invention is not limited to the above-described embodiment, and can be appropriately changed within the scope described in the claims. For example, in the above-described embodiment, the support frame 13 that supports the retort 11 and the heating device 12 is arranged at a fixed inclination angle α with respect to the gantry 14 by the second support portion 31, but the second support portion 31. The inclination angle α may be adjustable by using a jack device such as a ball jack. In this case, the inclination angle α can be adjusted so that the object to be processed easily flows to the vicinity of the transfer blade 54 in accordance with the fluidity of the object to be processed.

  The heat treatment apparatus of the present invention can also be applied to a heat treatment apparatus for an atmosphere other than vacuum, and in that case, the vacuum pump and the vacuum seal in the above embodiment are not necessary.

10: Rotary retort furnace (rotary heat treatment furnace)
11: Retort (processing container)
12: Heating device 15: Rotation drive part 27: Discharge port 31: 2nd support part (adjustment means)
48: Cooling and stirring unit (cooling device)
54: Transfer blade

A heat treatment apparatus according to the present invention includes a cylindrical processing container having a processing object discharge port at one end in an axial direction, a heating apparatus that heats the processing object in the processing container, and the processing container. A rotational drive unit that is capable of rotationally driving in both forward and reverse directions around an axis, and that rotationally drives the processing container in one direction during heat treatment of the workpiece,
The processing container has a large-diameter portion extending in the axial direction, a conical portion that is provided at an end portion on the discharge port side of the large-diameter portion, and has a smaller diameter toward the discharge port side,
The treatment container is disposed so as to be inclined so that the discharge port side is low, and the lower surface of the conical portion is disposed so as to be inclined upward toward the discharge port side,
A transfer blade is provided in the conical portion to transfer an object to be processed to the discharge port by rotation in the other direction of the processing container.

The rotary heat treatment apparatus according to the present invention heat-treats an object to be processed by a heating device while rotating a processing container in one direction by a rotation driving unit, and then rotates the processing container in the other direction by a rotation driving unit. Thus, the workpiece can be transferred to the discharge port and discharged from the discharge port. Therefore, the processing object can be discharged quickly as compared with the conventional technique in which the processing container is changed to an inclined posture and the processing object flows down naturally. Therefore, the temperature drop of the processing container while discharging the object to be processed can be reduced, and the cycle time can be shortened. Further, since the transfer blade discharges the object to be processed by the rotation of the processing container by the rotation drive unit, it is not necessary to separately provide a device for driving the transfer blade, and can be configured at low cost.
The rotary heat treatment apparatus of the present invention further includes a rotary joint that connects the processing vessel and a fixed side of the rotary heat treatment device so as to be relatively rotatable, and the processing vessel is to be processed more than the discharge port during the heat treatment. The rotary joint is connected to the processing vessel and has a shaft portion extending in the axial direction, and a fixed side of the rotary heat treatment apparatus. A fixed-side member having a boss extending in the axial direction that is connected to the outer side in the radial direction of the shaft portion, and provided between the shaft portion and the boss portion in the radial direction, A bearing that connects the shaft portion and the boss portion so as to be rotatable relative to each other and a radial space between the shaft portion and the boss portion that communicates with the inside of the processing vessel are sealed to maintain a vacuum in the processing vessel. Sealing member It is preferable that example.
It is preferable that a space for allowing a cooling medium to flow is formed in the fixed side member.
The processing container includes a small-diameter portion that extends in the axial direction and extends to the large-diameter portion, and has a smaller diameter than the large-diameter portion, and the rotary joint includes a stationary side of the rotary heat treatment apparatus, the small-diameter portion, and Are preferably connected.
The rotary heat treatment apparatus further includes a connection part that is connected to a discharge port side of the processing container and receives a heat-treated object to be processed, and a valve that can seal the discharge side of the object to be processed in the connection part. It is preferable.

Claims (5)

A cylindrical processing container having a discharge port for a workpiece at one end in the axial direction;
A heating device for heat-treating an object to be processed in the processing container;
A rotational drive unit capable of rotationally driving the processing container in both forward and reverse directions around its axis, and rotating the processing container in one direction during heat treatment of the object to be processed;
A rotary heat treatment apparatus, wherein a transfer blade for transferring an object to be processed to the discharge port by rotation in the other direction of the processing container is provided in the processing container.   The rotary heat treatment apparatus according to claim 1, wherein the transfer blade is formed in a spiral shape that circulates along an inner peripheral surface of the processing container.   3. The rotary heat treatment apparatus according to claim 1, wherein the processing container is disposed so as to be inclined so that the discharge port side is at a low level.   The rotary heat treatment apparatus according to claim 3, further comprising adjustment means for adjusting an inclination angle of the processing container.   The rotary heat treatment apparatus according to any one of claims 1 to 4, further comprising a cooling device that cools the heat-treated object discharged from the treatment container.

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