JPS6338884A - Thermal treatment equipment - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to the structure of a heat treatment apparatus that heats a material to be heat treated. This invention relates to a heat treatment apparatus having a reciprocating heat treatment process.

[Prior art] As a conventional heat treatment apparatus of this type,
The technique described in Japanese Patent No. 610 can be mentioned.

FIG. 5 is a horizontal sectional view of the entire conventional heat treatment apparatus, FIG. 6 is a vertical sectional view of the main part of the heat treatment apparatus as seen from the front, and FIG. 7 is a vertical sectional view of the same as seen from the side of the heat treatment apparatus. .

In the figure, a heat treatment apparatus main body 1 has an outer shell made up of a refractory lining 2 and a surrounding heat insulating layer 3. Bulkhead 1
It is located in the center of the heat treatment apparatus main body 1, and forms an outward path 5, a direction change path 6, and a return path 7 within the heat treatment apparatus main body 1. The tracks of the outbound route 5 and return route 7 consist of a combination of two rails 9.11 supported by support legs 8 and a number of trochanters 12.14, and the vL path of the direction change route 6 is shown in FIG. As seen in the figure, a board 10 placed on the floor-L and a number of spheres 1
It consists of 3 combinations. As a whole, it forms a substantially U-shaped trajectory.

The upper ends of the trochanters 12 and 14 and the upper ends of the sphere 13 are set on the same plane. Each of the trays 5Q supported by the trochanters 12.14 has a main body 51 and a vertical wall 5 having two grooves 52 on their lower surfaces with a width equal to the width of the rails 9.11.
It consists of 3.

The groove 52 is formed between the upper ends of the rails 9 and 11 and the trochanter 12°14.
1 to 50 supported by the trochanters 12 and 14 can be transferred without touching the rails 9 and 11. The tray 50 supported by the sphere 13 in the direction changing path 6 can also be transferred without touching the board 10.

Two sets of pushers 15 and 18 are arranged at the rear of the heat treatment apparatus main body 1. This pusher 15.1
8 consists of a combination of a piston rod 16.19 that penetrates the furnace wall and a cylinder 17.20, and is set so that after the pusher 18 located on the forward path 7 side is activated, the pusher 15 located on the forward path 5 side is activated. ing.

Electric heating devices 21 are installed on the floor between the support legs 8 on the outbound path 5 and the return path 7, each extending in a direction across the path, and three electric heating devices 22, 23 are installed on the ceiling, extending parallel to the path. fan 2 is placed on the ceiling of that area.
4.29 is provided. The fan 24.29 is
The belt 28.3 from the electric fi 27.32 mounted on the roof is attached to the vertical lNl 25,30 supported on the bearing jackera 1-26.31 of the water cooling gutter.
3 to stir the atmosphere.

The conventional in-furnace conveyance device configured as described above operates as follows.

The heat-treated materials to be heat-treated are sequentially placed on a tray 50 in the front chamber 40, and are sequentially transferred into the heat treatment apparatus main body 1 by a distance equal to the length of the tray 50. The heat-treated material placed on the tray 50 is gradually heated in the heat exchange chamber 41 and sent to the heating/soaking chamber 42, where it is heated to a predetermined temperature. When the heat-treated material placed on the tray 50 reaches the direction changing path 6, the tray 50 is transferred to the return path 7 side by the piston rod 16 of the pusher 15. At this time, the tray 50 that has reached the return path 7 side of the direction change path 6 is transferred to the return path 7 by the piston rod 19 of the pusher 18 and becomes empty. Therefore, the tray 50 that has come to the return path 7 side of the direction change path 6 can be sent to the return path 7 by the piston rod 19 of the pusher 18.

Tray 50 sent to return path 7 by piston rod 19
The heat-treated material placed thereon reaches the heat exchange chamber 44 while being heated in the heating/soaking chamber 43, where it is gradually cooled and reaches the cooling chamber 45. In this way, the heat treatment of the material to be heat treated is performed.

[Problems to be Solved by the Invention] However, in the conventional heat treatment apparatus described above, the partition wall 4 is located in the center of the heat treatment apparatus main body 1, and the partition wall 4 is located in the center of the heat treatment apparatus main body 1. 7 is formed. In other words,
In the case of the configuration shown in the plan view schematically explaining the overall layout of the heat treatment apparatus in FIG. 8, there are , heat exchange chamber F, cooling chamber G, and rear end l'', except for the direction change chamber, heat exchange chamber B, and heat exchange chamber F, the forward path 5 and return path 7 are independent (as shown) or partition wall 4 (as described above). According to the prior art example, the outbound route 5 and the return route 7 are separated in the longitudinal direction. Further, the heat exchange chamber B and the heat exchange ffF are connected by an atmosphere circulation duct.

At this time, the length [X] of the stirring claw unit in the width direction of the forward path 5 and return path 7 in the direction of the length of the furnace is as follows: By design,
' It is necessary to reduce the directivity of Y to a predetermined value J:.

That is, when the value of X/Y becomes large, there is a problem that temperature unevenness occurs and the desired temperature cannot be achieved.

Furthermore, the partition wall 4 is located in the center of the heat treatment apparatus main body 1, and thermal energy is consumed by the partition wall 4, resulting in a problem that the running cost of the furnace is high. In particular, since the partition wall 4 was disposed approximately along the length of the heat treatment apparatus main body 1,
There was also the problem that the heat treatment equipment itself was expensive.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and aims to provide a heat treatment apparatus that equalizes the temperature distribution in the furnace, reduces heat loss, and reduces running costs.

[Means for Solving the Problems] The heat treatment apparatus according to the present invention includes a heat treatment apparatus main body consisting of a heat treatment target material transport path arranged in parallel, and a heat treatment target material 11F.
a conveyance means for conveying the heat-treated material disposed in the second conveyance path;
It must be equipped with a partition wall that separates the heat treatment apparatus main body from the heat treatment material transport paths arranged in parallel, and is arranged in a part of the length direction of the heat treatment material transport paths arranged in parallel. .

[Function] In the present invention, the partition wall that separates the heat treatment apparatus main body consisting of the heat treatment material transport paths arranged in parallel from the heat treatment material UN transport path arranged in parallel is connected to the heat treatment material transport path. Since the partition wall is installed in a part of the length direction, in the heat treatment material conveyance path where the heat treatment equipment main body is arranged side by side and the partition wall is not installed,
Length [X] of the conveyance path of the material to be heat treated in the longitudinal direction of the furnace and heat treatment! , [the ratio to the furnace width [Y] perpendicular to the direction of the feeding path is
By doubling the furnace width [Y], X/Y can be made smaller, and as a result, the temperature distribution inside the furnace can be improved. In addition, it is equipped with a partition wall disposed in a part of the length direction of the heat-treated material conveyance path to separate the heat treatment apparatus main body from the heat-treated material conveyance path arranged in parallel. Since the partition walls may be shorter than those provided with partition walls, there is less heat loss, and running costs can be reduced and the heat treatment apparatus itself can be made inexpensive.

[Example] Fig. 1 is a plan view illustrating the overall layout of a heat treatment apparatus according to an embodiment of the present invention, and Fig. 2 is a plan view showing a direction changing path in a heating/soaking chamber according to an embodiment of the present invention. FIG. 3 is a vertical sectional view of the main part when cut in parallel, and FIG. 3 is a horizontal sectional view of the main part when cut parallel to the direction changing path in the heating/soaking chamber of an embodiment of the present invention. .

In Fig. 1, the structure of the heat treatment apparatus main body 100 is basically the same as that of a conventional furnace main body, and the material to be heat treated is transferred to a front space J and a heat exchange chamber to a heating/soaking chamber. an outbound path 200 of the parallel heat-treated material conveyance path, a return path 300 of the other heat-treated material conveyance path that transports the heating/soaking process, heat exchange chamber P, cooling chamber Q, and rear chamber R, and an outbound path. 200
and the return route 300. The heating/soaking and heating/soaking ZN are provided with stirring layers 1n, 2n, 3n, 4n, 5n, and 5n. In addition, there is a stirring layer 1F in the heat exchange chamber K and heat exchange WP)
, 2D, 31), the cooling constriction Q is provided with stirring layers 1Q and 2Q. Note that a partition wall 112 is provided between the heating/soaking chamber and the stirring layers 1n and 2n of the heating/soaking room N. By the way, the heating/soaking chamber and the heating/soaking chamber N of the heat treatment apparatus in the embodiment shown in FIG.
Shown in the heating/soaking room in the figure.

In FIGS. 2 and 3, the direction converter M at the heating/soaking chamber side end of the outward path 200 and the heating/soaking chamber N side end of the return path 300 has a direction changing path 400. There is. The outbound route 200 and the return route 300 include the outbound route 200 and the return route 3.
It has a roll shaft 120 having a large diameter part 120a and a small diameter part 120b, which are rotated by a roll drive transmission means 210 or 310, which transfers a heat-treated material 110 in the length direction of the roll shaft 120. Roll drive motor 2
11 and the roll drive transmission means 210 or the roll drive motor 311 and the roll drive transmission means 312 are attached to the motor mount 212 or the motor mount 310, and the roll drive transmission means 210 or the roll drive transmission means 310 is It is driven by a drive motor 211 or a roll drive motor 311. Similarly, the direction change path 400 includes a roll drive transmission means 4 for transporting the heat-treated material 110 in the length direction of the i main path 200 and the return path 300.
11 or a roll shaft 4 having a large diameter portion 420a and a small diameter portion 420b rotated by the roll drive transmission means 412.
It has 20. The roll drive transmission means 411 or the roll drive transmission means 412 includes a roll drive motor 43.
1 or a roll drive motor 432.

The roll drive motor 431 and roll drive transmission means 4
11 or the roll drive motor 432 and the roll drive transmission means 412 are attached to the motor mount 441 or the motor mount 442, and are respectively attached to the heat treatment apparatus main body 100.
It is disposed outside the furnace wall 130 of the direction changing path 400. The motor mount 441 or the motor mount 442 is rotated by a jack drive motor 450, and is moved vertically up and down.
2 shirts 1 to 453.454. Drive input shaft side 1; 1 of the plurality of jatsugi 451.452
They are connected by a connecting shaft 455 to equalize the lifting and lowering positions of the shirts 1-453 and 454 of the plurality of jacks 451 and 452. The jack 451 is mounted firmly on the base of the heat treatment apparatus main body 100.
Similarly, the jack drive motor 450 and the jack 452 are attached to the jack drive morph number stand 458.

Therefore, the jack drive motor 450
1,452 shafts 453, 454 are moved up and down, the motor mounting bases 441, 442 are moved up and down, and the plurality of direction changing paths 400 whose both ends are connected to the roll drive transmission means 411 and the roll drive transmission means 412 are moved up and down. The roll shaft 420 is moved up and down.

Therefore, the tray 111 and the heat-treated material 110 placed on the plurality of roll shafts 420 of the direction changing path 400 move up and down on the plurality of roll shafts 420.

Between the plurality of roll shafts 420 of the direction changing path 400, a plurality of endless chain conveyors 471, 472° 473 are operated by a transfer main gear 461 and a transfer main gear 462.
It is arranged parallel to the roll axis 420. Furthermore,
Endless chain conveyors 471, 472, 473 are connected to guide gears 463, 464 and auxiliary gears 465, 466, 467
．． 468 and tension gear 469,
Tension gear 469 is biasing means 460 such as a spring.
Accordingly, each endless chain conveyor 471, 472, 473
Tension is applied to.

The plurality of endless chain conveyors 471, 472° 473
is located below the horizontal line 4208 of the large diameter portion of the plurality of roll shafts 420 of the direction changing path 400 when the motor mounting bases 441, 4.42 are raised. Also, when the motor mounting base 441, 442 is lowered, the direction change path 40
The horizontal line 4208 of the large diameter portion of the plurality of roll shafts 420 of 0 corresponds to the plurality of endless chain conveyors 471, 472, 473.
located below the top of the

The shaft of the transfer main gear 461 is connected to a conveyor drive motor 480 attached to a motor mount 481, and the rotation of the conveyor drive motor 480 causes the endless chain conveyor 471°472.473 to move along the outward path 20.
0 in the direction of the return route 300.

In addition, the length of the forward path 200 in the direction of the furnace arm [X] in this embodiment
And, the oven width [Y] perpendicular to the length direction of the outgoing path 200 is such that at the location where the partition wall 112 is present, the oven width [Y] is
12 and the width of the furnace wall 130 facing it, and the partition wall 11
2 does not exist, the oven width [Y] is the width of the opposing oven wall 130. In addition, the furnace width perpendicular to the length direction of the forward path 200 [Y is the stirring claws 1n, 2n, 3n, 4n,
The units are 5n, 6n, or stirring claws 1p, 2p, and 3p.

The heat treatment apparatus of this embodiment configured as described above can operate as follows.

First, the shafts 453 and 454 of the jacks 451 and 452 are raised by the rotation of the jack drive motor 450, the motor mounting bases 441 and 442 are raised, and the direction changing path 400 is moved by the roll drive transmission means 411 and the roll drive transmission means 412. The plurality of roll shafts 420 are raised.

At this point, a plurality of endless chain conveyors 471, 472,
The top of 473 is located below the horizontal line 4208 of the large diameter portion of the plurality of roll shafts 420 of the direction conversion path 400, and does not come into contact with the tray 111 on which the heat-treated material 110 is placed.

Then, due to the rotation of the roll shaft 120, the heat-treated material 110 placed on the tray 111, which has been transferred from the front to the front J, the heat exchange chamber K, and the heating/soaking chamber, is transferred from the forward path 200 to the direction change path 40.
Move in the direction of 0. When it moves onto the roll shaft 420 of the direction change path 400, it is detected by a detection means (not shown), and the roll drive motor 431 moves onto the roll shaft 42Q.
stop rotating. At this time, the material to be heat treated 110 is on the roll shaft 420 of the direction changing path 400.

In this state, the jack drive motor 450 is rotated to simultaneously drive the plurality of jacks 451 and 452. and,
The shirts 1 to 453 and 454 are lowered, and the motor mounting bases 441 and 442 are lowered.

Therefore, the plurality of roll axes 420 of the direction changing path 400
is lowered, and at this time, the lowering position of the roll shaft 420 is set so that the horizontal line 4208 of its large diameter portion is located below the top of the plurality of endless chain conveyors 471, 472° 473. Therefore, the heat-treated material 110 on the roll shaft 420 of the direction changing path 400 is transferred onto the plurality of endless chain conveyors 471, 472, 473 of the direction changing path 400.

A plurality of endless chain conveyors 471 of the direction change path 400.
The tray 111 with the heat-treated material 110 placed on it is transferred to the endless chain conveyor 471.472 by the rotation of the conveyor drive motor 480. '472,473
The tray 111 on which the above heat-treated material 110 is placed is returned to
00, and is transferred to the return path 300 side at the end of the direction change path 400. When the tray 111 carrying the heat-treated material 110 is transferred to the end of the direction change path 400 on the return path 300 side, the rotation of the conveyor drive motor 480 is stopped.

Rotating the jack drive motor 450 in the opposite direction to the former,
A plurality of jacks 451 and 452 are driven simultaneously. Then, the shafts 453 and 454 are raised, and the motor mounting bases 441 and 442 are raised. Therefore, the plurality of roll shafts 420 of the direction changing path 400 rise, and at this time, the raised position of the roll shaft 420 is determined by the horizontal line of the large diameter portion 420a of the plurality of endless chain conveyors 471, 472.
'473, and a plurality of endless chain conveyors 471°472. of the direction changing path 400.
The heat-treated material 110 above 473 is transferred onto the large diameter portion 420a of the roll shaft 420 of the direction changing path 400. Therefore, after that, roll! Due to the rotation of N1420 and the roll shaft 120, the heat-treated material 110 placed on the tray 111 moves along the return path 300 in a direction away from the direction change path 400, and enters the heating/soaking chamber N, heat exchange chamber P, and cooling chamber Q. will be transferred.

At this time, the temperature distribution in the longitudinal direction of the furnace of the heat treatment equipment is
The result will be as shown in FIG. 1(b).

In this way, the heat treatment apparatus of this embodiment includes a heat treatment apparatus main body 100 having an outward path 200 and a return path 300 arranged in parallel, and a roll shaft 420 for transporting the heat-treated material 110 disposed in the outward path 200 and return path 300. and roll shaft 120
and the like, and the outward path 20 of the heat treatment apparatus main body 100.
0 and the return trip 300, and the outbound trip 200 and the return trip 3.
00 in the length direction, and a partition wall 60 disposed in a part of the length direction of the outgoing path 200 and the incoming path 300 at the entrance and exit of the heating and soaking chamber N.

In the heat treatment apparatus of the above embodiment of the present invention, the conveyor that transports the direction change path 400 in a direction perpendicular to the directions of the outbound path 200 and the return path 300 is the endless chain conveyor 47.
1,472.473, but when implementing the present invention, the endless chain conveyor 471,472
．． The conveyor belt is not limited to 473, and may be a chain conveyor with an end. Or regarding the type of conveyor,
Can also be used as a belt conveyor or roller conveyor. Of course, depending on the type of conveyor, the number of conveyors can be one and the heat can be stably dissipated! l! As long as the shrines 110 can be transported, it is not necessarily necessary to have a plurality of shrines 110.

Of course, when carrying out the present invention, the direction changer M can be omitted and a heat treatment apparatus that performs heat treatment in parallel can be used. FIG. 4 is an example of this, and is a plan view illustrating the outline of the overall layout of a heat treatment apparatus that performs heat treatment in parallel.

In the heat treatment apparatus shown in Fig. 4 that performs heat treatment in parallel, there are a front chamber J1, a heat exchange chamber K, a heating/soaking chamber, and a heat exchange chamber []
The material to be heat-treated 110 is transferred in series with the cooling chamber Q and the rear chamber R, and the material to be heat-treated is heat-treated in parallel.

In this embodiment, the partition walls 71 and 72 are arranged only at the entrance side of the heating/soaking chamber, that is, at the entrance of the heating/soaking chamber of the right-hand processing path and the left-hand processing path.
Only in the locations where a stirring claw is installed, one stirring claw is provided each in the right direction processing path and the left direction processing path, and in the other locations, one stirring claw is provided in common for the right direction processing path and the left direction processing path. It is.

That is, when carrying out the present invention, the structure of the heat treatment apparatus main body is not limited to a heat treatment apparatus main body consisting of an outward path and a return path arranged in parallel, but a heat treatment apparatus main body consisting of a heat treatment target material transport path arranged in parallel. If it is the device itself, J: Yes.

Incidentally, each of the above embodiments includes a front chamber, a heat exchange chamber, a heating/soaking chamber, a heat exchange chamber, a cooling chamber, and a back chamber, but it can also be used in a chamber having a slow cooling chamber. be.

F. Effects of the Invention] As described above, the heat treatment apparatus of the present invention includes a heat treatment apparatus main body including a heat treatment target material conveyance path arranged in parallel, and a heat treatment target arranged in the heat treatment target material conveyance path arranged in parallel. Transport materials! ti transport means and the heat-treated material conveyance path arranged in parallel in the heat treatment apparatus main body, and includes a partition wall disposed in a part of the length direction of the heat-treated material conveyance path. By reducing the number of partition walls that partition the heat-treated material transport path, the width [Y] of the heat treatment apparatus body is increased, and the ratio to the length [X] in the longitudinal direction of the heat treatment apparatus body, that is, X/ By reducing Y and making the temperature distribution of the heat treatment equipment body uniform, and by omitting the partition walls that separate the parallel conveyance paths of the heat-treated materials, heat loss due to the partition walls is reduced and running costs are reduced. It can be carried out.

[Brief explanation of drawings]

FIG. 1 is a plan view schematically explaining the overall layout of a heat treatment apparatus according to an embodiment of the present invention, and FIG. FIG. 3 is a vertical cross-sectional view of the main part when cut, and FIG. The figure is a plan view illustrating the overall layout of a heat treatment apparatus according to another embodiment of the present invention, FIG. 5 is a horizontal sectional view of the entire furnace of a conventional heat treatment apparatus n, and FIG. Figure 7 is a vertical sectional view of the main part as seen from the side of the furnace.
The cross-sectional view and FIG. 8 are plan views illustrating the outline of the overall layout of a conventional heat treatment apparatus. In the figure, 112: partition wall, 100: heat treatment apparatus main body, 110: material to be heat treated, 120: roll shaft, 200: forward path, 300: return path, 420: roll shaft. In addition, in the figures, the same reference numerals and the same symbols indicate the same or equivalent parts.

Claims (3)

[Claims] (1) A heat treatment apparatus main body consisting of a heat-treated material transport path arranged in parallel, a transport means for transferring the heat-treated material arranged in the heat-treated material transport path, and the heat-treated material transport path arranged in parallel. 1. A heat treatment apparatus comprising: a partition wall disposed in a part of the length direction of a conveying path for a material to be heat treated, separating the passageway from the conveyance path for the material to be heat treated. (2) The heat treatment apparatus according to claim 1, wherein the parallel conveyance paths for the heat-treated materials include an outgoing path and a returning path. (3) The heat treatment apparatus according to claim 1, wherein the partition wall is disposed at a portion of the inlet and outlet of the heating chamber in the length direction of the outgoing and incoming paths.