KR101117016B1 - Heat treatment furnace and vertical heat treatment apparatus - Google Patents

Abstract

Provided is a heat treatment furnace that enables rapid elevating temperature and can improve durability.

The heat treatment furnace 2 is a processing container 3 for accommodating and heat treating the object to be processed, and a cylindrical heater installed to cover the outer circumference of the processing container 3 and heating the object to be processed ( 5) is provided. The heater 5 is provided with the cylindrical heat insulating material 16 and the heat generating resistor 18 arrange | positioned along the inner peripheral surface of the said heat insulating material 16. As shown in FIG. The heat generating resistor 18 is bent into a wave and is made of a strip-shaped body having a peak and a curved portion. The said heat insulating material 16 is provided with the fin member 20 which hold | maintains the said heat generating resistor 18 so that the movement to the radial direction of a heater is possible at appropriate intervals.

Heat treatment furnace, to-be-processed object, heater, heat generating resistor, insulation

Description

Heat Treatment Furnace & Vertical Heat Treatment Equipment {HEAT TREATMENT FURNACE AND VERTICAL HEAT TREATMENT APPARATUS}

This patent application benefits from Japanese Patent Application No. 2007-72477, filed March 20, 2007 and Japanese Patent Application No. 2008-25113, filed February 5, 2008. The entire disclosures in these prior applications are incorporated herein by reference.

The present invention relates to a heat treatment furnace and a vertical heat treatment apparatus having the heat treatment furnace.

In the manufacture of semiconductor devices, various heat treatment apparatuses are used to perform oxidation, diffusion, chemical vapor deposition (CVD), and the like on a semiconductor wafer as a workpiece. The general heat treatment apparatus includes a heat treatment apparatus including a processing vessel (reaction tube) for accommodating and heat treating a semiconductor wafer, and a heater (heating apparatus) provided to cover the periphery of the processing vessel and heating the wafer in the processing vessel. The furnace is provided. The heater includes a cylindrical heat insulating material and a heat generating resistor provided on the inner circumferential surface of the heat insulating material through a support.

As the heat generating resistor, a spiral heater element (also referred to as a heater wire or a heat generating resistor) arranged along the inner wall surface of a cylindrical heat insulating material is used, for example, in the case of a heat treatment apparatus capable of batch treatment. ) Inside can be heated to a high temperature, for example about 800 to 1000 ℃. As the heat insulating material, for example, a material obtained by baking a heat insulating material made of a ceramic fiber or the like into a cylindrical shape is used, and heat can be reduced as radiant heat and conductive heat, thereby facilitating efficient heating. As the support, a ceramic material is used, for example, and the heater element is supported at a predetermined pitch such that thermal expansion and thermal contraction are possible.

By the way, in the said heat processing furnace, the said heater element is formed spirally and is supported by the space | interval with the heat insulating material so that thermal expansion and thermal contraction are possible. However, the heater element generates creep deformation by being used under high temperature, and its line length gradually elongates with time. In addition, even during heating, the heater element causes thermal expansion. In addition, there is also a type of rapid cooling by blowing air to the heater element during the temperature drop. By repeating raising and lowering in this way, a heater element may deform | transform, and a short circuit may generate | occur | produce with the adjacent heater element.

In particular, in the case of the longitudinal heat treatment furnace, when the heater element moves in the support by repeated thermal expansion and thermal contraction due to the elevated temperature, the heater element gradually moves downward due to gravity, and the moving parts accumulate in the lowest turn. Winding diameter becomes large by accumulation of the movement of a heater element, and the heater element which reached | attained to the inner peripheral surface of a heat insulating material, and cannot expand outward is deformed up and down, and a short circuit occurs when it shorts with an adjacent heater element.

In order to solve such a problem, in order to prevent accumulation of the heater element toward one end side of the elongation due to creep, thermal expansion, or the like, a fixing member such as an axial shape protruding outward in the radial direction of the furnace element is welded. It is also proposed to attach and fix the tip of the fixing member in a heat insulating material (see Patent Document 1).

[Patent Document 1] Japanese Patent Application Laid-open No. Hei 10-233277

[Patent Document 2] Japanese Patent Application Laid-Open No. 2005-197074

However, in the case where the fixing member is simply welded to the outer side of the heater element as described above, not only the junction is exposed to high temperature, but also stress is easily concentrated at the junction along with thermal expansion and contraction of the heat generating resistor. In this case, deterioration of durability (shortening life) is considered, and if the fixing member is in the shape of a rod shaft, it is difficult to be released from the heat insulator, and it is difficult to secure sufficient holding force.

In the case of the rapid raising and lowering processing of the wafer, it is necessary to apply a large power to the heater element during the rapid raising of temperature. However, in the conventional heater element up to now, the load is too large, so it is easy to be disconnected. There was a limit to the treatment. Moreover, in order to solve this problem, it is necessary to use an expensive heater element which is hard to be disconnected, and there exists a problem of causing cost increase.

On the other hand, it is effective to increase the ratio of the heater element surface area (element surface area) to the input power in order to reduce the load of the heater element and to prolong the life (improving durability). This is because increasing the heater element surface area lowers the heater surface temperature and reduces the load on the heater element. In a so-called spiral type (spiral) heater element, since the element can be efficiently arranged in a predetermined space, it is used as a load reduction design. However, in the heater or the heat treatment furnace using this spiral type heater element, for example, as shown in Fig. 14, the heater element 18 is embedded in the heat insulating material 16 to fix the heater element 18. Since it is made into, it becomes difficult to heat up rapidly through the heat insulating material 16 with respect to the heating object of a core. Even when the temperature is lowered, the heater element 18 is cooled through the heat insulating material 16, and the heat capacity of the heat insulating material 16 is also increased, so that the rapid falling temperature is difficult. Moreover, since the clearance gap of the expansion part of the heater element 18 is not secured, the heater element itself is stressed at the time of expansion, resulting in the fall of durability.

Moreover, as a heater element, what is formed by shape | molding a strip | belt-shaped heat generating resistance member in the wave form is known (patent document 2). Although this can also increase surface area similarly to a spiral type, it has a structure provided in a cylindrical heat insulating material. It has the same problem.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a heat treatment furnace and a vertical heat treatment apparatus capable of rapidly elevating temperature and improving durability and reducing cost.

The present invention includes a processing container for accommodating and heat treating a target object, and a cylindrical heater installed to cover an outer circumference of the processing container and heating the target object, wherein the heater includes a cylindrical heat insulating material and a heat insulating material. And a heat generating resistor disposed along an inner circumferential surface, wherein the heat generating resistor is formed into a strip-shaped body having a bent portion and a bent portion in a wave shape, and retaining the heat generating resistor in the heat insulating material in the radial direction of the heater at appropriate intervals. A heat treatment furnace characterized by arranging a supporting pin member.

According to the present invention, the fin member is formed in an inverted U shape having a pair of leg portions to support the curved portion of the heat generating resistor, and each leg portion penetrates the heat insulating material from the inside to the outside and is bent from the outside to the outer circumferential surface of the heat insulating material. It is a heat treatment furnace characterized by being locked.

The present invention is a heat treatment furnace characterized in that a plurality of groove portions continuous in the circumferential direction are formed on the inner circumferential surface of the heat insulating material at appropriate intervals in the vertical direction, thereby accommodating all or part of the heat generating resistor.

This invention is the heat processing furnace characterized in that the said heat insulating material is provided with two or more air blowing holes for forced air cooling which penetrate in and out between the heat generating resistors which adjoin upper and lower sides at appropriate intervals in the circumferential direction.

According to the present invention, the heat insulating material is divided into two sides to the left and right through a split surface extending in the longitudinal direction. End portions of each other are connected via a connecting plate, and the connecting plate is disposed on a divided surface portion of the heat insulating material.

The present invention is the heat treatment furnace, wherein the connecting plate is fixed to the divided surface portion of the heat insulating material by a fixing member made of a pin.

The present invention is the heat treatment furnace, characterized in that the connecting plate is provided with a latching portion fixed to the outer peripheral surface of the heat insulating material.

The present invention is a heat treatment furnace, wherein the connecting plate is provided with a fixing piece that is fixed in the heat insulating material.

The present invention is a heat treatment furnace characterized in that the heat insulating material is provided with a fall preventing pin for holding an acid portion of the heat generating resistor.

This invention is the heat processing furnace characterized by the fall prevention plate which is provided in the said heat insulating material so that the lower part of the mountain part of the said heat generating resistor may not fall down.

The present invention provides a heat treatment furnace having a lower length open as a furnace and a vertically elongated processing container for accommodating and heat-treating an object, a cylindrical heater provided on an outer periphery of the processing container and heating the object, A lid which closes the furnace, a retainer which is loaded on the lid and holds the object in multiple stages, and the lid is lifted to open and close the lid and carry in and carry out the retainer into the processing container. The elevating mechanism is provided, wherein the heater is provided with a cylindrical heat insulating material and a heat generating resistor disposed on an inner circumferential surface of the heat insulating material, and the heat generating resistor is formed of a strip-shaped body having a peak and a curved portion bent in a wave shape. In which a fin member for movably holding the heat generating resistor in the radial direction of the heater is disposed at appropriate intervals. It is a vertical heat treatment apparatus characterized by the above-mentioned.

According to the present invention, the fin member is formed in an inverted U shape having a pair of leg portions to support the curved portion of the heat generating resistor, and each leg portion penetrates the heat insulating material from the inside to the outside and is bent from the outside to the outer circumferential surface of the heat insulating material. Longitudinal heat treatment apparatus characterized by being locked.

The present invention is a longitudinal heat treatment apparatus characterized in that a plurality of groove portions continuous in the circumferential direction are formed on the inner circumferential surface of the heat insulating material at appropriate intervals in the vertical direction, thereby accommodating all or part of the heat generating resistor.

The vertical heat treatment apparatus according to the present invention is provided with a plurality of air cooling holes for forced air cooling penetrating in and out between the heat generating resistors adjacent to each other in the heat insulating material at appropriate intervals in the circumferential direction.

According to the present invention, the heat insulating material is divided into two sides to the left and right through a split surface extending in the longitudinal direction. End portions of each other are connected via a connecting plate, and the connecting plate is disposed on the divided surface portion of the heat insulating material.

This invention is the vertical type heat processing apparatus characterized by the said connection plate being fixed by the fixing member which consists of fins in the dividing surface part of the said heat insulating material.

The present invention is a vertical heat treatment apparatus, characterized in that the engaging plate is provided with a latching part fixed to the outer peripheral surface of the heat insulating material.

This invention is the vertical type heat processing apparatus characterized by the said fixing plate which is provided in the said heat insulating material, and is fixed to the said connection plate.

This invention is the vertical heat processing apparatus characterized by the fall prevention pin which holds the mountain part of the said heat generating resistor provided in the said heat insulating material.

This invention is the vertical heat processing apparatus characterized by the fall prevention plate which is provided in the said heat insulating material so that the lower part of the mountain part of the said heat generating resistor may not fall down.

According to the present invention, since the heat generating resistor processed in the form of a strip is formed in the state exposed along the inner circumferential surface of the heat insulating material, rapid raising and lowering temperature can be achieved, and durability and cost can be reduced.

EMBODIMENT OF THE INVENTION Below, the best form for implementing this invention is described in detail based on an accompanying drawing. 1 is a longitudinal cross-sectional view schematically showing a longitudinal heat treatment apparatus according to an embodiment of the present invention, FIG. 2 is an enlarged cross-sectional view of portion A of FIG. 1, FIG. 3 is an enlarged longitudinal cross-sectional view of portion A, FIG. 4 is a plan view of a heater element, and FIG. Is a side view of the heater element.

In Fig. 1, reference numeral 1 denotes a vertical heat treatment apparatus which is one of semiconductor manufacturing apparatuses. The heat treatment apparatus 1 accommodates a plurality of objects to be processed, for example, a semiconductor wafer w at one time, for oxidation, diffusion, A vertical heat treatment furnace 2 capable of performing heat treatment such as reduced pressure CVD is provided. The heat treatment furnace 2 is provided with a processing container (also referred to as a reaction tube) 3 for accommodating and heat treating the wafer w, and covers the outer circumference of the processing container 3 to cover the wafer w. A cylindrical heater (heating device) 5 to be heated is provided.

The heat treatment apparatus 1 is provided with a base plate 6 for installing the heater 5. The base plate 6 is formed with an opening 7 for inserting the processing container 3 from below to above, and the opening 7 is provided with a gap between the base plate 6 and the processing container 3. The heat insulating material which is not shown so that it may cover is provided.

The processing container 3 is made of quartz and has a vertically long cylindrical shape in which an upper end is closed and an lower end is opened as the furnace port 3a. An outward flange 3b is formed at the open end of the processing container 3, and the flange 3b is supported by the base plate 6 via a flange pressing portion (not shown). The processing container 3 in the example of illustration is not shown for exhausting the gas in the processing port 3 and the introduction port (inlet) 8 which introduces a processing gas, an inert gas, etc. into the processing container 3 in the lower part. Has an exhaust port (exhaust port). A gas supply source is connected to the inlet port ^8, and an exhaust system having a vacuum pump capable of depressurizing control at, for example, 10 to 10 ⁻⁸ Torr is connected to the exhaust port.

Under the processing container 3, the lid 10 which can be opened and closed in the up-down direction which closes the lower end opening part (furnace) 3a of the processing container 3 is provided so that lifting / lowering movement is possible by the lifting mechanism 10A. have. In the upper part of this cover body 10, for example, the thermal insulation container 11 which is a thermal insulation means of a furnace ball is mounted, and the upper part of the said thermal insulation cylinder 11 has many wafers w of 300 mm in diameter, for example, For example, a quartz boat 12, which is a holding tool to be mounted at a predetermined interval in the vertical direction about 100 to 150 sheets, is stacked. The lid 10 is provided with a rotation mechanism 13 for rotating the boat 12 around its axis. The boat 12 is unloaded (unloaded) from the inside of the processing container 3 into the lower loading area 15 by the downward movement of the lid 10, and after replacing the wafer w, the lid 10 is replaced. ) Is loaded (loaded) into the processing container 3 by the upward movement.

As shown in Figs. 2 to 5, the heater 5 has a cylindrical heat insulating material 16 and a groove shape formed in multiple stages in the axial direction (up and down direction in the illustrated example) on the inner circumferential surface of the heat insulating material 16. The shelf part 17 and the heater element (heater line | wire, heat generating resistor) 18 arrange | positioned along each shelf part 17 are provided. The heat insulating material consists of inorganic fiber containing silica, alumina, or alumina silicate, for example. It is preferable that the heat insulating material is divided into two parts to the left and right through the divided surface 16a extending in the longitudinal direction, in terms of attaching the heater element and assembling the heater.

The heater element 18 consists of the strip | belt-shaped body 18A shape | molded (bending) by the wave form. The corrugated heater element 18 is made of, for example, an alloy of iron (Fe), chromium (Cr) and aluminum (Al) (so-called Kanthal material). This heater element 18 is, for example, about 1 to 2 mm in thickness, about 14 to 18 mm in width, about 11 to 15 mm in amplitude of the wave portion, and about 28 to 32 mm in pitch p of the wave portion. It is about. In addition, the vertex angle (theta) of the wave part of the heater element 18 is set to about 90 degrees, and each vertex part (also called a convex part or a mountain part) 18a is R-bending process. Thereby, while moving to some extent in the circumferential direction of the heater element 18 on the shelf part 17 of the heat insulating material 16, the improvement of the intensity | strength of a bending part is aimed at.

The heat insulator 16 is arranged with a fin member 20 for holding the heater element 18 in the radial direction at appropriate intervals and for preventing it from falling off or escaping from the shelf 17. On the inner circumferential surface of the cylindrical heat insulating material 16, this and concentric annular groove portions 21 are formed in multiple stages at a predetermined pitch in the axial direction, and between the adjacent upper groove portions 21 and the lower groove portions 21. The shelf portion 17 of the annular shape that is continuous in the circumferential direction is formed. Between the upper and lower portions of the heater element 18 and the inner wall 21a of the groove portion 21 and the heater element 18 in the groove portion 21, thermal expansion contraction and radial movement of the heater element 18 are performed. An allowable gap is formed, and these gaps allow cooling air during forced air cooling to penetrate the rear surface of the heater element 18 so that the heater element 18 can be cooled effectively.

The fin member 20 includes a pair of leg portions 20b to support the curved portion 18b of the inner circumferential surface of the heater element 18 as the base portion 20a, and is formed in a lateral inverted shape. Both leg portions 20b penetrate the heat insulating material 16 from the inside to the outside. The end portions 20c of the two leg portions 20b are bent in a direction to be spaced apart from each other and locked to the outer circumferential surface of the heat insulating material 16. The fin member 20 is preferably made of the same material as the heater element 18. Moreover, as shown in FIG. 3, it is preferable that the heater element 18 is accommodated in the groove part 21 about half of the outer side in the radial direction, and exposes about half of the inside of the radial direction out of the groove 21. As shown in FIG. .

The heater element 18 is not continuously connected in a vertical direction like a conventional heater element, and is disposed on the shelf portion 17 of each stage as shown in FIGS. Terminated at For this reason, the heater element 18 does not move and accumulates (accumulates) downward by its own weight. In addition, the heater elements 18 are connected (connected) between adjacent upper and lower ends as shown in Fig. 5, and are connected in series at multiple stages (seven stages in the illustrated example) and at the multiple stages. The terminal board 22 for electrode connection is connected to the beginning end part 18e of the lowest end of a group, and the termination part 18r of the uppermost end, respectively. Thereby, the heater 5 is comprised so that temperature control may be divided | segmented into several zone in the up-down direction inside the heat processing furnace 2.

Although the heater element 18 may be arrange | positioned annularly along the shelf part 17-the groove part 21 of the heat insulating material 16, it corresponds to the heat insulating material 16 divided | segmented along the division surface 16a. As shown in Fig. 4, it is preferable to be formed in a half divided shape (arc shape). As a connection (wiring) pattern of the heater element 18, what is shown, for example in FIGS. 4-5 is considered. In this connection pattern, both ends 18e, 18f, 18g ... 18r of the heater element 18 of each stage are bent so that it may protrude radially outward, and the 1st stage (lowest stage) start end (right end) 18e The terminal plates 22 and 22 are respectively joined to the uppermost end portion (left end portion) 18r. In order to connect the heat generating resistors 18 adjacent to each other up and down in series, the ends, for example, the first end 18f of the first stage and the first end 18g of the second stage are connected via the connecting plate 23. Then, the second stage end 18h and the third stage end 18i are sequentially connected in such a manner that they are connected via the connecting plate 23. This connecting plate 23 is located on the divided surface 16a of the heat insulating material 16.

The end of the heater element 18 and the connecting plate 23 are joined by welding. The terminal plate 22 is provided to penetrate the heat insulating material 16 in the radial direction. It is preferable that the said connection plate 23 is embedded in the heat insulating material 16 in order to prevent the welding part with the edge part of the heater element 18 from being exposed to high temperature. In addition, as the connection pattern of the heater element 18, the thing of that excepting the above is applicable. It is preferable that the terminal plate 22 and the connecting plate 23 are made of the same material as the heater element 18, and are formed in a plate shape having a required cross-sectional area in view of prevention of blowdown and suppression of heat dissipation.

In order to maintain the shape of the heat insulating material 16 and to reinforce the heat insulating material 16, the outer circumferential surface of the heat insulating material 16 is covered with an outer shell 28 made of metal, for example, stainless steel, as shown in FIG. have. Moreover, in order to suppress the heat influence to the exterior of a heater, the outer peripheral surface of the outer shell 28 is covered with the water cooling jacket 30. As shown in FIG. An upper heat insulating material 31 covering this is provided at the top of the heat insulating material 16, and a stainless steel ceiling plate 32 is provided on the top of the upper heat insulating material 31 to cover the top (upper end) of the shell 28.

In order to accelerate the processing and to improve the throughput by rapidly lowering the wafer after the heat treatment, the heater 5 includes an array system which discharges the atmosphere in the space 33 between the heater 5 and the processing container 3 to the outside ( 35 and forced air cooling means 36 for introducing the air at normal temperature (20 to 30 ° C.) into the space 33 and forcibly cooling it. The array system 35 is mainly composed of, for example, an exhaust port 37 provided in the upper portion of the heater 5, and an array pipe (not shown) connecting the exhaust port 37 and a factory exhaust system (not shown). An exhaust blower and a heat exchanger (not shown) are provided in the array tube.

The forced air cooling means 36 includes an annular flow passage 38 formed in a plurality of heights in the height direction between the heat insulating material 16 and the outer shell 28, and the center inclination direction of the heat insulating material 16 from each annular flow passage 38. The air blowing hole 40 for forced air cooling provided in the heat insulating material 16 is provided in order to blow out air and generate | occur | produce a swirl flow in the circumferential direction of the said space 33. As shown in FIG. The annular flow passage 38 is formed by attaching a band-shaped or annular heat insulating material 41 to the outer circumferential surface of the heat insulating material 16 or by cutting the outer circumferential surface of the heat insulating material 16 in a ring shape. The air blowing hole 40 is a shelf portion between heater elements 18 adjacent to the upper and lower sides of the heat insulating material 16, as shown in Figs. 6A and 6B. It is preferable to form 17) so that this may penetrate in and out of the radial direction. By providing the air blowout holes 40 in the shelf 17 in this manner, the air can be blown into the space 33 without being disturbed by the heater element.

On the outer circumferential surface of the shell 28 is provided a common one, not shown, supply duct for distributing and supplying cooling fluid to each annular flow passage 38 along the height direction. The communication port which communicates with the shape flow path 38 is formed. A cooling fluid supply source (for example, a blower) (not shown) for sucking and supplying the air in the clean room as the cooling fluid is supplied to the supply duct via an opening / closing valve.

According to the heat treatment furnace 2 to the vertical heat treatment apparatus 1 comprised as mentioned above, the processing container 3 for accommodating and heat-processing the wafer w, and it is provided so that the circumference | surroundings of the said processing container 3 may be covered and a wafer The cylindrical heater 5 which heats (w) is provided. The heater 5 is disposed along a cylindrical heat insulating material 16, a groove-shaped shelf part 17 formed in multiple stages in the axial direction on the inner circumferential surface of the heat insulating material 16, and each shelf part 17. The provided heater element 18 is provided. The heater element 18 is formed by forming a strip in the form of a wave, and the heat insulating member 16 further includes a shelf part (not shown) to move the heater element 18 in the radial direction of the heater 5 at appropriate intervals. The pin member 20 which hold | maintains so that it may not fall out from 17) is arrange | positioned. For this reason, it can be installed in the state which exposed the colgate type heater element 18 to the shelf part 17 of each step of the inner peripheral surface of the heat insulating material 16, and can raise and lower rapidly rapidly, and also improve durability and reduce cost. This is planned. By using the Colgate-type heater element 18, the ratio of the element surface area can be effectively increased to reduce the load on the heater element due to the decrease in the heater surface temperature, thereby preventing breakage. For this reason, a large power can be put into the heater element 18, and it can heat up rapidly. In addition, since disconnection is suppressed, durability can be improved and life can be prolonged, and an inexpensive cantal material can be used as the heater element 18, thereby reducing costs.

The forced air cooling hole 40 for penetrating the shelf part 17 in and out is formed in the shelf part 17 between the heater elements 18 which adjoin the upper and lower sides of the said heat insulating material 16. Therefore, air can be easily taken out without being disturbed by the heater element. The heat insulating material 16 is divided into two with the divided surface 16a extending in the longitudinal direction, and the heater element 18 is also divided in correspondence to the heat insulating material, so that the heater element can be easily attached to the heat insulating material. Thereby, the assembly property can be improved.

FIG. 7 is a view showing an example of a structure for fixing the connecting plate at the end of the heat generating resistor to the heat insulator. FIG. 7A is an enlarged perspective view of a main part, and FIG. 7B is a sectional view of the fixed state. In order to suppress or prevent deformation of the connecting plate 23, which is a folded portion (U-turn part) of the heater element 18, the connecting plate 23 is finned at an end portion (divided surface portion) 16a of the heat insulating material 16. And a fixing member 46 fixed to the outer circumferential surface of the heat insulator 16 while being fixed with a fixing member (an inverted U-shaped pin in the example) 45 of the back and the like. have.

8A and 8B are cross-sectional views showing another example of the structure of fixing the connecting plate at the end of the heat generating resistor to the heat insulating material. At the end of the heat insulating material 16, the connecting plate 23 is fixed to the fixing member 45, and an auxiliary heat insulating material 47 is provided to cover the connecting plate 23. The auxiliary heat insulating material 47 is interposed or filled between the ends (divided surface portions) of the heat insulating material 16. The fixing member 45 may be a pipe, a round bar, an angled bar, or the like in addition to the pin.

9 (a) and 9 (b) are cross-sectional views showing another example of the structure of fixing the connecting plate at the end of the heat generating resistor to the heat insulating material. The connecting plate 23 is provided with a fixing piece 48 which is fixed in the heat insulating material 16 or the auxiliary heat insulating material 47. This fixing piece 48 is formed by bending the tip of the connecting plate 23 at right angles, for example. An auxiliary heat insulating material 47 is provided at the end of the heat insulating material 16 so as to cover the connecting plate 23. It is preferable that the fixing piece 48 enters the heat insulating material 16 side (see FIG. 9 (b)), but may enter the auxiliary heat insulating material 47 side (see FIG. 9 (a)).

Fig. 10 is a view showing the structure of holding the convex portion of the heat generating resistor with the anti-fall pin, Fig. 10 (a) is a partial perspective view and Fig. 10 (b) is a schematic perspective view of the anti-fall pin. The heat insulating material 16 is provided with a fall prevention pin 49 for holding the convex portion 18a of the appropriate portion of the heater element 18 which is corrugated and unevenly corrugated from the inner circumferential surface of the heat insulating material 16 so as not to fall down. have. The fall prevention pin 49 is formed by bending a wire rod such as steel wire. One wire is bent in two, and this is bent again in an inverted c-shape, and the bent portion at the tip is pressed to form a loop shape or a substantially triangular enlarged portion 49a. The convex part 18a of the heater element 18 is received inside the inverted-shaped part 49b of this fall prevention pin 49, and the lower enlarged part 49a is near the heat insulating material 16 side, for example, It is located above the groove 21 or the shelf 17. The both ends 49c and 49c on the fall prevention pin 49 penetrate through the heat insulating material 16, and protrude toward the outer peripheral surface side, and are bent by engaging these both ends 49c and 49c from side to side, and are caught by the outer peripheral surface of the heat insulating material 16. FIG. .

By this mounting method, the fall prevention pin 49 is arranged in a plurality of rows, for example, on one heat insulating material at an appropriate interval in the circumferential direction of the heater element 18 of the heat insulating material 16 and in the axial direction of the heat insulating material 16. Ten are arranged. According to the fall prevention pin 49, it is possible to prevent the heater element 18 from falling down or falling down, whereby the depth of the groove portion 21 of the heat insulating material 16 to the shelf portion (shade) 17 It becomes possible to reduce the amount of protrusions, and it is also possible to eliminate the groove portion 21 to the shelf portion 17.

Fig. 11 is a perspective view showing another example of the tipping pin. As the anti-fall pin 49, one wire may be bent in an inverted shape (see FIG. 11 (a)), or one wire may be bent in two, and this may be bent in an inverted shape. 11 (b)]. In addition, both ends 49 and 49c are bent as a latching part.

Fig. 12 is a view showing the structure of holding the convex portion of the heat generating resistor with the anti-fall plate, Fig. 12 (a) is a partial perspective view, and Fig. 12 (b) is a schematic perspective view of the anti-fall plate. The heat insulating material 16 is provided with a fall prevention plate 50 for supporting the lower portion of the convex portion 18a of the appropriate portion of the heater element 18 which is corrugated unevenly from the inner circumferential surface of the heat insulating material 16 so as not to fall down. have. It is preferable that this fall prevention plate 50 consists of a rectangular plate made of ceramic, for example, and the one end part in the longitudinal direction is provided with the pointed part 50a for sticking and fixing this to a heat insulating material. By supporting the lower portion of the convex portion 18a of the heater element 18 horizontally, the fall prevention plate 50 can prevent the heater element 18 from falling or falling down, whereby Similarly, the grooves 21 to the shelf 17 can be removed.

13 is a perspective view illustrating another example of the heat insulating material. Since the heat insulating material 16 of the heater 5 may generate a crack on the inner circumferential surface due to internal stress due to thermal expansion and contraction, in order to prevent this, as shown in FIG. (42) is preferably formed. In addition, it is preferable that the heat insulating material 16 is divided up and down at the lower surface position of each shelf part 17 in consideration of the assembly property of a heater. That is, the heat insulating material 16 consists of the division block 16a divided | segmented into multiple stages in the up-down direction, and when a heater element is provided in the shelf part 17 of the division block 16a of the 1st step | paragraph, the 2nd-stage division block ( The heater elements 18 are easily installed on the shelf portions 17 of each stage in such a way that the heater elements 18 are installed on the shelf portions 17 of the second-stage dividing block 16a by stacking up 16a. It is possible to improve the assembly properties. In this case, it is preferable that the positioning concave portion 43a and the convex portion 43b coupled to each other are formed along the circumferential direction on the opposing surface in the divided blocks 16a adjacent to the upper and lower sides.

In addition, this invention is not limited to the said embodiment, A various design change is possible within the scope of the summary of this invention. For example, the processing container may be formed by connecting a heat-resistant metal having an inlet pipe part and an exhaust pipe part, for example, a cylindrical manifold of stainless steel, to a lower end part, or may have a double pipe structure.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a longitudinal sectional view schematically showing a vertical heat treatment apparatus according to an embodiment of the present invention.

2 is an enlarged cross-sectional view of portion A of FIG.

3 is an enlarged longitudinal sectional view of portion A of FIG.

4 is a top view of the heater element.

5 is a side view of the heater element.

Fig. 6A is a plan view showing an example of a heat insulating material, and Fig. 6B is a sectional view taken along the line B-B in Fig. 6A.

Fig. 7A is an enlarged perspective view of an essential part showing an example of a structure for fixing the connecting plate at the end of the heat generating resistor to the heat insulator, and Fig. 7B is a sectional view of the fixed state.

Fig. 8 is a sectional view showing another example of the structure of fixing the connecting plate at the end of the heat generating resistor to the heat insulating material.

9 (a) and 9 (b) are sectional views showing another example of the structure of fixing the connecting plate at the end of the heat generating resistor to the heat insulating material.

Fig. 10A is a partial perspective view showing the structure of holding the convex portion of the heat generating resistor with the anti-fall pin, and Fig. 10B is a schematic perspective view of the anti-fall pin.

11 (a) and 11 (b) are perspective views showing another example of the anti-fall pin.

Fig. 12A is a partial perspective view showing the structure of holding the convex portion of the heat generating resistor with the fall prevention plate, and Fig. 12B is a schematic perspective view of the fall prevention plate.

Fig. 13 is a partial perspective view showing another example of heat insulator.

Fig. 14A is a sectional view showing an example of a conventional heater, and Fig. 14B is a view of the inner circumferential surface of the heater.

<Explanation of symbols for the main parts of the drawings>

1: heat treatment device

3: processing container

5: heater

6: base plate

7: opening

8: introduction port

10: cover body

11: thermos

12: boat

16: heat insulation

17: shelf

18: heater element

20: pin member

21: groove

35: exhaust system

50: fall prevention plate

Claims (20)

A processing container for accommodating and heat treating a target object; It is provided to cover the outer periphery of the said processing container, and provided with the cylindrical heater which heats a to-be-processed object, The heater includes a cylindrical heat insulating material and a heat generating resistor disposed along an inner circumferential surface of the heat insulating material, The heat generating resistor is made of a strip-shaped body having a bent portion and a bent by bending the waveform, In the heat insulating material, a fin member for movably holding the heat generating resistor in a radial direction of the heater at a predetermined interval is disposed, The heat insulator is divided into two sides to the left and right through a split surface extending in the longitudinal direction, and the heat generating resistor is also divided into left and right corresponding to the heat insulating material, and the heat generating resistors adjacent to the upper and lower sides of the heat generating resistor and the ends of each other are separated from each other. The temporary heat connection furnace characterized in that the connecting plate is connected via a connecting plate, the connecting plate is disposed in the divided surface portion of the heat insulating material. According to claim 1, wherein the fin member is formed in an inverted c-shape having a pair of legs to support the curved portion of the heat generating resistor, each leg portion penetrates the heat insulating material from the inside to the outside, bent from the outside to insulate the heat insulating material Heat treatment furnace, characterized in that the locking on the outer peripheral surface of the. The heat treatment furnace according to claim 1, wherein a plurality of groove portions continuous in the circumferential direction are formed on the inner circumferential surface of the heat insulating material at predetermined intervals in the vertical direction, thereby accommodating all or part of the heat generating resistor. 2. The heat treatment furnace according to claim 1, wherein the heat insulating material has a plurality of air blowing holes for forced air cooling penetrating in and out between the heat generating resistors adjacent to each other up and down at predetermined intervals in the circumferential direction. delete The heat treatment furnace according to claim 1, wherein the connecting plate is fixed to a divided surface portion of the heat insulating material by a fixing member made of a pin. The heat treatment furnace according to claim 1, wherein the connecting plate is provided with a locking part fixed to the outer circumferential surface of the heat insulating material. The heat treatment furnace according to claim 1, wherein the connecting plate is provided with a fixing piece to be fixed in the heat insulating material. The heat treatment furnace according to claim 1, wherein the heat insulating material is provided with a fall preventing pin for holding an acid portion of the heat generating resistor. The heat treatment furnace according to claim 1, wherein the heat insulating material is provided with a fall preventing plate that supports the lower portion of the acid portion of the heat generating resistor so as not to fall down. A heat treatment furnace having a lower length opening as a furnace and a longitudinally elongated processing container for accommodating and heat treating the object, and a cylindrical heater provided on an outer periphery of the processing container and heating the object, A cover body that closes the furnace port, A holding tool mounted on the lid and holding the object to be processed in multiple stages; An elevating mechanism for elevating the lid to open and close the lid and carrying in and out of the holding tool into the processing container; The heater includes a cylindrical heat insulating material and a heat generating resistor disposed on an inner circumferential surface of the heat insulating material, The heat generating resistor is made of a strip-shaped body having a bent portion and a bent by bending the waveform, In the heat insulating material, a fin member for movably holding the heat generating resistor in a radial direction of the heater at a predetermined interval is disposed, The heat insulator is divided into two sides to the left and right through a split surface extending in the longitudinal direction, and the heat generating resistor is also divided into left and right corresponding to the heat insulating material, and the heat generating resistors adjacent to the upper and lower sides of the heat generating resistor and the ends of each other are separated from each other. The temporary heat treatment apparatus characterized in that the connecting plate is connected via a connecting plate, and the connecting plate is disposed on the divided surface portion of the heat insulating material. 12. The heat sink according to claim 11, wherein the fin member is formed in an inverted U shape having a pair of legs so as to support the curved portion of the heat generating resistor, and each of the legs penetrates the heat insulating material from the inside to the outside and is bent from the outside to form the insulator. Longitudinal heat treatment apparatus characterized by being latched on the outer peripheral surface. 12. The longitudinal heat treatment apparatus according to claim 11, wherein a plurality of groove portions continuous in the circumferential direction are formed on the inner circumferential surface of the heat insulating material at predetermined intervals in a vertical direction, thereby accommodating all or part of the heat generating resistor. 12. The longitudinal heat treatment apparatus according to claim 11, wherein the heat insulating material has a plurality of air blowing holes for forced air cooling penetrating in and out between the heat generating resistors adjacent to each other up and down at predetermined intervals in the circumferential direction. delete 12. The vertical heat treatment apparatus according to claim 11, wherein the connecting plate is fixed to a divided surface portion of the heat insulating material by a fixing member made of a pin. 12. The longitudinal heat treatment apparatus according to claim 11, wherein the connecting plate is provided with a locking fixing part that is caught and fixed to an outer circumferential surface of the heat insulating material. 12. The longitudinal heat treatment apparatus according to claim 11, wherein the connecting plate is provided with a fixing piece that is fixed in the heat insulating material. 12. The vertical heat treatment apparatus according to claim 11, wherein the heat insulating material is provided with a fall preventing pin for holding an acid portion of the heat generating resistor. 12. The longitudinal heat treatment apparatus according to claim 11, wherein the heat insulating material is provided with a fall prevention plate that supports the lower portion of the acid portion of the heat generating resistor so as not to fall down.

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