JPH10115401A - Solvent loss amount reducing method and device thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inhibit a vapor breakdown time to a minimum at a relatively low cost without increasing the size of a device and reduce the amount of loss of a solvent by enhancing the recovery rate of the solvent. SOLUTION: According to this solvent loss reducing method, a solvent is heated and boiled, thereby forming a vapor phase 6 and heating an article 22 to be heated with the vapor phase 6 as a heating medium. In this case, after the heated article 22 is arranged to move into the vapor phase, the amount of the solvent is increased so as to compensate for the heating value robbed off from the vapor phase 6 resultant from the approach of the heated article 22 during the execution of a heating processing process which is carried out from the vapor phase 6.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for reducing a loss of a solvent in a heat treatment for heating an object to be heated using a vapor phase of a solvent such as an inert organic liquid as a heating medium.

[0002]

2. Description of the Related Art A heat treatment apparatus (e.g., a thermosetting resin curing apparatus) for performing a heat treatment for heating an object to be heated by using a vapor phase of a solvent such as an inert organic liquid as a heating medium, comprises a heat treatment tank. In the heat treatment tank, a liquid phase of the solvent and a vapor phase of the solvent formed above the liquid phase in the vertical direction are sequentially arranged in a stacked state in the vertical direction. The vapor phase is formed by heating and boiling the solvent by heating means provided in the heat treatment tank. In the upper part of the heat treatment tank,
A cooling device is provided for maintaining the level of the vapor phase surface of the vapor phase substantially constant by calorie balance with the vapor phase. Above the heat treatment tank, there is provided a heating object transport means for entering and discharging the heating object to be heated into and out of the vapor phase.

When the object to be heated is lowered into the vapor phase by lowering the object conveying means, the object to be heated is heated by the heat of condensation of the vapor phase. After the object to be heated is heated to a predetermined temperature, the object-to-be-heated is conveyed up and the object to be heated is carried out of the vapor phase, thereby completing the predetermined heat treatment of the object to be heated.

[0004] The above heat treatment apparatus is further provided with a solvent recovery apparatus for recovering a solvent from the inside of the heat treatment tank. This solvent recovery device includes a solvent recovery tank. The solvent recovery tank and the heat treatment tank are connected via a steam suction pipe. One end of the vapor suction pipe is opened in the solvent recovery tank, and the other end is opened at a predetermined interval above the vapor phase surface in the heat treatment tank. The solvent recovery device is provided with suction means for sucking steam from the vapor phase through a steam suction pipe, and cooling means for condensing the sucked steam. Since the solvent recovery device is configured as described above, the vapor from the vapor phase is sucked into the solvent recovery tank by the suction means and collected by being condensed by the cooling means.

[0005]

In the above-described method for recovering a solvent by the conventional solvent recovery apparatus, the recovery rate in a state where the vapor phase surface is kept constant is relatively high, and it can be said that the recovery effect is excellent. . However, when the object to be heated enters the vapor phase and the heat of the vapor phase is taken away by the object to be heated, the vapor phase collapses instantaneously. When the vapor phase collapses, the vapor phase surface falls below a predetermined level, and the predetermined distance from the vapor suction pipe of the solvent recovery device increases. When the predetermined interval is large, the vapor from the vapor phase cannot be sufficiently sucked, the recovery rate decreases, and the loss of the solvent increases.

In order to improve the recovery rate of lost steam,
It is necessary to minimize the vapor collapse time due to the entry of the heated object into the vapor phase, that is, the time required for the vapor phase to fall from a predetermined level and return to the predetermined level again. In order to minimize the vapor collapse time, it is conceivable to increase the capacity (heating capacity) of the heating means for constantly heating and boiling the solvent. However, according to this method, the capacity of the cooling device for maintaining the vapor phase surface constant needs to be increased in accordance with the increase in the capacity of the heating means, which increases the size of the entire device and increases the cost.

[0007] The present invention has been made in view of the above-mentioned facts, and its technical problem is to reduce the steam collapse time to a minimum at a relatively low cost without increasing the size of the entire apparatus.
An object of the present invention is to improve a method and an apparatus for reducing the amount of solvent loss so that the recovery rate of the solvent can be improved and the amount of solvent loss can be reduced.

[0008]

According to one aspect of the present invention, in a heat treatment for heating a substance to be heated by heating and boiling a solvent to form a vapor phase, and using the vapor phase as a heating medium to heat the object to be heated. While the heating object moves toward the vapor phase, enters into the vapor phase, is heated, and then is subjected to a heat treatment step carried out from the vapor phase, the vapor phase is caused by the entry of the object to be heated. A method for reducing the amount of solvent loss, characterized by increasing the capacity of heating the solvent so as to compensate for the amount of heat deprived of the solvent.

In the above invention, during the heat treatment step in which the object to be heated moves toward the vapor phase, enters the vapor phase, is heated, and is then carried out of the vapor phase,
Since the capacity for heating the solvent is increased so as to compensate for the amount of heat deprived from the vapor phase by the entry of the object to be heated, the capacity for heating the solvent is not always increased, and therefore,
There is no need to increase the capacity of the cooling device for keeping the vapor phase surface constant. As a result, it is possible to minimize the vapor disintegration time, increase the solvent recovery rate and reduce the amount of solvent loss at a relatively low cost without increasing the size of the entire apparatus. Reducing the amount of solvent loss reduces the amount of solvent used, and also in this aspect, cost reduction can be obtained.

According to the present invention, in addition to the above configuration,
A method for reducing the loss of a solvent is provided, in which the object to be heated starts moving toward the vapor phase to enter the vapor phase, and at the same time, increases the capacity of heating the solvent.
According to the method of increasing the capacity of heating the solvent after the object to be heated enters the vapor phase, a time delay occurs until the heating effect occurs, and the recovery time of the steam collapse is prolonged. However, in the present invention, since the capacity for heating the solvent immediately before the object enters the vapor phase is increased, the time delay is reduced, and the recovery time after the vapor collapse can be reduced, and the solvent can be removed. The recovery rate can be improved and the loss of the solvent can be reduced. Further, the amount of the solvent used is reduced, and the effect of cost reduction can be obtained in this aspect as well.

According to another aspect of the present invention, the heat treatment tank, the liquid phase of the solvent contained in the heat treatment tank, and the vapor phase of the solvent formed vertically above the liquid phase A heating means for constantly heating and boiling the solvent to form the vapor phase, and a heat quantity balance with the vapor phase so that the height of the vapor phase surface of the vapor phase is kept substantially constant. A cooling device provided, a heated object transporting means for moving the heated object into and out of the vapor phase, and a solvent recovery device for recovering the solvent from the heat treatment tank; The solvent recovery apparatus includes a solvent recovery tank, and a heat treatment apparatus including a vapor suction pipe having one end opened in the solvent recovery tank and the other end opened at a predetermined interval above the vapor phase surface. In the above, an auxiliary heating means for increasing the capacity of heating the solvent, and the object to be heated is The amount of heat deprived of the vapor phase by the entry of the object to be heated during the heat treatment step of moving toward the vapor phase, entering the vapor phase, being heated, and then being carried out of the vapor phase, is performed. And a control means for controlling the operation of the auxiliary heating means so as to compensate for the difference. In the present invention, an auxiliary heating means is provided in addition to the heating means for constantly heating and boiling the solvent, and the auxiliary heating means is controlled by the control means so that the object to be heated moves toward the vapor phase and is moved in the vapor phase. During the heat treatment step of being carried out from the vapor phase after being heated, the operation is controlled so as to compensate for the amount of heat deprived from the vapor phase due to the entry of the object to be heated. There is no need to increase the capacity of the heating means for constantly heating and boiling, and therefore it is not necessary to increase the capacity of the cooling device. As a result, it is possible to minimize the vapor disintegration time, increase the solvent recovery rate and reduce the amount of solvent loss at a relatively low cost without increasing the size of the entire apparatus. Further, the amount of the solvent used is reduced, and the effect of cost reduction can be obtained in this aspect as well. Further, the power saving effect can be obtained because it is not necessary to increase the capacity of the heating means for constantly heating and boiling the solvent.

According to the present invention, in addition to the above structure,
A temperature detecting means for detecting a temperature of the vapor phase,
The control means activates the auxiliary heating means at the same time that the heated object transport means starts lowering the heated object toward the vapor phase, and the vapor phase is changed based on an output signal of the temperature detection means. A heat treatment device is provided which controls to stop the operation of the auxiliary heating means when a predetermined temperature is reached. In the present invention, since the auxiliary heating means is operated at the same time that the object to be heated starts descending toward the vapor phase, the capacity for heating the solvent immediately before the object to be heated enters the vapor phase is increased. Therefore, the time delay until the heating effect occurs is reduced, the recovery time after steam collapse can be shortened, the recovery rate of the solvent can be improved, and the loss of the solvent can be reduced. Further, the amount of the solvent used is reduced, and the effect of cost reduction can be obtained in this aspect as well. The operation of the auxiliary heating means compensates for the amount of heat deprived from the vapor phase, and when the vapor phase surface returns to a predetermined level, the operation of the auxiliary heating means stops. This prevents the level of the vapor phase from increasing excessively and keeps the level of the vapor phase constant. As a result, the recovery rate of the solvent can be reliably improved, and the loss of the solvent can be effectively reduced.

According to the present invention, in addition to the above structure,
A heat treatment apparatus is provided, wherein the temperature detecting means comprises a thermocouple thermometer, and the thermocouple thermometer is disposed at a position substantially aligned with the vapor phase surface. In the present invention, since the temperature of the vapor phase is detected at the vapor phase surface, the level of the vapor phase surface is stably and reliably maintained. As a result, the recovery rate of the solvent can be more reliably improved, and the loss of the solvent can be more effectively reduced.

According to the present invention, in addition to the above configuration, there is further provided a heat treatment apparatus, wherein the auxiliary heating means comprises a plurality of heating elements. In the present invention, since the number of heating elements can be controlled while appropriately selecting the number of heating elements according to the state such as temperature, the control of the capacity for heating the solvent can be quickly and effectively performed according to the descending and rising of the object to be heated. It is possible to perform in a targeted manner. In addition, the level of the vapor phase is prevented from being excessively increased. As a result, the steam disintegration time is minimized, and the recovery rate of the solvent is further improved,
The loss of the solvent can be reduced more effectively.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a method and an apparatus for reducing a loss of a solvent constituted according to the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 shows an embodiment of a heat treatment apparatus constructed according to the present invention. The heat treatment apparatus includes a heat treatment tank, which can be formed from a metal material such as stainless steel, and is indicated by reference numeral 2 as a whole. A solvent is accommodated in a heat treatment tank 2 having a shape of a hollow rectangular cube having an open upper end and a closed lower end, and forms a liquid phase 4 of the solvent. As the solvent, an inert organic liquid which has an excellent boiling point stability and can appropriately select a type suitable for the treatment temperature of the object to be heated is suitably used.
Examples of the inert organic liquid include fluorine-based inert organic liquids such as perfluorotrialkylamine compounds, perfluoropolyethers, and perfluoroalicyclic compounds.

The bottom of the heat treatment tank 2 containing the solvent is provided with a main heater H1 as a heating means for constantly heating and boiling the solvent, and heating and boiling the solvent as necessary, as will be described later. Auxiliary heaters H2, H3, H4, and H5, which are auxiliary heating means for performing the heating, are provided. The main heater H1, and the auxiliary heaters H2, H3, H4, and H5, which are heating elements, are each formed of a well-known electric resistance heating unit. As the solvent is constantly heated and boiled by the main heater H1, a vapor phase 6 of the solvent is formed in a vertically stacked state above the liquid phase 4.

A cooling device 12 for maintaining the level of the vapor phase surface 8 of the vapor phase 6 substantially constant by balancing the amount of heat with the vapor phase 6 is provided in the upper part of the heat treatment tank 2. The cooling device 12 includes a cooling pipe 14 disposed substantially in a coil shape along an inner peripheral surface near an upper end portion in the heat treatment tank 2.
A cooling water tank 16 provided outside the heat treatment tank 2,
The cooling water tank 16 includes an introduction pipe 18 that supplies the cooling water into the cooling pipe 14, and a return pipe 19 that returns the cooling water supplied into the cooling pipe 14 into the cooling water tank 16. In the cooling water tank 16, a cooling means for cooling the cooling water in the cooling water tank 16 to a predetermined temperature, and a pump means for forcibly circulating the cooling water cooled by the cooling means (neither is shown) Are arranged. Cooling water tank 16
The cooling water inside is circulated through the introduction pipe 18, the cooling pipe 14, and the return pipe 19. The upper part in the heat treatment tank 2 is cooled by the cooling pipe 14, and the vapor phase 6 is formed.

Above the heat treatment tank 2, a heated object transport means for injecting and transporting an object to be heated 20 (for example, stainless steel whose surface is coated with a thermosetting resin) into and out of the vapor phase 6. 20 are provided. Heated object transfer means 2
2 is a holding means 24 for releasably holding the object 22 to be heated.
And lifting means (not shown) for vertically moving the gripping means 24. The elevating means can be constituted by, for example, a rodless pneumatic cylinder mechanism. The object to be heated 22 is moved up and down by the elevating means between a standby position shown by a solid line in FIG. 1 and a heated position in the vapor phase 6 shown by a two-dot chain line in FIG.

The heat treatment apparatus further includes a solvent recovery device 30 for recovering the solvent from the heat treatment tank 2. The solvent recovery device 30 includes a solvent recovery tank 32. The solvent recovery tank 32 and the heat treatment tank 2 are connected via a vapor suction pipe 34. Steam suction pipe 34
One end is opened in the solvent recovery tank 32, and the other end is opened above the vapor phase surface 8 in the heat treatment tank 2 at a predetermined interval D. In the solvent recovery device 32, there are provided suction means for sucking steam from the vapor phase 6 through a steam suction pipe 34, and cooling means for condensing the sucked steam (both are shown). Zu). The vapor from the vapor phase 6 is sucked into the solvent recovery tank 32 through the vapor suction pipe 34 by the suction means, and is condensed by the cooling means, and is recovered as the solvent in the solvent recovery tank 32.

With reference to FIG. 1 and FIG. 2, the heat treatment apparatus includes a thermocouple thermometer S which is a temperature detecting means for detecting the temperature of the vapor phase 6, The amount of heat deprived of the vapor phase 6 by the entry of the object 22 only during the heat treatment step carried out from the vapor phase 6 after descending toward the inside and entering the vapor phase 6 to be heated. So that the auxiliary heaters H2, H3, H
4 and H5.
The thermocouple thermometer S is disposed in the heat treatment tank 2 at a position substantially aligned with the vapor phase surface 8. The control means 40 composed of a microcomputer activates the auxiliary heaters H2, H3, H4 and H5 at the same time as the heating object transporting means 20 starts lowering the heating object 22 toward the vapor phase 6,
The amount of heat deprived from the vapor phase 6 due to the entry of the article to be heated 22 is compensated for, and based on the output signal of the thermocouple thermometer S, when the vapor phase 6 reaches a predetermined temperature (when it returns), the auxiliary heater Control is performed to stop the operations of H2, H3, H4, and H5.

The total heating capacity of the auxiliary heaters H2, H3, H4 and H5 is set so as to correspond at least to the amount of heat taken by the object 22 to be heated from the vapor phase 6. SW of FIG.
Indicates an operation switch of the lifting / lowering means of the heated object transporting means 20. When the operation switch SW is turned ON,
This signal is output to the control means 40, and the control means 40
On the basis of the ON operation signal of the operation switch SW, an output signal is sent to the elevating / lowering means of the object-to-be-heated conveying means 20 to start descending, and the auxiliary heaters H2, H3, H4 and H
5 and output them to ON.

When the operation switch SW of the lifting / lowering means of the object-to-be-heated conveying means 20 is turned on, the object-to-be-heated 22 starts to descend. At the same time, the auxiliary heaters H2, H3, H4 and H5 are turned on by the operation of the control means 40. In addition to the operation of the main heater H1 which is always operated, the auxiliary heater H
2, H3, H4 and H5 actuation increases the solvent heating capacity. When the object 22 enters the vapor phase 6, the object 22 is heated by the heat of condensation of the vapor phase 6. The amount of heat corresponding to the amount of heat to be heated by the object to be heated 22 is deprived, and the level of the vapor phase surface 8 is instantaneously reduced. However, since the capacity for heating the solvent is increased as described above, the vapor phase surface 8 is increased. Levels recover rapidly. When the thermocouple thermometer S detects that the temperature of the vapor phase 6 has reached a predetermined temperature, the auxiliary heater H
2, H3, H4 and H5 are turned off, and their heating operation is stopped. The solvent is heated only by the main heater H1.

During this time, the operation of the solvent recovery device 30 causes
The vapor from the vapor phase 6 is recovered in the solvent recovery tank 32 via the vapor suction pipe 34. The level of the vapor phase surface 8 is temporarily lowered by the entry of the object 22 to be heated, but since the capacity of heating the solvent is increased by the operation of the auxiliary heaters H2, H3, H4, and H5, the amount of decrease in the level is reduced. And the decrease time is reduced as compared with the conventional device. The reduction in the level of the vapor phase surface 8 is reduced because the spread of the predetermined distance D between the opening of the vapor suction pipe 34 and the vapor phase surface 8 is reduced as compared with the related art. Reducing the fall time of the surface 8 level means reducing the steam collapse time. As a result, the recovery of steam, that is, the solvent, is improved.

The auxiliary heaters H2, H3, H4 and H5 are:
After the object to be heated 22 descends toward the vapor phase 6 and enters the vapor phase 6 and is heated by the action of the control means 40,
While the heating process carried out from the vapor phase 6 is performed, it is controlled to operate so as to compensate for the amount of heat deprived from the vapor phase 6 due to the entry of the object 22 to be heated. There is no need to increase the capacity of the main heater H1 for boiling (the capacity may be the same as before), and thus it is not necessary to increase the capacity of the cooling device 12. As a result, it is possible to minimize the steam collapse time, increase the solvent recovery rate, and reduce the amount of solvent loss at a relatively low cost without increasing the size of the entire heat treatment apparatus. By reducing the loss amount of the solvent, the amount of the solvent used is reduced, and the cost reduction effect can be obtained in this aspect as well.

When the heated object 22 stopped at the heated position in the vapor phase 6 is heated at a predetermined temperature for a predetermined time, the heated object 22 is raised by the heated object conveying means 20, and
It is carried out of the vapor phase 6 and stopped at the standby position. Thus, the predetermined heating process of the object to be heated 22 is completed. In this embodiment, as described above, the operation of raising and lowering the heated object transporting means 20 is also controlled by the control means 40.

[0027]

Next, an embodiment of the present invention using the above-mentioned heat treatment apparatus will be described. A perfluorotrialkylamine (C ₄ F ₉ ) ₃ N was used as a solvent as a heating medium.
Heat treatment was performed to cure a resin-based paste containing a thermosetting resin on the surface of 1 kg of stainless steel (specific heat = 0.115). The temperature at which the stainless steel enters the vapor phase 6 is 50 ° C., and the carry-out temperature is 178, which is the boiling point of the perfluorotrialkylamine contained in the heat treatment tank 2.
° C, main heater H1, auxiliary heaters H2, H3, H4 and H
5 has a capacity of 12 kW (the total capacity of the auxiliary heaters H2 to H5 is 48 kW), and the main heater H1 has a capacity of 48 kW.
The heating temperature of each of the liquid phase 4 and the vapor phase 6 is 178
° C, height h1 of liquid phase 4 is 300 mm, height h of vapor phase 6
2 is 1,000 mm, the vapor phase surface 8 and the vapor suction pipe 34
The distance D from the opening of the stainless steel is 10 mm, the time from the start of the lowering of the stainless steel until it completely enters the vapor phase 6 and is positioned at the position to be heated is about 20 seconds, and the heating time is 300 minutes.
Seconds and the unloading time were 60 seconds.

As a result of performing the heat treatment on the stainless steel under the above conditions, the steam collapse time t was 27 seconds.
As a result of performing a heat treatment by using a conventional heat treatment apparatus having only the main heater H1 as a means for heating the solvent under the same conditions as the above, the vapor collapse time t was 134 seconds. With only the 12 kw main heater H1 normally provided in the conventional heat treatment apparatus, 1.96 kg / m ² · Hr. Of the inert organic liquid, but according to the heat treatment apparatus of the present invention to which the auxiliary heaters H2 to H5 were added, the loss amount was 0.4 kg / m ² · Hr. Thus, the loss amount can be reduced to about 20% compared to the conventional device (and method).

Incidentally, the loss amount of the inert organic liquid as the solvent depends on the amount of the inert organic liquid in the heat treatment tank 2 and the amount of the inert organic liquid recovered in the solvent recovery tank 32 of the solvent recovery unit 30. Can be easily obtained from the sum of The measurement of the loss amount of the inert organic liquid is performed in a state where the operation of the heat treatment apparatus is stopped and the inert organic liquid is cooled to room temperature.

In the above-mentioned heat treatment apparatus, the loss amount of the inert organic liquid can be reduced to about 20% of the conventional apparatus,
Since the cooling capacity of the cooling device 12 does not need to be increased and the cooling device 12 can be used as it is, the running cost is increased by the power consumption of 3.6 k during the time when the auxiliary heaters H2 to H5 are operated.
Only wH, total running cost is about 75
% Savings.

The vapor collapse time t, which is the time required for the vapor phase surface 8 of the vapor phase 6 to fall from the predetermined level and return to the predetermined level, is obtained by the following equation. t = {W × c × (T ₂ −T ₁ ) × 3600 (seconds)} / Q In the above equation, t: steam collapse time (seconds) W: weight of the object to be heated (kg) c: weight of the object to be heated Specific heat (kcal / kg · ° C.) T ₂ : Temperature at which the heated object enters the vapor phase (° C.) T ₁ : Temperature at which the heated object is carried out of the vapor phase (° C.) Q: Heating capacity [total Heater capacity x 860 x 0.8] (kca
1 / Hr. ) Respectively. In the heating capacity Q, the unit of the total heater capacity is kw, the numerical value 860 is a calorie conversion coefficient,
The value 0.8 indicates the power factor.

In the above-described heat treatment apparatus, four auxiliary heaters H2 to H5 are used, and the number is appropriately selected according to the scale of the heat treatment apparatus. Also, the operation control of the auxiliary heater by the control means may be performed while appropriately selecting the number in addition to the case where all the numbers are simultaneously performed as in the above embodiment. By controlling the operation while appropriately selecting the number of the auxiliary heaters, more accurate supplementary heating control can be performed.

In a soldering apparatus, a melt phase of solder, a liquid phase of a solvent such as an inert organic liquid, and a vapor phase of a solvent are sequentially arranged in a lamination form from the bottom in a heat treatment tank. . When the present invention is applied to such a soldering apparatus, the main heater H1 is disposed in the solder melt phase, but the auxiliary heaters H2 to H5 are not located in the solder melt phase. It is preferred to be arranged in the liquid phase of the solvent. With such an arrangement, heating of the solvent is quickly performed.

[0034]

According to the method and apparatus for reducing the amount of solvent loss according to the present invention, the overall apparatus is not increased in size, the cost is relatively low, the vapor disintegration time is minimized, and the solvent recovery rate is improved. As a result, the loss of the solvent can be reduced. Further, the amount of the solvent used is reduced, and cost reduction in this aspect is achieved.

[Brief description of the drawings]

FIG. 1 is a configuration diagram schematically showing an embodiment of a heat treatment apparatus configured according to the present invention.

FIG. 2 is a schematic diagram showing a configuration of a control unit and related members configured according to the present invention.

[Explanation of symbols]

 2 Heat treatment tank 4 Liquid phase 6 Vapor phase 8 Vapor phase surface 12 Cooling device 14 Cooling pipe 20 Heated object conveying means 22 Heated object 30 Solvent recovery device 34 Steam suction pipe H1 Main heater H2 to H5 Auxiliary heater S Thermocouple temperature Total

Claims (6)

[Claims] In a heat treatment for heating and boiling a solvent to form a vapor phase and heating the object to be heated using the vapor phase as a heating medium, the object to be heated moves toward the vapor phase and the vapor During the heat treatment step of entering the phase and being heated and then carried out of the vapor phase, the solvent is heated so as to compensate for the amount of heat deprived from the vapor phase due to the entry of the object to be heated. A method for reducing the amount of solvent loss, characterized by increasing the capacity of the solvent. 2. The amount of solvent lost according to claim 1, wherein the object to be heated starts moving toward the vapor phase to enter the vapor phase, and at the same time increases the capacity of heating the solvent. Reduction method. 3. A heat treatment tank, a liquid phase of a solvent contained in the heat treatment tank, a vapor phase of the solvent formed vertically above the liquid phase, and a constant heating and boiling of the solvent. Heating means for forming the vapor phase, and a cooling device disposed so that the height of the vapor phase surface of the vapor phase is kept substantially constant by a heat amount balance with the vapor phase; The apparatus further includes a heated object transporting means for moving the heated object into and out of the vapor phase, and a solvent recovery device for recovering a solvent from the heat treatment tank. And a vapor suction pipe having one end opened into the solvent recovery tank and the other end opened at a predetermined interval above the vapor phase surface. Auxiliary heating means for increasing pressure, and the object to be heated moves toward the vapor phase. The auxiliary heating is performed so as to compensate for the amount of heat deprived from the vapor phase due to the entry of the object to be heated while the heat treatment step of entering the vapor phase and being heated and then carried out of the vapor phase is performed. Control means for controlling the operation of the means. 4. A temperature detecting means for detecting a temperature of the vapor phase, wherein the control means starts the lowering of the object to be heated toward the vapor phase by the means for conveying the object to be heated, and the auxiliary means simultaneously. 4. The heat treatment apparatus according to claim 3, wherein the heating means is operated, and based on an output signal of the temperature detection means, control is performed such that the operation of the auxiliary heating means is stopped when the vapor phase reaches a predetermined temperature. 5. The heat treatment apparatus according to claim 4, wherein said temperature detecting means comprises a thermocouple thermometer, and said thermocouple thermometer is disposed at a position substantially aligned with said vapor phase surface. 6. The heat treatment apparatus according to claim 4, wherein said auxiliary heating means comprises a plurality of heating elements.