CN103813497A - Cable for high temperature and heat treatment device using the same - Google Patents

Abstract

The invention relates to a cable for high temperature and a heat treatment device using the same. The cable for high temperature comprises a transmission part, where power is transmitted; an insulation part sealing the transmission part; a metal tube sealing the insulation part; and a sealing part sealing the end part of the metal tube.

Description

High-temperature cable and use the equipment for Heating Processing of this high-temperature cable

Technical field

The present invention relates to the equipment for Heating Processing of a kind of high-temperature cable and this high-temperature cable of use, more specifically, relating to a kind of electric power that can suppress or prevent heat that heater radiates and conveying produces to disturb and can suppress or prevent and in chamber, produces the high-temperature cable of impurity or flue dust and use the equipment for Heating Processing of this high-temperature cable due to the heat of radiation.

Background technology

Conventionally, high-temperature cable is manufactured to resistant to elevated temperatures electric wire and is coated with for the glass fibre of trap heat at high temperature.

In the time that high-temperature cable is used in equipment for Heating Processing, owing to covering the glass fibre of electric wire and cause the radiation of heat, impurity or flue dust can produce in chamber thus, thereby cause the infringement to heat treatment target.

In the prior art, the Korean Utility Model (announcing and " only using the structure (Structure of electrical cable using only thermocouple) of the cable of thermocouple " by name on April 16th, 2009) that number of registration is 20-0444267 discloses a kind of cable.

Summary of the invention

The present invention aims to provide a kind of heat and the electric power generation interference of conveying and equipment for Heating Processing that can suppress or prevent to produce the high-temperature cable of impurity or flue dust due to the heat of radiation in chamber and use this high-temperature cable that can suppress or prevent that heater from radiating.

According to an aspect of the present invention, high-temperature cable comprises: conducting part, and electric power is transported to conducting part; Insulation division, this insulation division is sealed conducting part; Metal tube, this metal tube is sealed insulation division; And sealing, sealing portion seals the end of metal tube.

According to a further aspect in the invention, equipment for Heating Processing comprises: chamber, and this chamber provides the space of heat-treating adding thermal target; Heater, this heater is placed in chamber with to heating target radiation heat; Organism component, this organism component is contained in chamber and holds and adds thermal target and heater; Supporting member, this supporting member is set on organism component to add thermal target and heater is separated; And high-temperature cable, this high-temperature cable is contained in chamber and is electrically connected to heater, to transmit electric power to heater in the case of not occurring to disturb with the heat of radiation.

Heater can comprise: heating unit, and this heating unit is divided into the heating region of radiate heat and two relative extended nominal regions in end from heating region; Compensating unit, this compensating unit is divided into that join domain extends with from two relative ends of join domain and the compensatory zone of radiate heat; And fixed cell, heating unit and compensating unit are fixed to this fixed cell.

In each heating region and compensatory zone, all can be formed with the reflector that heat is reflected, to heat is emitted to be arranged on the thermal target that adds of heater below.

Supporting member can comprise: cramp bar, and this cramp bar is connected on organism component; And fulcrum post unit, this fulcrum post unit is set on cramp bar and to adding thermal target and supports.

Equipment for Heating Processing may further include sliding component, and chamber is connected to organism component to this sliding component so that organism component enters or leave chamber.

Sliding component can comprise: ways, and this ways is set to chamber and forms the sliding path of organism component; And moving link, this moving link is set on organism component and along ways and moves.

Chamber can comprise: housing, and this housing forms the space of carrying out hot place amount to adding thermal target; And door, this door is removably connected to housing to open or close described space.

Equipment for Heating Processing may further include sliding component, and organism component is attached to housing by this sliding component, and organism component in the time opening or closing described space is slided with respect to housing.

Sliding component can comprise: ways, and this ways is set to chamber and forms the sliding path of organism component; And moving link, this moving link is set on organism component and along ways and moves.

Equipment for Heating Processing may further include locking component, and the closed condition in described space is set or removed to this locking component.

Equipment for Heating Processing may further include fixed component, and this fixed component is connected to housing and in the time opening or closing described space, door is supported.

Equipment for Heating Processing may further include path component, and door is connected to fixed component by this path component, and while opening or closing described space with box lunch, door is slided with respect to fixed component.

Path component can comprise: ways, and this ways is set on fixed component and forms the sliding path of door; And transporting member, this transports member and is set in door and along ways and moves.

Locking component can comprise: latch member, and this latch member is selected lock-out state; And first locking component, latch member connects and locks onto this first locking component.

Locking component may further include the second locking component, and this second locking component to be to be set on described fixed component with the separated mode of described the first locking component, so that latch member connects and locks onto this second locking component.

Latch member can comprise: claw, and this claw connects and locks onto the first locking component; And make the reciprocating claw drive division of claw.

Add thermal target and be divided into multiple control areas, make described control area there is different Temperature Distribution mutually along the direction of arranging heater.

Equipment for Heating Processing may further include: temperature sensing unit, and this temperature sensing unit detects the temperature corresponding with described control area; And controller, the heat that this controller regulates the heater corresponding with described control area to radiate according to the temperature being detected by described temperature sensing unit.

According to high-temperature cable of the present invention and use the electric power of heat that the equipment for Heating Processing of this high-temperature cable can suppress or prevent that heater from radiating and conveying to produce to disturb and can suppress or prevent to produce impurity or flue dust due to the heat of radiation in the space of chamber.

In addition,, according to the present invention, can prevent from interfering with chamber in the space that is routed in chamber of heater.

In addition,, according to the present invention, can improve the insulation effect and the heat treatment performance that adds thermal target of chamber.

In addition,, according to the present invention, be easy to individually heater safeguarded and replaced.

In addition, according to the present invention, can load easily and unloading adds thermal target, and can prevent or suppress to add the surface damage of thermal target.

In addition, according to the present invention, can by the modularization of temperature compensation heater by heat substantially Transmit evenly to the edge that adds thermal target.

In addition, according to the present invention, by twin heater, can easily realize independent temperature control and can by substantially uniformly heat be delivered to the edge that adds thermal target.

In addition, according to the present invention, can easily assemble heater, and can be in the region of radiate heat not by electrical power stabilization be transported to heating wires.

In addition, according to the present invention, can easily and easily lead-in wire be fixed and suppress or prevent that it from rotating, can prevent the short circuit of electrical connection, and can suppress or prevent the rotation of heating wires.

In addition,, according to the present invention, in the case of not having any independent supporting structure, can prevent that heating wires and connector from rotating in the region of radiate heat neutralizes the region of radiate heat not.

Accompanying drawing explanation

In conjunction with the drawings following examples are described in detail, above-mentioned and other side of the present invention, feature and advantage will become more apparent, in the accompanying drawings:

Fig. 1 is the sectional view of high-temperature cable according to an embodiment of the invention;

Fig. 2 is the sectional view of high-temperature cable according to another embodiment of the present invention;

Fig. 3 is the front view of equipment for Heating Processing according to an embodiment of the invention;

Fig. 4 is the end view of equipment for Heating Processing according to an embodiment of the invention;

Fig. 5 is the perspective view of temperature compensation heater according to an embodiment of the invention;

Fig. 6 is the decomposition diagram of the temperature compensation heater of Fig. 5;

Fig. 7 is the sectional view of temperature compensation heater according to an embodiment of the invention;

Fig. 8 is the end view of fixed cell according to an embodiment of the invention;

Fig. 9 is the sectional view of the coupled situation of temperature compensation heater according to an embodiment of the invention;

Figure 10 is the sectional view of the coupled situation of temperature compensation heater according to another embodiment of the present invention;

Figure 11 is the partial, exploded perspective view of supporting member according to an embodiment of the invention;

Figure 12 shows the mode of operation of the supporting member in equipment for Heating Processing according to an embodiment of the invention;

Figure 13 shows the mode of operation of equipment for Heating Processing according to an embodiment of the invention;

Figure 14 and Figure 15 show the closed condition of the chamber of equipment for Heating Processing according to an embodiment of the invention;

Figure 16 and Figure 17 show the open mode of the chamber of equipment for Heating Processing according to an embodiment of the invention;

Figure 18 is the fragmentary, perspective view of the locking component of equipment for Heating Processing according to an embodiment of the invention;

Figure 19 is the end view that heat treatment according to another embodiment of the present invention arranges;

Figure 20 shows the thermal target that adds that is divided into multiple control areas according to an embodiment of the invention;

Figure 21 shows temperature compensation heater in equipment for Heating Processing according to an embodiment of the invention, that arrange according to the division situation that adds thermal target; And

Figure 22 shows temperature compensation heater in equipment for Heating Processing according to another embodiment of the present invention, that arrange according to the division situation that adds thermal target.

Embodiment

Hereinafter, with reference to the accompanying drawings embodiments of the invention are described.It should be pointed out that accompanying drawing is not by accurate scale, and convenient and clear just to describing, and the thickness of the line in accompanying drawing or the size of parts will be exaggerated.

In addition, term used herein defines and can change according to user or operator's custom or intention by considering function of the present disclosure.Therefore, the definition of term should be formulated according to the whole disclosures that propose herein.

Hereinafter will be described high-temperature cable according to an embodiment of the invention.

Fig. 1 is the sectional view of high-temperature cable according to an embodiment of the invention.

With reference to Fig. 1, high-temperature cable 800 according to an embodiment of the invention is placed in chamber 100 and is electrically connected to heater 200, makes in the time that electric power is transported to heater, can suppress or prevent the interference causing due to the heat of heater radiation.

High-temperature cable 800 comprises conducting part 810, insulation division 830, metal tube 850 and containment member 870.

Conducting part 810 is electrically connected to heater so that electric power is delivered to heater.Conducting part 810 can be formed by copper or aluminium.Conducting part 810 can be electrically connected at least one in heating lead-in wire 370 and compensating lead wire 470 by connecting elements 880.

Insulation division 830 is sealed conducting part.Insulation division 830 can intercept from the heat of heater radiation, thereby prevents that heat is delivered to conducting part 810, and can shield the electric power mobile along conducting part 810.Insulation division 830 can comprise the magnesium oxide as mineral insulating material.

Metal tube 850 is sealed insulation division 830.Metal tube 850 can prevent the distortion or the damage that cause because of the heat of heater radiation.Metal tube 850 can be formed by stainless steel.

Containment member 870 seals two relative ends of metal tube 850.Containment member 870 prevents that insulation division 830 is outside the relative end of metal tube 850 is exposed to.Containment member 870 is formed and is welded to respectively relative two ends of metal tube 850 by quartz or glass.

Hereinafter, will high-temperature cable be according to another embodiment of the present invention described.

Fig. 2 is the sectional view of high-temperature cable according to another embodiment of the present invention.

With reference to Fig. 2, be placed in chamber 100 and be electrically connected to heater 200 according to the high-temperature cable 800 of another embodiment, make in the time that electric power is transported to heater 200, can suppress or prevent the interference causing due to the heat of heater radiation.

High-temperature cable 800 comprises conducting part 810, insulation division 830, metal tube 850, containment member 870 and attachment members 820.

Conducting part 810 is electrically connected to heater to transmit electric power to heater.Conducting part 810 can be formed by copper or aluminium.Conducting part 810 can be electrically connected at least one in heating lead-in wire 370 and compensating lead wire 470 by connecting elements 880.

Insulation division 830 is divided into two or more parts, and the part being divided into arranges to seal conducting part 810 along the longitudinal direction of conducting part 810.Insulation division 830 can stop heat to be delivered to conducting part 810 from heater, and can shield worn-out along the mobile electric power of conducting part 810.Insulation division 830 can comprise pottery or the magnesium oxide as mineral based insulation material.

Metal tube 850 is sealed insulation division 830.Metal tube 850 can prevent the distortion or the damage that cause because of the heat of heater radiation.Metal tube 850 can be formed by stainless steel.

Containment member 870 seals two relative ends of metal tube 850.Containment member 870 prevents that insulation division 830 is outside the relative end of metal tube 850 is exposed to.Containment member 870 can be formed by pottery, quartz or glass, and can be welded to respectively two relative ends of metal tube 850.In addition, containment member 870 can be formed and can be connected to respectively by the ceramic material that is sleeve-like two relative ends of metal tube 850.

Each attachment members 820 is all connected to an end of conducting part 810, so that insulation division 830, metal tube 850 and containment member 870 are fixed to conducting part 810.

Attachment members 820 thread connection are to two relative ends of conducting part 810 to containment member 870 is fixed to metal tube 850 with the state of close contact.On conducting part 810, screw thread can be formed with to carry out and being threadedly engaged with of sealing 820.

Hereinafter, will be described equipment for Heating Processing according to an embodiment of the invention.

Fig. 3 is the front view of equipment for Heating Processing according to an embodiment of the invention; Fig. 4 is the end view of equipment for Heating Processing according to an embodiment of the invention; Fig. 5 is the perspective view of temperature compensation heater according to an embodiment of the invention; Fig. 6 is the decomposition diagram of the temperature compensation heater of Fig. 5; Fig. 7 is the sectional view of temperature compensation heater according to an embodiment of the invention; Fig. 8 is the end view of fixed cell according to an embodiment of the invention; Fig. 9 is the sectional view of the coupled situation of temperature compensation heater according to an embodiment of the invention; Figure 10 is the sectional view of the coupled situation of temperature compensation heater according to another embodiment of the present invention; Figure 11 is the partial, exploded perspective view of supporting member according to an embodiment of the invention; Figure 12 shows the mode of operation of the supporting member in equipment for Heating Processing according to an embodiment of the invention; Figure 13 shows the mode of operation of equipment for Heating Processing according to an embodiment of the invention; Figure 14 and Figure 15 show the closed condition of the chamber of equipment for Heating Processing according to an embodiment of the invention; Figure 16 and Figure 17 show the open mode of the chamber of equipment for Heating Processing according to an embodiment of the invention; And Figure 18 is the fragmentary, perspective view of the locking component of equipment for Heating Processing according to an embodiment of the invention.

With reference to Fig. 3 to Figure 18, comprise chamber 100, heater 200, organism component 600, supporting member 700 and high-temperature cable 800 according to the equipment for Heating Processing of embodiment, and equipment for Heating Processing can for the heat by from heater 200 to add thermal target M(be contained in organism component 600 and by supporting member 700 support) heat-treat.

According in the equipment for Heating Processing of the present embodiment, add thermal target M and be contained in organism component 600, supporting member 700 supports the lower surface that adds accordingly thermal target M, and heater 200 is arranged on and adds thermal target M top.In the time that electric power inputs to heater 200, the heat that heater 200 radiates can be heat-treated the top that adds thermal target M.

Reflector 201 is set to heating region 301 and the compensatory zone 401 of heater 200, so that the heat that reflection heater 200 radiates.What reflector 201 can be radiated to heat to be arranged on heater 200 belows adds thermal target M.

In the situation that adding thermal target M and being stacked, raise because of thermal expansion when adding thermal target M, the heat of radiation can carry out the heat treatment of less important ground to the bottom that adds thermal target M.

Chamber 100 defines the space of heat-treating adding thermal target M.Therefore, heater 200, organism component 600 and supporting member 700 are contained in chamber 100.

Chamber 100 comprises housing 110 and door 130.

Housing 110 is for limiting the casing to adding the space that thermal target M heat-treats, and door 130 is removably connected to housing 110 to open or close this space.

The closed condition in this space being limited by housing 110 and door 130 can will hereinafter be described by locking component 1000() set or remove.

Heater 200 is radiated to heat to add accordingly thermal target M, to heat-treat adding thermal target M.

Heater 200 is temperature compensation heater, and provides substantially uniformly Temperature Distribution to improve heat treatment performance to adding thermal target M.

Each temperature compensation heater 200 includes heating unit 300, compensating unit 400 and fixed cell 500.

Heating unit 300 can be divided into heating region 301 and the relative extended nominal region 303 in two ends from heating region 301.Input electric power be transported to heating region 301 from nominal region 303, and by input electric power and from heating region 301 radiate heat.

Heating region 301 can be formed with the reflector 201 for reflecting radiated heat.The heat radiating from heating region 301 can be concentrated to and be added thermal target M by reflector 201.The distortion that reflector 201 is caused due to radiated heat by opposing and the material of oxidation form.In addition, reflector 201 is constructed to: prevent reflection efficiency because of radiation heat deteriorated.

In one embodiment, reflector 201 can form and be positioned on heating tube 310 by gold.More specifically, at 400 ℃ or higher temperature, golden reflector 201 can not be out of shape and prevent the deteriorated of reflection efficiency.

As shown in Figure 7 (a), reflector 201 can be formed on the inwall of heating tube 310.Reflector 201 can prevent the damage of being swiped because of external impact on the inwall of heating tube 310.In addition, as shown in Figure 7 (b), reflector 201 can be formed on the outer wall of heating tube 310.Reflector 201 can be easily deposited on the outer wall of heating tube 310.

Although in the present embodiment, reflector 201 forms by deposition, the invention is not restricted to this, and reflector 201 can be formed on heating tube 310 by various methods well known in the prior art.

Heating unit 300 can comprise heating tube 310, heating wires 330, heated connector 350 and heating lead-in wire 370.

Heating tube 310 is hollow form and is divided into heating region 301 and nominal region 303.Heating tube 310 can easily give off radiated heat, can prevent because radiated heat is damaged or distortion and can being formed by transparent or semitransparent material.In one embodiment, heating tube 310 can be transparent or semitransparent hollow quartz tube or transparent or semitransparent double glazing pipe.

Heating wires 330 is inserted in heating tube 310 with heat corresponding with heating region 301 and that radiation is produced by the electric power of inputting.Add thermal target M and can be heated the heat heating that wire 330 radiates.In one embodiment, heating wires 330 can be made up of Kan Saer resistance heating wire (Kanthal resistive heating wire).

Heated connector 350 is electrically connected to heating wires 330 with corresponding with nominal region 303.Heated connector 350 is inserted in heating tube 310 electrical power stabilization to make input and is transported to heating wires 330, and has prevented that the heat that heated connector 350 radiates because of heating wires 330 is out of shape or damages.

Among heating wires 330 and heated connector 350, at least heating wires 330 can be formed helical form.Due to heating wires 330 at least in the shape of a spiral, therefore heating wires 330 and heated connector 350 can be stably inserted in heating tube 310, and can prevent the electrical connections short circuit between heating lead-in wire 370, heated connector 350 and heating wires 330.

Because nominal region 303 is shaped as enough short of length, so as not with interfering according to the motion of the heated connector 350 in the temperature compensation heater 200 of the present embodiment, therefore can only make heating wires 330 be formed as helical form.But it is favourable that heating wires 330 and heated connector 350 are both configured as to helical form.

When not becoming shape and being helical form, heating wires 330 and heated connector 350 both downward deflections of meeting under the state that is inserted in heating tube 310, thereby cause the temperature distributing disproportionation of the heat radiating from heater 200 even, and cause the electrical connection section between heating lead-in wire 370, heated connector 350 and heating wires 330 to break.

Heating lead-in wire 370 is used as the terminal transmitting electric power to heating wires 330.Heating lead-in wire 370 is electrically connected to heated connector 350 and is fixed to fixed cell 500.

Each heating lead-in wire 370 includes heating fixed part 371 and heating terminal 373.

Heating fixed part 371 is electrically connected to corresponding heated connector 350 and is inserted in corresponding fixed cell 500.Because heating fixed part 371 is inserted in fixed cell 500, therefore heat fixed part 371 and can prevent the rotation of heating lead-in wire 370.

Heating fixed part 371 can be shaped as the various shapes except round-shaped.In one embodiment, heating fixed part 371 can be hexagonal shape.

Independent terminal can be outstanding from heating fixed part 371, to be convenient to be electrically connected to heated connector 350.

Heating terminal 373 is outstanding from heating fixed part 371.Heating terminal 373 exposes to be connected to corresponding high-temperature cable 800 from fixed cell 500.Heating terminal 373 can stably be connected to high-temperature cable 800(by connecting elements 880 and will hereinafter be described).Should be understood that, the invention is not restricted to connecting elements 880, and cable 800 and heating stable connection the between terminal 373 can be by various methods realizations well known in the prior art.

Heating lead-in wire 370 may further include heating connection part 375.

Heating connection part 375 is connected to heating terminal 373 so that heating fixed part 371 close contact fixed cells 500.In one embodiment, the heating connection part 375 that is nut type can thread connection arrive from the outstanding heating terminal 373 of heating fixed part 371.Therefore, heating can be formed with the screw thread for being threadedly engaged with heating connection part 375 on terminal 373.

When heating connection part 375 when terminal 373, is heated fixed part 371 and can prevent from heating the rotation of terminal 373, thereby prevent the rotation of heating wires 330 and heated connector 350 to heating by thread connection.

Compensating unit 400 can be divided into compensatory zone 401 and the relative extended compensatory zone 401 in two ends from compensatory zone 401.Input electric power be transported to compensatory zone 401 from join domain 403, and by input electric power from compensatory zone 401 radiate heat.

Compensatory zone 401 can be formed with the reflector 201 that the heat of radiation is reflected.The heat radiating from compensatory zone 401 can be concentrated to and be added thermal target M by reflector 201.Reflector 201 by opposing because the distortion that produces of heat of radiation and the material of oxidation form.In addition, reflector 201 is configured to: prevent reflection efficiency because of the radiation of heat deteriorated.

In one embodiment, compensating unit 400 can be divided into the join domain corresponding with heating region 301 403 and the compensatory zone 401 corresponding with nominal region 303.

In one embodiment, reflector 201 can be made of gold and be positioned on compensating pipe 410.More specifically, at 400 ℃ or higher temperature, golden reflector 201 can not be out of shape and prevent the deteriorated of reflection efficiency.

As shown in Figure 7 (a), reflector 201 can be formed on the inwall of compensating pipe 410.Reflector 201, on the inwall of compensating pipe 410, can prevent the damage of being swiped because of external force.In addition, as shown in Figure 7 (b), reflector 201 can be formed on the outer wall of compensating pipe 410.Reflector 201 can be easily deposited on the outer wall of compensating pipe 410.

Although in the present embodiment, reflector 201 forms by deposition, the invention is not restricted to this, and reflector 201 can be formed on compensating pipe 410 by various methods well known in the prior art.

Compensating unit 400 can comprise compensating pipe 410, thermal compensation wire 430, compensation connector 450 and compensating lead wire 470.

Compensating pipe 410 is hollow form and is divided into join domain 403 and compensatory zone 401.Compensating pipe 410 can easily give off radiated heat, can prevent from damaging or being out of shape and can being formed by transparent or semitransparent material because of the heat of radiation.In one embodiment, compensating pipe 410 can be transparent or semitransparent hollow quartz tube or transparent or semitransparent double glazing pipe.

In one embodiment, heating tube 310 and compensating pipe 410 can have identical size and can be formed by identical material.

Thermal compensation wire 430 is inserted in compensating pipe 410 and relies on the input of electric power and produce heat with and radiation corresponding with compensatory zone 401.Adding the heat that thermal target M can radiate by thermal compensation wire 430 heats.More specifically, add the heat marginal portion of thermal target M being radiated by thermal compensation wire 430 and heat, the Temperature Distribution that makes to add between marginal portion and the middle body of thermal target M can be substantially uniform.In one embodiment, thermal compensation wire 430 Ke Yi Wei Kan Saer compensating wires (Kanthal compensation wires).

Compensation connector 450 is electrically connected to thermal compensation wire 430 with corresponding with join domain 403.Compensation connector 450 is inserted in compensating pipe 410 electrical power stabilization to make input and is transported to thermal compensation wire 430, and has prevented that the heat that compensation connector 450 radiates because of thermal compensation wire 430 is out of shape or damages.

Among thermal compensation wire 430 and compensation connector 450, at least thermal compensation wire 430 can be shaped as helical form.Due to thermal compensation wire 430 at least in the shape of a spiral, therefore thermal compensation wire 430 and compensation connector 450 can be stably inserted in compensating pipe 410, and can prevent the electrical connections short circuit between compensating lead wire 470, compensation connector 450 and thermal compensation wire 430.

Due to according in the temperature compensation heater 200 of embodiment, compensatory zone 401 is shaped as has shorter length for adding the width of thermal target M or length, and therefore compensation connector 450 can deflection downwards in join domain 403.Thereby thermal compensation wire 430 and compensation connector 450 both can be shaped as helical form.But, consider the length of compensatory zone 401 and the length of join domain 403, only thermal compensation wire 430 can be formed as helical form.

When not becoming shape and being helical form, thermal compensation wire 430 and compensation connector 450 both downward deflections of meeting under the state that is inserted in compensating pipe 410, thereby cause Temperature Distribution inhomogeneous of the heat radiating from heater 200, and cause the electrical connection section between compensating lead wire 470, compensation connector 450 and thermal compensation wire 430 to break.

Compensating lead wire 470 is used as the terminal that thermotropism compensating wire 430 transmits electric power.Compensating lead wire 470 is electrically connected to compensation connector 450 and is fixed to fixed cell 500.

Each compensating lead wire 470 includes compensation fixed part 471 and compensation terminal 473.

Compensation fixed part 471 is electrically connected to thermal compensation wire 430 and is inserted in corresponding fixed cell 500.Because compensation fixed part 471 is inserted in fixed cell 500, therefore compensate fixed part 471 and can prevent the rotation of compensating lead wire 470.

Compensation fixed part 471 can be shaped as the various shapes except round-shaped.In one embodiment, compensation fixed part 471 can be hexagonal shape.

Independent terminal can be outstanding from compensation fixed part 471, to be convenient to be electrically connected to thermal compensation wire 430.

Compensation terminal 473 is outstanding from compensation fixed part 471.Compensation terminal 473 exposes to be connected to power supply from fixed cell 500.Compensation terminal 473 can stably be connected to high-temperature cable 800(by connecting elements 880 and will hereinafter be described).Should be understood that, the invention is not restricted to connecting elements 880, and high-temperature cable 800 and stable be connected of compensation between terminal 473 can stably realize by various methods well known in the prior art.

Compensating lead wire 470 may further include compensation connection part 475.

Compensation connection part 475 is connected to compensation terminal 473 and makes to compensate fixed part 471 close contact fixed cells 500.In one embodiment, the compensation connection part 475 that is nut type can thread connection arrive from the outstanding compensation terminal 473 of compensation fixed part 471.Therefore, compensation can be formed with the screw thread for being threadedly engaged with compensation connection part 475 on terminal 473.

When compensation connection part 475 when terminal 473, is compensated fixed part 471 and can prevent from compensating the rotation of terminal 473, thereby prevent the rotation of thermal compensation wire 430 and compensation connector 450 to compensation by thread connection.

Heating unit 300 and compensating unit 400 are fixed to fixed cell 500.A pair of fixed cell 500 is connected to respectively two relative ends of heating unit 300 and compensating unit 400

Can be by heating unit 300 and compensating unit 400 be connected to fixed cell 500 and modularization according to the temperature compensation heater 200 of the present embodiment.

Each fixed cell 500 all can comprise heating support 501 and bottoming hole 503.

Heating tube 310 is connected to heating support 501 at one end thereof place, and the hot terminal 373 of heating lead-in wire 370 is through bottoming hole 503.Therefore, heating support 501, bottoming hole 503 and heating attachment recess 505 communicate with each other.

In one embodiment, as shown in Figure 9, heating support 501 can be recessed shape and can hold heating tube 310.In another embodiment, as shown in figure 10, heating support 501 can be outstanding shape and can be inserted in heating tube 310.

Heating attachment recess 505 can be formed in fixed cell 500.

Heating fixed part 371 is inserted in heating attachment recess 505 to suppress or to prevent the rotation of heating lead-in wire 370.Because heating fixed part 371 is inserted in heating attachment recess 505, therefore in the time that being coupled to each other with heating support 501, heating connection part 375 can prevent the rotation of heating lead-in wire 370.

Fixed cell 500 may further include compensation support 502 and compensate opening 504.

Compensation support 502 is connected to an end of compensating pipe 410, and the compensation terminal 473 of compensating lead wire 470 is through compensate opening 504.Therefore, compensation support 502 is communicated with compensation attachment recess 506, and compensation attachment recess 506 is communicated with compensate opening 504.

In one embodiment of the invention, as shown in Figure 9, compensation support 502 can be recessed shape and can hold compensating pipe 410.In another embodiment, as shown in figure 10, compensation support 502 can be outstanding shape and can be inserted in compensating pipe 410.

In addition, compensation attachment recess 506 can be formed in fixed cell 500.

Compensation fixed part 471 is inserted in compensation attachment recess 506 to suppress or to prevent the rotation of compensating lead wire 470.Because compensation fixed part 471 is inserted in compensation attachment recess 506, therefore in the time that being coupled to each other with compensation support 502, compensation connection part 475 can prevent the rotation of compensating lead wire 470.

In temperature compensation heater 200 according to an embodiment of the invention, heating lead-in wire 370 and compensating lead wire 470 thread connection are to fixed cell 500, thereby allow heating unit 300 and compensating unit 400 to carry out independent maintenance.

Organism component 600 comprises align member 610 and spacing member 630.

When the mode that adds thermal target M to be parallel to when heater 200 is arranged, align member 610 supports heater 200.Each align member 610 is all formed with and connects recess 611, the fixed cell 500 of heater 200 can be sat put to support connecting in recess 611 and by connecting recess 611.In addition, connect cap 613 and can removably be attached on the connection recess 611 of align member 610, so that stably fixing seat is put at the fixed cell 500 connecting on recess 611.Heater 200 is attached on organism component 600 or from organism component 600 dismountings individually by connecting the attached of cap 613 or separation, thereby allows to safeguard individually heater 200.

Align member 610 can be provided with supporting member 700.

Each spacing member 630 is all separated heater 200 and supporting member 700

Be configured to time separated from one another when adding thermal target M, the align member 610 of supporting heater 200 can be separated from one another by spacing member 630.In addition, be arranged to time separated from one another when adding thermal target M, the align member 610 that is provided with supporting member 700 can be separated from one another by spacing member 630.In addition, the align member 610 of supporting heater 200 and the align member 610 that is provided with supporting member 700 can be arranged to separated from one another by spacing member 630.

Each supporting member 700 includes cramp bar 710 and fulcrum post unit 730.

Cramp bar 710 is connected to organism component 600.Cramp bar 710 is formed with the support slot 711 that holds fulcrum post unit 730.

Fulcrum post unit 730 is set on cramp bar 710 and to the thermal target M that adds being contained in organism component 600 and supports.Fulcrum post unit 730 comprises frame support bracket 731 and fulcrum post 733, and this frame support bracket 731 is connected on cramp bar 710, and this fulcrum post 733 is given prominence to and supports adding thermal target M from frame support bracket 731.

Supporting member 700 may further include rotating shaft 750.Rotating shaft 750 is configured as through cramp bar 710 and frame support bracket 731 so that fulcrum post unit 730 can be rotated.

Supporting member 700 may further include elastic component 770.Elastic component 770 can flexibly support fulcrum post unit 730, makes in the time that fulcrum post unit 730 rotates fulcrum post unit 730 stably to support and adds thermal target M.

For example, as shown in figure 12, be set to while removing in organism component 600 or from organism component 600 when adding thermal target M, fulcrum post unit 730 can tilt in case not with add thermal target M and interfere.Here can use independent control member (not shown).

In addition, fulcrum post unit 730 can reset to its home position and adds thermal target M stably to support.Herein, this can utilize the elastic-restoring force of elastic component 770, maybe can use independent control member (not shown).

Although not shown, fulcrum post unit 730 can be connected on cramp bar 710 to move up or down, thus restriction or prevent and the interference that adds thermal target M.

High-temperature cable 800 is contained in chamber 100 and is electrically connected to heater 200, and the heat that can deliver power to heater 200 and do not radiated is disturbed.

Each high-temperature cable 800 includes conducting part 810, insulation division 830, metal tube 850 and containment member 870.

Conducting part 810 is electrically connected to heater 200 electric power is delivered to heater 200.Conducting part 810 can be formed by copper or aluminium.Conducting part 810 can be electrically connected at least one in heating lead-in wire 370 and compensating lead wire 470 by connecting elements 880.

Insulation division 830 is sealed conducting part 810.Insulation division 830 can stop heat to be delivered to conducting part 810 from heater 200, and can shield the electric power mobile along conducting part 810.Insulation division 830 can comprise the magnesium oxide as mineral based insulation material.

Metal tube 850 is sealed insulation division 830.Metal tube 850 can prevent the distortion or the damage that cause because of the heat that heater 200 radiates.Metal tube 850 can be formed by stainless steel.

Containment member 870 seals two relative ends of metal tube 850.Containment member 870 prevents that insulation division 830 is outside two relative ends of metal tube 850 are exposed to.Containment member 870 forms and is soldered on two relative ends of metal tube 850 by quartz or glass.

May further include sliding component 900 according to the equipment for Heating Processing of embodiment.

Sliding component 900 is connected to organism component 600 to allow organism component 600 to enter or leave chamber 100 by chamber 100.Organism component 600 can easily enter or leave chamber 100 by sliding component 900.

Organism component 600 is connected to housing 110 by sliding component 900, and organism component 600 in the time that chamber 100 opens or closes is slided with respect to housing 110.

Sliding component 900 allows organism component 600 to slide in the housing 110 of chamber 100, and each sliding component 900 all can comprise ways 910 and moving link 930.

Ways 910 is set to chamber 100 to form the sliding path of organism component 600, and moving link 930 is set to organism component 600 to move along ways 910.

May further include locking component 1000 according to the equipment for Heating Processing of embodiment.

Locking component 1000 is set or removes in chamber 100 closed condition to adding the space that thermal target M heat-treats.Locking component 1000 is closed space, and the air-tightness of chamber 100 can stably be kept.Each locking component 1000 includes latch member 1100 and the first locking component 1300.

Latch member 1100 is selected lock-out state.Latch member 1100 can be connected to door 130 by analog bracket 1001.Latch member comprises claw 1110 and claw drive division 1130.

Claw 1110 can connect and lock onto the first locking component 1300, and claw drive division 1130 makes claw 1110 reciprocating motions.For example, claw drive division 1130 can be by using pneumatic or hydraulic pressure to make claw 1110 reciprocating motions.

Claw 1110 can be inserted in the first locking component 1300, and then can be made its connection and be locked onto the first locking component 1300 by operation claw drive division 1130.

Latch member 1100 connects and locks onto the first locking component 1300.The first locking component 1300 can be set to the housing 110 of chamber 100.In the time using fixed component 1600 described below, the first locking component 1300 can be set on fixed component 1600.The first locking component 1300 can be formed with the first locking recess 1310, and the claw 1110 of latch member 1100 can be inserted in the first locking recess 1310.

Due in the time that chamber 100 is closed, the claw 1110 of latch member 1100 is inserted into by operation claw drive division 1130 in the first locking recess 1310 of the first locking component 1300, therefore chamber 100 can keep closing, thereby has maintained the air-tightness of chamber 100.

Locking component 1000 may further include the second locking component 1500.

The second locking component 1500 and the first locking component 1300 are separated, and latch member 1100 can connect and lock onto the second locking component 1500.In the time being provided with fixed component 1600 described below, the second locking component 1500 can be set on fixed component 1600.The second locking component 1500 can be formed with the second locking recess 1510, and the claw 1110 of latch member 1100 can be inserted in the second locking recess 1510.

In the time that chamber 100 is opened, door 130 separates with housing 110, and the claw 1110 that is arranged on the latch member 1100 in door 130 is inserted in the second locking recess 1510 of the second locking component 1500 by operation claw drive division 1130.Therefore, the position of the door 130 that chamber 100 stays open and separates with housing 110 is stably locked, thereby makes to be easy to determine the position of door 130.

Although not shown, in the time that the first locking component 1300 is set in door 130, latch member 1100 can be set on housing 110 or on fixed component 1600.In the time that the first locking component 1300 is set to door 130, a pair of latch member 1100 can be spaced and be set on housing 110 and fixed component 1600 on.In addition,, in the time that the first locking component 1300 is set in door 130, a pair of latch member 1100 can be spaced and be set on fixed component 1600.

Equipment for Heating Processing comprises and may further include fixed component 1600 according to an embodiment of the invention.

Fixed component 1600 connects and is fixed to the housing 110 of chamber 100, and can in the time that chamber 100 opens or closes, stably support door 130.

Equipment for Heating Processing may further include path component 1800 according to an embodiment of the invention.

Door 130 is connected to fixed component 1600 by path component 1800, makes in the time opening and closing chamber 100, and door 130 can be slided with respect to fixed component 1600.

Path component 1800 allows door 130 to slide in fixed component 1600, and each path component 1800 all can comprise ways 1810 and transport member 1830.

Ways 1810 is set to fixed component 1600 to form the sliding path of door, and transports member 1830 and be set to door 130 to move along ways 1810.

Hereinafter, will equipment for Heating Processing be according to another embodiment of the present invention described.

Figure 19 is according to the end view of the equipment for Heating Processing of the present embodiment.With reference to Figure 19, comprise chamber 100, heater 200, organism component 600, supporting member 700 and high-temperature cable 800 according to the equipment for Heating Processing of the present embodiment, and can by the heat that radiates from heater 200 to add add described in thermal target M(thermal target M be placed in organism component 600 and by supporting member 700 support) heat-treat.

May further include at least one sliding component 900, locking component 1000, fixed component 1600 and path component 1800 according to the equipment for Heating Processing of the present embodiment.

With will be represented by identical Reference numeral according to the identical parts of the parts of the equipment for Heating Processing of previous embodiment, and will to its omit describe in detail.

But, when the align member 610 of supporting heater 200 is arranged to time separated from one another by the spacing member 630 of organism component 600, being arranged in the heater 200 of a side of align member 610 and the heater 200 that is arranged in the opposite side of align member 610 can alternately arrange.

Therefore the Temperature Distribution that, is applied to the heat that adds thermal target M can keep more equably.

Hereinafter, will the operation that the target in equipment for Heating Processing is heat-treated according to an embodiment of the invention be described.

Figure 20 shows the thermal target that adds that is divided into multiple control areas according to an embodiment of the invention, and Figure 21 shows temperature compensation heater in equipment for Heating Processing according to an embodiment of the invention, that arrange according to the division situation that adds thermal target.

With reference to Figure 20 and Figure 21, add thermal target M and be divided into multiple control areas 210, make control area 210 there is different Temperature Distribution, and can make to add thermal target M according to the equipment for Heating Processing of the present embodiment and there is uniform Temperature Distribution along the direction of arranging temperature compensation heater 200.

Each temperature compensation heater 200 includes heating unit 300 and compensating unit 400, and adding thus thermal target M can have uniform Temperature Distribution along the longitudinal direction of temperature compensation heater 200.

Arrange along the direction of arranging temperature compensation heater 200 control area 210.

Each control area 210 includes at least one temperature compensation heater 200.In one embodiment, two temperature compensation heaters 200 can be set in each control area.

Described multiple control area 210 can be divided into fringe region 211 and multiple control band 213,215.In Figure 21, described multiple control bands 213,215 can comprise the first control band 213 and the second control band 215.

In the direction that fringe region 211 is arranged at temperature compensation heater 200, be positioned at two relative ends of heating target M.For example, fringe region 211 can be corresponding with the region that the temperature compensation heater 200 that is arranged on the top, relative two ends that adds thermal target M heats.

The first control band 213 be positioned at each fringe region 211 from fringe region 211 to the side adding the direction at center of thermal target M.For example, each the first control band 213 all can be corresponding with the region that the temperature compensation heater 200 of this side top that is arranged on fringe region 211 heats.

The second control band 215 be positioned at each the first control band 213 from the first control band 211 to the side adding the direction at center of thermal target M.For example, each the second control band 215 all can be corresponding with the region that the temperature compensation heater 200 being arranged in this side of the first control band 213 heats.

Therefore, fringe region 211 and described multiple control band 213,215 have different Temperature Distribution, can heat adding thermal target M equably thus.For example, the heat radiating from temperature compensation heater 200 is adjusted to: it is the highest making the temperature of the heat that the temperature compensation heater corresponding with fringe region 211 200 radiate, and the temperature of the heat that the temperature compensation heater 200 corresponding with control band 213,215 radiates reduces towards center gradually from two the relative ends that add thermal target M, adds thermal target M thereby can heat equably.

In one embodiment of the invention, equipment for Heating Processing may further include temperature sensing unit 230 and controller C.

The temperature sensing unit 230 corresponding temperature in Detection & Controling region 210.

In one embodiment, temperature sensing unit 230 adds above thermal target M being arranged between temperature compensation heater 200, and detects the temperature of each control area 210.The temperature of the heat that temperature sensing unit 230 Detection & Controling regions 210 are corresponding, radiate from temperature compensation heater 200.

Temperature sensing unit 230 can comprise first sensor 231, the second transducer 233 and the 3rd transducer 235.First sensor 231 detects the temperature of the fringe region 211 of control area 210, and the second transducer 233 detects the temperature of the first control band 213 of control area 210, and the 3rd transducer 235 detects the temperature of the second control band 215 of control area 210.

The temperature being detected by temperature sensing unit 230 is transferred to controller C.

Controller C regulates according to the temperature pair heat that the temperature compensation heater corresponding with control area 210 200 radiates being detected by temperature sensing unit 230.

For example, controller C sets temperature heat, corresponding with the default heating-up temperature that adds thermal target M that emits to control area 210 from temperature compensation heater 200.Controller C compares the temperature corresponding to institute's detected temperatures of detected temperature sensing unit 230 temperature and controller C setting, thereby regulates the heat radiating from the temperature compensation heater corresponding with control area 210 200.

Hereinafter, by be described according to another embodiment of the present invention to carry out the operation of heat treated in equipment for Heating Processing to adding thermal target.

Figure 22 shows temperature compensation heater in equipment for Heating Processing according to another embodiment of the present invention, that arrange according to the division situation that adds thermal target.With reference to Figure 22, add thermal target M and be divided into multiple control areas 210, make control area 210 there is different Temperature Distribution, and can make to add thermal target M according to the equipment for Heating Processing of the present embodiment and there is uniform Temperature Distribution along the direction of arranging temperature compensation heater 200.

Each temperature compensation heater 200 includes heating unit 300 and compensating unit 400, and adding thus thermal target M can have uniform Temperature Distribution along the longitudinal direction of temperature compensation heater 200.

Arrange along the direction of arranging temperature compensation heater 200 control area 211,213,215.

Each control area 210 includes at least one temperature compensation heater 200.In one embodiment, two temperature compensation heaters 200 can be set in each control area.

Described multiple control area 210 can be divided into fringe region 211 and multiple control band 213,215.As shown in figure 22, described multiple control band 213,215 can comprise the first control band 213 and the second control band 215.

In the direction that fringe region 211 is arranged at temperature compensation heater 200, be positioned at two relative ends of heating target M.For example, fringe region 211 can be corresponding with the region that the temperature compensation heater 200 that is arranged on two the relative ends that add thermal target M heats.

The first control band 213 be positioned at each fringe region 211 from fringe region 211 to the side adding the direction at center of thermal target M.For example, each the first control band 213 all can be corresponding with the region that the temperature compensation heater 200 being arranged in this side of fringe region 211 heats.

The second control band 215 be positioned at each the first control band 213 from the first control band 213 to the side adding the direction at center of thermal target M.For example, each the second control band 215 all can be corresponding with the region that the temperature compensation heater 200 of this side that is arranged on the first control band 213 heats.

Therefore, fringe region 211 and described multiple control band 213,215 have different Temperature Distribution, can heat adding thermal target M equably thus.For example, the heat radiating from temperature compensation heater 200 is adjusted to: it is the highest making the temperature of the heat that the temperature compensation heater corresponding with fringe region 211 200 radiate, and the heat temperature that the temperature compensation heater 200 corresponding with control band 213,215 radiates reduces towards core gradually from two the relative ends that add thermal target M, adds thermal target M thereby can heat equably.

In one embodiment of the invention, equipment for Heating Processing may further include temperature sensing unit 230 and controller C.

The temperature sensing unit 230 corresponding temperature in Detection & Controling region 210.

In the present embodiment, temperature sensing unit 230 can be set to and add thermal target M below to adding on the fulcrum post unit 730 that thermal target M supports or being positioned at, to detect the temperature that adds thermal target M in each control area 210.

Temperature sensing unit 230 can comprise first sensor 231, the second transducer 233 and the 3rd transducer 235.First sensor 231 detects the temperature of the fringe region 211 of control area 210, and the second transducer 233 detects the temperature of the first control band 213 of control area 210, and the 3rd transducer 235 detects the temperature of the second control band 215 of control area 210.

The temperature being detected by temperature sensing unit 230 is transferred to controller C.

Controller C regulates according to the temperature pair heat that the temperature compensation heater corresponding with control area 210 200 radiates being detected by temperature sensing unit 230.

For example, the temperature that controller C detects temperature sensing unit 230 compares with the default heating-up temperature that adds thermal target M, thus the heat that regulates the temperature compensation heater 200 corresponding with control area 210 to radiate.

As mentioned above, according to the present embodiment, equipment for Heating Processing can be made a response to the actual temperature that adds thermal target M, thereby prevents from producing defect because of heat adding in thermal target M.

As mentioned above, according to high-temperature cable of the present invention with use heat that the equipment for Heating Processing of this high-temperature cable can suppress or prevent that heater from radiating to produce with the electric power of conveying to disturb, can suppress or prevent because the heat of radiation causes producing impurity or flue dust in the space of chamber 100 and can prevent that the electric wire that is connected to heater 200 from producing interference with chamber in the space of chamber 100.

Although some embodiment are described with reference to accompanying drawing and form, but should be understood that, the invention is not restricted to these embodiment and can realize with various different modes, and without departing from the spirit and scope of the present invention, those skilled in the art can make various modifications, modification and change.Therefore, scope of the present invention should by claim with and equivalents determine.

Claims (19)

1. a high-temperature cable, comprising:

Conducting part, electric power is transported to described conducting part;

Insulation division, described insulation division is sealed described conducting part;

Metal tube, described metal tube is sealed described insulation division; And

Sealing, described sealing seals the end of described metal tube.

2. an equipment for Heating Processing, comprising:

Chamber, described chamber provides the space of heat-treating adding thermal target;

Heater, described heater is placed in described chamber with to described heating target radiation heat;

Organism component, described organism component is contained in and in described chamber and described in holding, adds thermal target and described heater;

Supporting member, described supporting member be set on described organism component with will described in add thermal target and described heater is separated; And

High-temperature cable, described high-temperature cable is contained in described chamber and is electrically connected to described heater, to transmit electric power to described heater in the case of not occurring to disturb with the heat of radiation.

3. equipment for Heating Processing according to claim 2, wherein, described heater comprises:

Heating unit, described heating unit is divided into the heating region of radiate heat and two relative extended nominal regions in end from described heating region;

Compensating unit, described compensating unit is divided into that join domain extends with from two relative ends of described join domain and the compensatory zone of radiate heat; And

Fixed cell, described heating unit and described compensating unit are fixed to described fixed cell.

4. equipment for Heating Processing according to claim 3, wherein, is all formed with the reflector that heat is reflected in each described heating region and described compensatory zone, so as heat to be emitted to be arranged on described heater below described in add thermal target.

5. equipment for Heating Processing according to claim 2, wherein, described supporting member comprises:

Cramp bar, described cramp bar is connected on described organism component; And

Fulcrum post unit, described fulcrum post unit is set on described cramp bar and to the described thermal target that adds and supports.

6. equipment for Heating Processing according to claim 2, further comprises:

Sliding component, described sliding component is connected to described organism component so that described organism component enters or leave described chamber by described chamber.

7. equipment for Heating Processing according to claim 6, wherein, described sliding component comprises:

Ways, described ways is set to described chamber and forms the sliding path of described organism component; And

Moving link, described moving link is set on described organism component and along described ways and moves.

8. according to the equipment for Heating Processing described in any one in claim 2 to 7, wherein, described chamber comprises:

Housing, described housing forms the space that adds thermal target and carry out hot place amount to described; And

Door, described door is removably connected to described housing to open or close described space.

9. equipment for Heating Processing according to claim 8, further comprises:

Sliding component, described organism component is attached to described housing by described sliding component, make in the time opening or closing described space described in organism component slide with respect to described housing.

10. equipment for Heating Processing according to claim 9, wherein, described sliding component comprises:

Ways, described ways is set to described chamber and forms the sliding path of described organism component; And

Moving link, described moving link is set on described organism component and along described ways and moves.

11. equipments for Heating Processing according to claim 8, further comprise:

Locking component, the closed condition in described space is set or removed to described locking component.

12. equipments for Heating Processing according to claim 11, further comprise:

Fixed component, described fixed component is connected to described housing and in the time opening or closing described space, described door is supported.

13. equipments for Heating Processing according to claim 12, further comprise:

Path component, described door is connected to described fixed component by described path component, while opening or closing described space with box lunch described in door slide with respect to described fixed component.

14. equipments for Heating Processing according to claim 13, wherein, described path component comprises:

Ways, described ways is set on described fixed component and forms the sliding path of described door; And

Transport member, described in transport member and be set in described door and along described ways and move.

15. equipments for Heating Processing according to claim 12, wherein, described locking component comprises:

Latch member, described latch member is selected lock-out state; And

The first locking component, described latch member connects and locks onto described the first locking component.

16. equipments for Heating Processing according to claim 15, wherein, described locking component further comprises:

The second locking component, described the second locking component to be to be set on described fixed component with the separated mode of described the first locking component, so that described latch member connects and locks onto described the second locking component.

17. equipments for Heating Processing according to claim 15, wherein, described latch member comprises:

Claw, described claw connects and locks onto described the first locking component; And

Claw drive division, described claw drive division makes described claw reciprocating motion.

18. equipments for Heating Processing according to claim 2, wherein, described in add thermal target and be divided into multiple control areas, make described control area there is different Temperature Distribution mutually along the direction of arranging described heater.

19. equipments for Heating Processing according to claim 18, further comprise:

Temperature sensing unit, described temperature sensing unit detects the temperature corresponding with described control area; And

Controller, the heat that described controller regulates the heater corresponding with described control area to radiate according to the temperature being detected by described temperature sensing unit.

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