JP2003207397A - Automatic temperature sensor calibrations system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system having no possibility of causing mistakes of calculation in conversion of detected voltage to temperature, without dispersing final determination whether the temperature is stabilized or not by operators. <P>SOLUTION: An automatic temperature sensor calibration system 100 according of the invention comprises an electric furnace 10b, and a first multimeter 10c. The electric furnace 10b raises the temperature to setting temperature 12. The first multimeter 10c is connected to a temperature sensor 20a inserted in the interior 10ba of the electric furnace 10b, and outputs data 16 corresponding to the temperature detected by the temperature sensor 20a. The automatic temperature sensor calibration system 100 comprises information processing equipment 30. When the data 16 corresponding to the temperature, which is output from the first multimeter 10c, is detected to be within a range 1ER of a first error predetermined in association with the setting temperature 12, the information processing equipment 30 determines that internal temperature of the electric furnace 10b is stabilized, and evolves a first temperature 1T from the data 16 corresponding to the temperature. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic temperature sensor calibration system, and more particularly to a system for automatically performing a series of operations related to temperature sensor calibration.

[0002]

2. Description of the Related Art A conventional automatic temperature sensor calibration system 10
FIG. 8 shows a configuration diagram of No. 0. This automatic temperature sensor calibration system 100 includes a temperature controller 10a, an electric furnace 10b, a first
It has a multimeter 10c, a second multimeter 10d, and a channel selector 10e. In the electric furnace 10b,
The standard temperature sensor 20a and at least two to-be-calibrated temperature sensors 20b (20ba, 20bb) are connected via a fixing component 20c.

The temperature controller 10a is connected to the electric furnace 10b, and has a first input portion 10ab for inputting a set temperature 12 in the electric furnace interior 10ba, and the electric furnace interior 1
The digital meter 10aa which shows the temperature of 0ba is provided. When the set temperature 12 is input to the temperature controller 10a by the operator, the electric furnace interior 10ba is set to the set temperature 12
Automatically rises to. After a while after the temperature rises, the temperature inside the electric furnace 10ba indicated by the digital meter rises and falls in the vicinity of the set temperature 12. This phenomenon indicates that the temperature inside the electric furnace 10ba is almost stable, but the operator makes the final judgment as to whether or not the temperature is stable. Therefore, this judgment tends to vary depending on the operator.

The first multimeter 10c and the second multimeter 10d detect a voltage or resistance value. Temperature sensor (standard temperature sensor 20a, temperature sensor 20 to be calibrated)
If b) is a thermocouple, the voltage is detected, and if it is a resistance temperature detector, the resistance value is detected. The first multimeter 10c is
It is connected to the standard temperature sensor 20a and detects the voltage (or resistance value, the same applies hereinafter) corresponding to the temperature output from the standard temperature sensor 20a. The second multimeter 10d is connected to the temperature sensor 20b to be calibrated via the channel selector 10e, and the temperature sensor 2 to be calibrated 2
The voltage output from 0b is detected. With respect to both the first multimeter 10c and the second multimeter 10d, the conversion of the detected voltage into the temperature is performed manually by the operator. Therefore, a calculation error may occur.

The channel selector 10e is for switching the temperature sensor 20b to be measured when measuring the voltage of the temperature sensor 20b to be calibrated. This switching is performed manually by an operator.

[0006]

SUMMARY OF THE INVENTION An object of the present invention is to provide a system in which the final judgment as to whether or not the temperature is stable does not vary depending on the operator.

Another object of the present invention is to provide a system in which no miscalculation can occur in converting the detected voltage into temperature.

[0008]

[Means for Solving the Problems] Means for solving the problems will be described below with reference to the numbers and symbols used in the embodiments of the present invention. These numbers and signs are added to clarify the correspondence between the description in [Claims] and the description in [Embodiment of the Invention], but in [Claims] It should not be used to interpret the technical scope of the described invention.

The automatic temperature sensor calibration system (100) according to the present invention comprises an electric furnace (10b) for heating up to a set temperature (12) and an inside (10b) of the electric furnace (10b).
A first multimeter (10) connected to a temperature sensor (20a) inserted in a) and outputting data (16) corresponding to the temperature detected by the temperature sensor (20a).
c) and. Further, the automatic temperature sensor calibration system (100) according to the present invention includes the first multimeter (1
0c), the temperature-corresponding data (16) is
It is determined that the temperature inside the electric furnace (10b) is stable by detecting that the temperature is within a predetermined first error range (1ER) in relation to the set temperature (12). An information processing device (30) for deriving a first temperature (1T) from the temperature correspondence data (16).

In the automatic temperature sensor calibration system (100) according to the present invention, the temperature sensor (20a) is a reference temperature sensor, and at least two calibrated temperature sensors (20b) inserted in the electric furnace (10b) are used. A second multimeter (10d) for detecting the temperature-corresponding data (18, 19) to be output, and the second multimeter (10d) in response to an instruction from the information processing device (30).
Output data to one of the temperature sensors to be calibrated (2
0ba), one of the calibration temperature corresponding data (18) detected from the other calibration temperature sensor (2)
Channel selector (10e) for switching to the other data (19) corresponding to the temperature to be calibrated detected by 0bb).

In the automatic temperature sensor calibration system (100) according to the present invention, the information processing device (30) derives a second temperature (2T) from the temperature-corresponding data (18, 19) to be calibrated and outputs the second temperature (2T). The difference between the temperature (2T) and the first temperature (1T) is calculated.

In the automatic temperature sensor calibration system (100) according to the present invention, the information processing device (30) is configured to raise the temperature of the electric furnace (10) to the preset temperature (12).
b), the temperature setting processing unit (30c), the temperature correspondence data (16) and the calibration target temperature correspondence data (1).
8 and 19) is within the first error range (1ER). Further, the information processing device (30) derives the first temperature (1T) from the temperature correspondence data (16), and derives the second temperature (2) from the calibration target temperature correspondence data (18, 19).
A derivation processing unit (30e) for deriving T) and a storage unit (30b-1) for storing the first error range (1ER). Further, the information processing device (30) outputs the output data to one of the temperature sensors (20b) to be calibrated.
From any one of the calibration target temperature corresponding data (18) detected by a), the other calibration target temperature sensor (20b)
Channel selector control unit (30) for switching to the other data (19) corresponding to the temperature to be calibrated detected by b).
g).

The automatic temperature sensor calibration method according to the present invention comprises:
It comprises a step (S2) of raising the temperature to the set temperature (12) and a step (S3) of outputting data (16) corresponding to the temperature detected by the temperature sensor (20a). Further, the automatic temperature sensor calibration method according to the present invention detects that the temperature correspondence data (16) is within a first error range (1ER) predetermined in relation to the set temperature (12). Thus, the method comprises a step (S5) of determining that the internal temperature of the electric furnace (10b) is stable, and a step (S10) of deriving the first temperature (1T) from the temperature correspondence data (16).

The automatic temperature sensor calibration method according to the present invention comprises:
The step (S8) of detecting the temperature-corresponding data (18, 19) to be calibrated output from at least two temperature sensors (20b) to be calibrated, and the output data to the second multimeter (10d) are used for any one of the calibration data. Calibration temperature sensor (20b
and a step (S13) of switching from any of the temperature-corresponding data to be calibrated (18) detected by a) to another temperature-corresponding data (19) to be calibrated detected by another temperature sensor (20bb) to be calibrated. To have.

The automatic temperature sensor calibration method according to the present invention comprises:
A step (S11) of deriving a second temperature (2T) from the calibration target temperature correspondence data (18, 19) and calculating a difference between the second temperature (2T) and the first temperature (1T) is included. There is.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of an automatic temperature sensor calibration system 100 according to the present invention will be described below with reference to the accompanying drawings.

(Embodiment 1) FIG. 1 is a block diagram of Embodiment 1 according to the automatic temperature sensor calibration system 100 of the present invention. The automatic temperature sensor calibration system 100 according to the first embodiment includes a temperature controller 10a, an electric furnace 10b, a first multimeter 10c, a second multimeter 10d, a channel selector 10e, an information processing device 30, and a communication cable 40. There is. The inside 10ba of the electric furnace is heated by the temperature controller 10a.

The temperature controller 10a receives a temperature setting request signal 11 for requesting a temperature rise from the information processing device 30 to the set temperature 12 of the electric furnace interior 10ba. The temperature setting request signal 11 includes a set temperature 12 (for example, 100 ° C.) inside the electric furnace 10ba, a temperature interval 13 for performing a test (50 ° C. pitch,
Or 100 ℃ pitch), temperature range for testing 14
(For example, 100 ° C. to 500 ° C.) is included. In response to the temperature setting request signal 11, the temperature controller 10a starts to raise the temperature inside the electric furnace 10ba to the set temperature 12 (first time).

The temperature controller 10a receives from the information processing device 30 a temperature stability notification signal 14a indicating that the inside of the electric furnace 10ba is stable at the set temperature 12 (however, the actual temperature inside the electric furnace 10ba is accurate). However, the temperature rise is stopped in response to the signal. In addition, the temperature controller 10a is the information processing device 30.
When the temperature increase restart request signal 15 is received from, the temperature increase (second time) is started again in response to the temperature increase restart request signal 15. In the second temperature increase, for example, if the set temperature 12 required in the first temperature increase is 100 ° C., the temperature interval 13 is a 100 ° C. pitch, and the temperature range 14 is 100 ° C. to 500 ° C. The process is performed until the inside of the electric furnace 10ba becomes stable at 200 ° C. In the subsequent temperature increase, the same process as the second temperature increase is repeated.

The temperature controller 10a includes an electric furnace interior 1
A digital meter 10aa indicating the temperature of 0ba is provided, and is checked by a monitor or the like at any time.

The inside of the electric furnace 10ba is a temperature controller 10a.
The temperature is controlled by. Also, the electric furnace body 10b
Is a fixing component 20c for fixing the standard temperature sensor 20a or the temperature sensor 20b to be calibrated (first temperature sensor 20ba to be calibrated, temperature sensor 20bb to be calibrated).
Is provided. The standard temperature sensor 20a and the temperature sensor 20b to be calibrated are inserted and fixed in the electric furnace interior 10ba from the insertion ports provided in the fixing component 20c.

The first multimeter 10c is connected to the standard temperature sensor 20a and detects the temperature correspondence data 16 (voltage or resistance value) corresponding to the temperature detected by the standard temperature sensor 20a. Standard temperature sensor 20a
When it is composed of a thermocouple, the temperature corresponding data 16 becomes a voltage, and when it is made of a resistance temperature detector, the temperature corresponding data 16 becomes a resistance value. Detected temperature correspondence data 1
6 is output to the information processing device 30 via the communication cable 40.

The second multimeter 10d is connected to the channel selector 10e and detects the temperature-corresponding data to be calibrated corresponding to the temperature detected by any of the several temperature sensors 20b to be calibrated. First multimeter 10c
When the temperature sensor 20b to be measured is a thermocouple, the temperature-corresponding data to be calibrated is a voltage, and when the temperature sensor 20b to be measured is a resistance temperature detector, the temperature-corresponding data to be calibrated is resistance. It becomes a value. The detected temperature-corresponding temperature-corresponding data is output to the information processing device 30 via the communication cable 40 as in the case of the first multimeter 10c.
The calibration target temperature correspondence data is either the first calibration target temperature correspondence data 18 or the second calibration target temperature correspondence data 19 described later.

The channel selector 10e receives from the information processing device 30 a measurement object notification signal 17 indicating which temperature sensor 20b to be calibrated, which is the measurement object. In addition, the channel selector 10e includes the identification number I of the temperature sensor 20b to be calibrated included in the measurement target notification signal 17.
Based on D, the measurement target switching operation is performed. The switching operation of the measurement target means output data to the second multimeter 10d, for example, from the first calibration target temperature corresponding data 18 output from the first calibration target temperature sensor 20ba, and from the second calibration target temperature sensor 20bb. It is to switch to the second data 19 corresponding to the temperature to be calibrated.

The standard temperature sensor 20a is used in the electric furnace interior 10
It is used to detect the temperature of ba. The temperature sensor 20b to be calibrated is manufactured for the purpose of detecting the temperature of a chemical agent, metal, or the like. In the automatic temperature sensor calibration system 100 of the present invention,
It is composed of at least two or more. The standard temperature sensor 20a, the first temperature sensor 20ba to be calibrated, and the second temperature sensor 20bb to be calibrated (hereinafter, these three are collectively referred to as "temperature sensor") are thermocouples or temperature measuring devices. Composed of resistors.

A block diagram of the information processing apparatus 30 is shown in FIG. The information processing device 30 includes a second input unit 30a, a first storage unit 30b-1, a temperature setting processing unit 30c, and an error detection unit 30.
d, a conversion processing unit 30e, a derivation processing unit 30f, a channel selector control unit 30g, and a control unit 30h.

The second input section 30a is composed of a keyboard or the like, and is used by an operator for input operation of the set temperature 12, the temperature interval 13, and the temperature range 14.

The information stored in the first storage section 30b-1 is shown in FIG. The first storage unit 30b-1 stores the first error range 1
ER, delay time DT, first derivation formula 1C, second derivation formula 2C
Is stored. The first error range 1ER is inside the electric furnace 1
When the temperature of 0ba is stable, it represents the ratio of the fluctuation range of the temperature. When the materials of the temperature sensors are all different, the first storage unit 30b-1 stores the first storage unit 30b-1.
The error range 1ER has three types (1ERa, 1ERb, 1E
Rc). Hereinafter, the standard temperature sensor 20a, the first calibrated temperature sensor 20ba, and the second calibrated temperature sensor 20bb
To the first error range 1ERa, the first error range 1ERa, the first error range 1ERb, the first error range 1ER
Let be c.

The first storage section 30b-1 is used when the inside of the electric furnace 10ba is stabilized at the set temperature 12 and when the heat of the inside of the electric furnace 10ba is transmitted to the temperature sensor and the temperature sensor reaches the set temperature 12. Delay time D representing the difference in time
Stores T. When the materials of the temperature sensors are all different, the delay time DT stored in the first storage unit 30b-1
Are three types (DTa, DTb, DTc). Less than,
Standard temperature sensor 20a, first temperature sensor 20b to be calibrated
a, delay time D for the second temperature sensor 20bb to be calibrated
Let T be the delay time DTa, the delay time DTb, and the delay time DTc, respectively.

Further, the first storage section 30b-1 has a first derivation formula 1C used for deriving the temperature from the voltage and a second derivation formula 2C used for deriving the temperature from the resistance value.
Is stored. An error with respect to the temperature detected by the first temperature sensor 20ba to be calibrated is calculated from the difference between the temperature derived from the first data to be calibrated 18 and the temperature derived from the data 16 to be calibrated (second temperature to be calibrated). Temperature sensor 2
Similarly, for 0bb, the error with respect to the detected temperature is calculated).

The temperature setting processing section 30c of the information processing apparatus 30
Transmits a temperature setting request signal 11 or a temperature increase restart request signal 15 to the temperature controller 10a, and the electric furnace interior 10
A request is made to raise the temperature of ba to the set temperature 12.

The error detector 30d is provided in the first multimeter 1
0c or the temperature corresponding data 16 output from the second multimeter 10d, the first calibrated temperature corresponding data 18, and the second calibrated temperature corresponding data 19 (hereinafter, all of them are collectively referred to as "input data"). ) Is entered. The error detection unit 30d detects that the input data is within the range of the first error range 1ER. The control unit 30h of the information processing device 30 determines that the temperature inside the electric furnace 10ba is stable based on the detection result by the error detection unit 30d.

The conversion processing unit 30e converts the input data when it is determined that the control unit 30h is stable, based on the delay time DT. The derivation processing unit 30f of the information processing device 30
From the input data after conversion, the first derivation formula 1C or the second
Using the derivation formula 2C, the first temperature 1T or the second temperature 2
Derive T. The first temperature 1T is the standard temperature sensor 20a.
The second temperature 2T corresponds to the temperature of the first calibrated temperature sensor 20ba or the second calibrated temperature sensor 20bb.

The process steps performed in the first embodiment of the automatic temperature sensor calibration system 100 of the present invention will be described in detail below with reference to FIG.

The temperature setting processing section 30c of the information processing apparatus 30
Sends a temperature setting request signal 11 to the temperature controller 10a to request the temperature inside the electric furnace 10ba to be raised to the set temperature 12 (step S1). In response to the temperature setting request signal 11, the temperature controller 10a starts to raise the temperature inside the electric furnace 10ba to the set temperature 12, thereby raising the temperature inside the electric furnace 10ba to the set temperature 12 (step S2). . The first multimeter 10c outputs the temperature correspondence data 16 corresponding to the temperature detected by the standard temperature sensor 20a to the error detection unit 30 of the information processing device 30.
It is output to d (step S3). The error detection unit 30d is
It is detected that the temperature corresponding data 16 is within the first error range 1ERa (step S4).

The control unit 30h determines that the temperature inside the electric furnace 10ba is stable from the result of the detection by the error detection unit 30d, and the temperature correspondence data 16 when it is determined to be stable is obtained from the error detection unit. It outputs from 30d to the conversion process part 30e (step S5). The conversion processing unit 30e converts the temperature correspondence data 16 based on the delay time DTa (step S6). The derivation processing unit 30f calculates the first derivation formula 1C or the second derivation formula 2 from the converted temperature correspondence data 16.
The first temperature 1T is derived using C (step S7).

The second multimeter 10d detects the data 18 corresponding to the first temperature to be calibrated and outputs it to the conversion processing unit 30e (step S8). The conversion processing unit 30e converts the first calibration target temperature correspondence data 18 based on the delay time DTb (step S9). The derivation processing unit 30f uses the converted first
The second temperature 2T is derived from the data 18 to be calibrated by using the first derivation formula 1C or the second derivation formula 2C (step S10). The controller 30h controls the first temperature 1T and the second temperature 1T.
The difference between the temperatures 2T is calculated (step S11).

The channel selector controller 30g sends the measurement object notification signal 17 in order to request that the temperature sensor 20b to be calibrated to be measured be switched from the first temperature sensor 20ba to be calibrated to the second temperature sensor 20bb to be calibrated. It is transmitted to the channel selector 10e (step S12).
The channel selector 10e switches the measurement target in response to the signal (step S13).

After that, the same processing as in steps S8 to S11 is performed on the second temperature sensor 20bb to be calibrated. In the process, the first calibration target temperature correspondence data 18 in steps S8 to S11 is replaced with the second calibration target temperature correspondence data 19, and the delay time DTb is replaced with the delay time DTc. The second temperature 2T derived in step S10 is either the temperature 2Ta derived from the first calibration-target temperature correspondence data 18 or the temperature 2Tb derived from the second calibration-target temperature correspondence data 19.

(Second Embodiment) FIG. 5 shows a block diagram of a second embodiment of the automatic temperature sensor calibration system 100 of the present invention. The automatic temperature sensor calibration system 100 according to the second embodiment further includes a state detection sensor 50 in addition to the configuration according to the first embodiment.

The configuration of the information processing apparatus 30 according to the second embodiment is shown in FIG. The information processing device 30 illustrated in FIG. 6 further includes a second storage unit 30b-2 and a state determination unit 30i in addition to the configuration illustrated in FIG. Information stored in the second storage unit 30b-2 is shown in FIG. The second storage unit 30b-2 is
The temperature information TD and the first state information 1SD indicating a state when the electric furnace interior 10ba is stable at a temperature corresponding to the temperature information TD are stored. The state means the inside of the electric furnace 10
It shows the color of ba and the odor emitted from the inside 10ba of the electric furnace (components contained in the vapor that is emitted).

The state determination unit 30i includes a state detection sensor 50.
When the second state information 2SD indicating the current state of the electric furnace interior 10ba is received from the first state information 1S, the second state information 2SD corresponds to the temperature information TD of the set temperature 12.
The second storage unit 30b-2 is searched for a match with D.

In the second embodiment, the control unit 30 determines whether the temperature inside the electric furnace 10ba is stable.
The same process is performed except that h comprehensively judges the detection results by the error detection unit 30d and the state judgment unit 30i.

[0044]

The automatic temperature sensor calibration system of the present invention can provide a system in which the final judgment as to whether the temperature is stable does not vary depending on the operator.

The automatic temperature sensor calibration system of the present invention comprises:
It is possible to provide a system in which there is no possibility of a calculation error in converting the detected voltage into temperature.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration according to a first embodiment of an automatic temperature sensor calibration system of the present invention.

FIG. 2 is a diagram showing a configuration of an information processing device according to the first embodiment in the automatic temperature sensor calibration system of the present invention.

FIG. 3 is a diagram showing information stored in a first storage unit according to the first embodiment of the automatic temperature sensor calibration system of the present invention.

FIG. 4 is a diagram showing processing performed according to the first embodiment in the automatic temperature sensor calibration system of the present invention.

FIG. 5 is a diagram showing a configuration of an automatic temperature sensor calibration system according to a second embodiment of the present invention.

FIG. 6 is a diagram showing a configuration of an information processing device according to a second embodiment in the automatic temperature sensor calibration system of the present invention.

FIG. 7 is a diagram showing information stored in a second storage unit according to the second embodiment in the automatic temperature sensor calibration system of the present invention.

FIG. 8 is a diagram showing a conventional configuration in the automatic temperature sensor calibration system of the present invention.

[Explanation of symbols]

10a Temperature controller 10aa Digital meter 10ab First input part 10b Electric furnace 10ba Electric furnace inside 10bb Heater 10c First multimeter 10d Second multimeter 10e Channel selector 20a Standard temperature sensor 20b (20ba, 20bb) Fixed temperature sensor 20c Fixed Equipment 30 Information processing device 30a Second input unit 30b-1 First storage unit 30b-2 Second storage unit 30c Temperature setting processing unit 30d Error detection unit 30e Conversion processing unit 30f Derivation processing unit 30g Channel selector control unit 30h Control unit 30i State determination unit 40 Communication cable 50 State detection sensor 1SD First state information 1ER (1ERa, 1ERb, 1ERc) First error range DT (DTa, DTb, DTc) Delay time 1C First derivation formula 2C Second derivation formula 11 Temperature Setting request signal 12 Setting temperature 13 temperature interval 14 temperature range 14a temperature stabilization notification signal 15 temperature increase restart request signal 16 temperature correspondence data 17 measurement target notification signal 18 first calibration temperature correspondence data 19 second calibration temperature correspondence data ID identification number 1T first temperature 2T Second temperature

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Ichiro Nakanishi             Mitsubishi Heavy, 10 Oemachi, Minato-ku, Nagoya-shi, Aichi             Industrial Co., Ltd. Nagoya Aerospace System Production             In-house F-term (reference) 2F056 XA05 XA07

Claims (7)

[Claims] 1. An electric furnace that heats up to a set temperature, and a temperature sensor inserted inside the electric furnace,
A first multimeter that outputs data corresponding to the temperature detected by the temperature sensor, and the temperature correspondence data that is output from the first multimeter have a first error determined in advance in relation to the set temperature. An automatic temperature sensor calibration system comprising: an information processing device that determines that the temperature inside the electric furnace is stable by detecting that the temperature is within the range, and derives the first temperature from the temperature correspondence data. 2. The temperature sensor is a reference temperature sensor, and a second multimeter for detecting calibration target temperature-corresponding data output from at least two calibration target temperature sensors inserted in the electric furnace; In response to an instruction from the device, output data to the second multimeter is converted from one of the calibration target temperature data detected by one of the calibration target temperature sensors to another calibration target temperature sensor. The automatic temperature sensor calibration system according to claim 1, further comprising: a channel selector that switches to another data corresponding to the temperature to be calibrated detected by. 3. The automatic temperature according to claim 1, wherein the information processing device derives a second temperature from the calibration target temperature corresponding data and calculates a difference between the second temperature and the first temperature. Sensor calibration system. 4. The information processing apparatus includes a temperature setting processing unit that instructs the electric furnace to raise the temperature to the set temperature, and the temperature correspondence data and the calibration target temperature correspondence data are in the range of the first error. An error detection unit that detects that the temperature is within the range, a derivation processing unit that derives the first temperature from the temperature correspondence data, and derives the second temperature from the calibration target temperature correspondence data, and the first error range And a storage unit for storing the output data from the corresponding calibration target temperature data detected by the calibration target temperature sensor, the other calibration target detected by the other calibration target temperature sensor. The automatic temperature sensor calibration system according to any one of claims 1 to 3, further comprising a channel selector control unit that switches to temperature-corresponding data. 5. A step of raising the temperature to a set temperature, a step of outputting data corresponding to a temperature detected by a temperature sensor, and a step of outputting the data corresponding to the temperature, which is predetermined in association with the set temperature. An automatic temperature sensor calibration method comprising: a step of determining that the internal temperature of the electric furnace is stable by detecting that it is within an error range; and a step of deriving a first temperature from the temperature correspondence data. 6. The step of detecting the temperature-corresponding data to be calibrated output from at least two temperature sensors to be calibrated, and the output data to the second multimeter detected by any one of the temperature sensors to be calibrated. 6. The method for calibrating an automatic temperature sensor according to claim 5, further comprising the step of switching from the data corresponding to the temperature to be calibrated to another data corresponding to the temperature to be calibrated detected by the other temperature sensor to be calibrated. 7. The automatic temperature sensor calibration method according to claim 5, further comprising the step of deriving a second temperature from the data to be calibrated and calculating a difference between the second temperature and the first temperature. .