JP2707765B2 - thermometer - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermometer that measures the resistance value of a platinum resistance thermometer and measures the temperature from the resistance value.

<Conventional Technology> A resistance temperature detector is a temperature sensor that utilizes the property that the electrical resistance of a metal changes in proportion to the temperature. Among them, platinum resistance temperature detectors can be expected to measure temperature with high accuracy, and JIS C 1604
(RTD) and Platinum RTD conforming to JIS C 1606 (sheathed RTD) have guaranteed performance and characteristics.

The relationship between the resistance value Rt of the platinum resistance temperature detector Pt100 specified in the above two JIS and the temperature t ° C. is expressed by the following equation.

(A) the temperature is in the range of -200 ℃ ~0 ℃ Rt = Ro [ 1 + At + Bt 2 + C (t-100) t 3] ... (1) (b) the temperature is in the range of 0 ℃ ~650 ℃ Rt = Ro ( 1 + At + Bt ² )… (2) A: 3.90802 × 10 ^-3 ℃ ^-1 B: −5.802 × 10 ^-7 ℃ ^-2 C: −4.2735 × 10 ^-12 ℃ ^-4 Ro: 100Ω (resistance at 0 ℃) Value).

Therefore, in order to construct a thermometer, the temperatures t ° C. are successively substituted into the right sides of the equations (1) and (2), and the equations (1) and (2) are calculated. Then, for example, a linearization table in which Rt on the left side obtained as a result is compared with the temperature t ° C.
Store in ROM (Read Only Memory). In this calculation, the resistance Ro at 0 ° C. is Pt100 (the resistance at 0 ° C. is 1).
00Ω), so that Ro = 100.00Ω (JIS standard value).

Then, the resistance value Rt of the platinum resistance thermometer disposed at the temperature of the measurement target is actually measured, and the temperature t ° C. corresponding to the measured resistance value Rt is read from the previously prepared linearize table to perform temperature conversion. .

<Problems to be Solved by the Invention> The conventional thermometer as described above has the following two problems.

When the temperature is to be measured with a high resolution (for example, a resolution of 0.01 ° C.), high-precision measurement cannot be performed due to the following reasons.

For example, an example using a Pt100 resistance temperature detector will be described.
The conventional thermometer uses the resistance value Ro of the platinum resistance temperature detector at 0 ° C. as a JIS standard value (Ro = 100.00Ω). Then, a linearization table obtained as a result of performing the calculations of the equations (1) and (2) using Ro = 100.00Ω is stored in the ROM.

However, those manufactured by manufacturers of platinum resistance thermometers usually have an error within an allowable range defined by the JIS. Therefore, even if the user purchases a Pt100 platinum resistance temperature detector that conforms to JIS, the actual Ro value of this resistance temperature detector may be, for example, Ro = 100.01Ω.

Here, for example, if a platinum resistance temperature detector whose actual value is Ro = 100.01Ω is purchased and connected to a thermometer and the temperature is measured, it is assumed that Rt = 100.01Ω is measured at a certain temperature. . In this case, since the actual Ro value is Ro = 100.01, the measured value of the thermometer at this time must be 0 ° C. However, the table stored in the ROM of the thermometer is Rt = 100.00
Is determined to be 0 ° C., which causes a measurement error.

The thermometer has a connection terminal of a platinum resistance thermometer on a panel surface, and a user of the thermometer performs temperature measurement by connecting a separately purchased platinum resistance thermometer to this terminal. And
The measurement error at this time is not preferable because it depends on the variation of the Ro value of each platinum resistance temperature detector used by the user of the thermometer (however, within the allowable range of JIS) due to the above-described causes.

The linearization table cannot be shared by a plurality of types of resistance temperature detectors, for example, Pt100 and Pt1000 resistance temperature detectors.
Therefore, a lot of ROM is required.

The above has discussed the error in the variation of the resistance value Ro of the platinum resistance temperature detector of Pt100.However, in the thermometer storing the linearization table for Pt100, for example, Pt1000
When the resistance (Ro = 1000Ω at 0 ° C.) is connected, the value of Ro is completely different, so that the linearization table cannot be shared. Therefore, linearization tables for Pt100 and Pt1000 must be prepared, and many ROMs are required.

An object of the present invention is to solve the above two problems and to provide a thermometer in which a temperature measurement error is not affected by the Ro value of a platinum resistance temperature detector.

<Means for Solving the Problems> The present invention provides a measuring unit for measuring a resistance value (Rt) at a temperature t of a platinum resistance temperature detector connected to solve the above problem and obtaining a measured value α · Rt. A first storage means (8) in which a measurement accuracy value α of the measurement unit is stored in advance, a second storage means (6) in which a table of Rt / Ro versus temperature t is stored in advance, and (Ro is a platinum measurement value). Resistance value at 0 ° C. of the resistance thermometer), input data (Ro) indicating the actual resistance value of the connected platinum resistance thermometer at 0 ° C., the measurement accuracy value α, and the resistance measured by the measurement unit From the value α ・ Rt, α ・ Rt / α ・ R
o = Rt / Ro is calculated and the temperature t corresponding to this value is calculated as the second
Means (3) for reading from the storage means, and means comprising:

<Operation> The second storage unit stores a linearization table (hereinafter, referred to as a table) of Rt / Ro versus temperature t. Add a description. In the equations (1) and (2), when Ro is shifted to the left side, the value (Rt / Ro) on the left side can be calculated by substituting each t ° C. into the right side. This is stored as a table. Therefore, the Rt / Ro value stored in the table is uniquely calculated from t, and does not specify the Ro value. That is, it is not affected by the variation of the Ro value of each platinum resistance temperature detector (including the difference between Pt100 and Pt1000).

The Rt value can be obtained by the measurement unit. If the measurement accuracy of the measurement unit is α, the measured value becomes α · Rt. The resistance value Ro of a commercially available platinum resistance thermometer at 0 ° C is calculated by the manufacturer of the resistance bulb at the time of product delivery.
The data of the measured Ro value is attached to each product.
Ro value data attached by platinum resistance thermometer manufacturers can be interpreted as extremely accurate measurements. In the present invention, α ·
By performing the calculation of Rt / α · Ro = Rt / Ro, the value of Rt / Ro in which the accuracy α of the measurement unit is canceled can be obtained, and the temperature can be read from the table from the Rt / Ro value.

<Example> Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram showing an embodiment of a thermometer according to the present invention, FIG. 2 is a diagram showing a graph of a table shown in FIG. 3 stored in a ROM 6, and FIG. .

In FIG. 1, P1 and P2 are terminals to which a platinum resistance thermometer is connected, and are provided, for example, on a panel surface of a thermometer. And the person who uses the thermometer can use these terminals P1, P2
Is connected to a platinum resistance temperature detector 1 and placed at a temperature to be measured.

The platinum resistance temperature detector 1 has a known resistance Ro at 0 ° C. Normally, commercially available platinum resistance thermometers have the Ro value actually measured for each platinum resistance temperature detector attached to the product when the product is delivered by the resistance temperature sensor maker. Therefore, the user of the thermometer normally puts the platinum resistance temperature detector 1 in an environment of 0 ° C.
Need not be measured.

The measuring part 2 is composed of a resistance bulb 1 connected between the terminals P1 and P2.
It consists of an analog circuit, an AD converter, a digital circuit, and the like for measuring the resistance value of the device. Then, assuming that the resistance value of the resistance bulb 1 is Rt, the measuring section 2 outputs a measured value (digital signal) of α · Rt.

Here, “α” is a measurement accuracy value, and is a coefficient indicating the certainty of the measurement value in the measurement unit 2. This measurement accuracy α is
It is a unique value and can be measured in advance by each measuring unit 2. The measuring method will be described. For example, when a standard resistor having a resistance RA = 100.000Ω is connected to the terminals P1 and P2, if the measured value RB of the measuring unit 2 is RB = 99.980Ω, α = RB / RA = Expressed as 0.9998. This measurement accuracy value α is measured in advance as described above and stored in the EEPROM 8 described later.

Note that the measurement accuracy α is determined by the circuit configuration and the constituent electronic components of the measurement unit 2, and therefore, when measured with the thermometer assembled, the value hardly changes thereafter.

It should be noted that a known configuration can be used for the measuring unit 2, and the configuration of the measuring unit 2 does not necessarily have the features of the present invention, and thus the description of the specific configuration is omitted.

The CPU 3 is a central processing unit, and receives data supplied from the input / output unit 4, data supplied from the measurement unit 2, and a ROM.
6. The operation of calculating the temperature t in the resistance temperature detector 1 is performed according to the program described in the ROM 5 using the data from the RAM 7 and the EEPROM 8.

The input / output unit 4 includes a display unit for displaying a measured temperature value, and a keyboard for inputting an actual resistance value Ro of the temperature measuring resistor 1 at 0 ° C.

The ROM 5 is a storage unit in which various programs for the CPU 3 to perform an operation described later are described. For example, Ro '=
α ・ Ro correction calculation program and α ・ Rt / α ・ R
Stores a program that performs the operation of o.

The ROM 6 is a storage means in which a table of Rt / Ro vs. temperature t as shown in FIG. 3 is stored in advance. FIG. 2 shows a graph of the relationship between Rt / Ro and the temperature t, for example.

The RAM 7 is a storage unit used for storing a work area and a measured value when performing various calculations.

The EEPROM (electrically erasable PROM) 8 is a storage unit in which the measurement accuracy value α of the measurement unit 2 described above is stored in advance.

The operation of the FIG. 1 apparatus configured as described above will be described.

A table of Rt / Ro versus temperature t as shown in FIG. 3 is stored in the ROM 6 in advance. The data stored in the ROM 6 is obtained, for example, by the following calculation.

In the equations (1) and (2), Ro is shifted to the left side. When the values t = t1, t2, t3,... Are substituted into the right side, the values on the left side (Rt / Ro) are, for example, Rt / Ro = 0.1, 0.2, 0.
3, ... can be calculated. The ROM 6 stores this as a table. Therefore, Rt / Ro stored in the table
The value is uniquely calculated from the temperature t and does not specify the Ro value. In other words, unlike conventional thermometers that depend on the variation of the Ro value of each platinum resistance temperature detector (including a large resistance value difference such as Pt100 and Pt1000),
The present application is not affected.

The platinum resistance temperature detector 1 connected to the terminals P1 and P2 has a temperature t
In this case, it is assumed that the resistance value is Rt. This resistance value Rt is
When the measurement is performed by the measurement unit 2 and the measurement accuracy of the measurement unit 2 is α, the measured value is α · Rt. α · Rt is stored in the RAM 7 via the CPU 3.

On the other hand, the user of the thermometer reads the 0
The resistance value Ro in ° C. is input from the input / output unit 4 to the CPU 3.
The actual value of this Ro is known as described above,
The value data is temporarily stored in the RAM 7, for example.

Here, when the resistance value Rt of the resistance temperature detector 1 and the resistance value Ro at 0 ° C. of the resistance temperature detector 1 are known, the temperature t corresponding to the Rt / Ro value is obtained from the table stored in the ROM 6. You can know. However, the data input to CPU3 is α · Rt
And Ro, and the Rt value is multiplied by the measurement accuracy α.
Therefore, if a simple division is performed, α · Rt / Ro is obtained, and the measurement accuracy α affects the accuracy of the temperature measurement.

Therefore, in the present application, the following calculation is performed to cancel the measurement accuracy value α of the measurement unit 2. That is, CPU3
Read α from OM8, and read the measured Ro value at the temperature of 0 ° C. from RAM7. And, by the program stored in ROM5,
Calculate α ・ Ro.

Further, the CPU 3 reads the measured value α · Rt stored in the RAM 7 and performs an operation of α · Rt / α · Ro = Rt / Ro to obtain the value of Rt / Ro canceling the accuracy α of the measuring unit. Get. And from this Rt / Ro value, ROM6
The temperature can be read by referring to the data of (1).

In the above description, as a method of creating the table of FIG. 3, an example will be described in which t = t1, t2, t3,... Are substituted into the right sides of the equations (1) and (2), and as a result, Rt / Ro is obtained. did. However, conversely, the left side of the equations (1) and (2) is expressed as Rt / Ro = 0.1,0.
Obviously, t on the right side when 2, 0.3,... May be calculated to obtain t = t1, t2, t3,.

<Effects of the present invention> As described above, according to the present invention, since the linearization table has the relationship of <Rt / Ro vs. temperature>, it is not affected by the resistance value of each platinum resistance temperature detector. Temperature measurement with high resolution.

Pt100 (100 Ω resistance thermometer at 0 ° C.) and Pt50 (50 Ω resistance temperature at 0 ° C.)
And Pt1000 (a 1000 Ω resistance thermometer at a temperature of 0 ° C.) can be used to measure the temperature using the same linearization table. At this time, there are no JIS standards for Pt50 and Pt1000 platinum resistance thermometers.

[Brief description of the drawings]

FIG. 1 is a diagram showing one embodiment of a thermometer according to the present invention, FIG.
FIG. 3 is a graph of the FIG. 3 table stored in the ROM 6, and FIG. 1 ... Platinum resistance temperature detector, 2 ... Measuring unit, 3 ... CPU, 4
…… Input / output unit, 5,6… ROM, 7… RAM, 8… EEPRO
M.

Claims (1)

(57) [Claims] 1. A measuring section for measuring a resistance value (Rt) of a connected platinum resistance temperature detector at a temperature t to obtain a measured value α · Rt, and a measurement accuracy value α of the measuring section is stored in advance. A first storage means (8), a second storage means (6) for preliminarily storing a table of Rt / _R0 versus temperature t and ( _R0 is a resistance value of the platinum resistance temperature detector at 0 ° C.), which are connected to each other; From the input data (R ₀ ) indicating the actual resistance value of the platinum resistance temperature detector at 0 ° C., the measurement accuracy value α, and the resistance value α · Rt measured by the measurement unit, α · Rt / α・ R ₀
= Rt / _R0 , and the temperature t corresponding to this value is calculated as the second
A thermometer comprising: means (3) for reading from a storage means.