JPH0816629B2 - Optical thermometer - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an optical thermometer using an infrared sensor, and in particular to temperature measurement error correction thereof.

BACKGROUND ART Mercury thermometers have traditionally been widely used as clinical thermometers, but digital electronic thermometers have recently become increasingly popular.

Most conventional electronic thermometers use a thermistor as a sensor and are equipped with a calculation circuit and digital display for calculating the temperature value, but the time required to measure the temperature is 2 to 3 minutes, which is worse than that of a mercury thermometer.In contrast, electronic thermometers that predict the final value from the temperature rise over the first minute or so have the problem that the predicted value does not necessarily match the actual value.

The problem of time required to measure temperature is also related to the location of the temperature. The body's regulatory mechanisms maintain a predetermined temperature for the deep body temperatures of the head, chest, and abdominal cavity, but direct measurement of these temperatures is difficult. Therefore, rectal, oral, and axillary temperatures are generally used for measurement. Axillary temperature measurement is widely used, but the armpit is usually slightly open, and the skin temperature there is slightly lower. When the thermometer is placed under the armpit and the armpit is closed, the skin temperature begins to rise and reaches a constant temperature (equilibrium temperature) in about 10 minutes. After this, if the thermometer is removed and observed, a fairly accurate axillary temperature can be obtained. However, if the thermometer is removed earlier than this, the measurement will inevitably be slightly lower.

Another factor affecting temperature measurement time is the heat capacity of the sensor. Mercury thermometers use body heat to heat a mercury reservoir through the glass wall and then measure the expansion of the mercury, so the heat capacity of the heated object is quite large, requiring a measurement time of 2 to 3 minutes. Electronic thermometers also use body heat to heat the metal part that comes into contact with the measurement site, and the thermistor changes its resistance depending on the temperature of the metal part, so the heat capacity of the heated object (metal part) is also large.

Although all of these thermometers are contact types, there are also non-contact types, such as the "Non-contact Oral Thermometer" disclosed in Japanese Patent Application Laid-Open No. 58-88627. This uses a pyroelectric infrared sensor to collect infrared light emitted from the oral cavity, chop it, input it to the sensor, amplify the sensor output, calculate the body temperature based on the reference temperature signal, and display it on the display. Alternatively, a thermistor is used as the infrared sensor, and the light collecting system,
It consists of a thermistor, an amplifier, a calculator, a display mechanism, and a reference temperature detector.

Further, methods for measuring body temperature by inserting the ear canal are disclosed in Japanese Patent Application Laid-Open Nos. 60-25427, 60-216232, and 60-13333.
1, JP 61-117422, JP 61-138130, US Patent
3,282,106 (1966). However, these have not yet been realized due to the following problems:

Japanese Patent Laid-Open Publication No. 60-25427 only describes an earplug-type body temperature sensor, and it is unclear whether the body temperature is measured by contact heat transfer of a resistance temperature sensor such as a thermistor, or whether a silicon sensor that detects infrared rays is used. Therefore, since the measurement means is unclear, it is not possible to actually construct a clinical thermometer.

Japanese Patent Application Laid-Open No. 60-216232 uses an earplug-type thermistor as a temperature sensor to measure body temperature by contact heat transfer with the ear canal. However, because this is a contact method, it is easy to imagine that the temperature measurement time will be longer than with an oral electronic thermometer.

Japanese Patent Laid-Open No. 60-133331 is basically the same as Japanese Patent Laid-Open No. 60-216232, since it has a sealed ear and uses a thermistor and a transistor sensor as a temperature sensor.

Japanese Patent Application Laid-Open No. 61-117422 discloses an ear-insertion type device that uses a thermopile as an infrared detection sensor. The sensor is kept at a constant temperature, and a reference temperature source is provided within the device to measure body temperature using a reference method. While this is a superior method from a technical standpoint, maintaining a constant temperature in the sensor and providing a reference temperature source make the device complex, which makes it difficult to commercialize at low cost.

Japanese Patent Application Laid-Open No. 61-138130 uses an optical fiber to guide infrared light from inside the ear canal to a pyroelectric sensor, but no infrared optical fiber has been developed for measuring body temperature. The wavelength range of radiant energy emitted from body temperature is 8 to 13 μm, and no fiber has been developed that can fully transmit radiation in this wavelength range. At room temperature, radiation from the fiber itself cannot be ignored, so it is difficult to realize a clinical thermometer using optical fiber with sufficient accuracy, and even if it were realized, it would be extremely expensive.

US Patent 3,282,106 (1966) “Method of Measurement
"Measuring Body Temperature" relates to a method for measuring body temperature by non-contact detection of infrared rays in the 10 μm band emitted from cavities in the mammalian body, typically the ear. However, this patent does not take into account temperature changes in the sensor part, which results in temperature errors.

Thus, contact-type thermometers have the problem that they take a long time to measure the temperature, while conventional non-contact types that are sensitive to infrared rays have problems such as being complicated in construction and expensive.

The present invention aims to improve on these points and provide an optical thermometer that has a short temperature measurement time, is simple in construction, can be manufactured at low cost, and has high measurement accuracy.
In this case, the tip of the housing inserted into the hole may be heated by body heat, resulting in measurement errors. Another object of the present invention is to make this temperature rise negligible, thereby preventing temperature measurement errors.

Disclosure of the Invention According to a first invention for achieving the above object, there is provided an optical thermometer comprising: an infrared sensor (3) housed in a housing (11); an optical system (5) that focuses infrared rays incident from the tip of the housing inserted into a hole onto the infrared sensor; a temperature measuring element (4) that measures the ambient temperature of the infrared sensor; a thin cap (6a) that has protrusions on either or both of its front and rear ends and that contacts the outer peripheral surface of the tip of the housing at the protrusions and is attached to the tip of the housing so that an air gap is formed between the thin cap and the outer peripheral surface of the tip of the housing; a processing unit (20) that outputs a body temperature signal corrected for the ambient temperature of the infrared sensor; and a display (30) that receives the body temperature signal and visually displays the body temperature.

According to a second aspect of the present invention for achieving the above object,
The infrared sensor (3) is housed in a housing (11), an optical system (5) that focuses infrared light incident from the tip of the housing inserted into the hole onto the infrared sensor, a temperature measuring element (4) that measures the ambient temperature of the infrared sensor, and a processing unit (2) that outputs a body temperature signal corrected for the ambient temperature of the infrared sensor.
The optical thermometer is provided with a temperature sensor (30) for detecting the temperature of a subject and a display (30) for visually displaying the temperature upon receiving the temperature signal, and the tip is formed of a wire-shaped or rod-shaped member.

Furthermore, according to the third invention for achieving the above object,
An optical thermometer is provided, comprising: an infrared sensor (3) housed in a housing (11); an optical system (5) that focuses infrared rays incident from the tip of the housing inserted into a hole onto the infrared sensor; a first temperature measuring element (4a) that measures the ambient temperature of the infrared sensor; a second temperature measuring element (4b) that measures the temperature of the tip; a processing unit (20) that receives outputs from the infrared sensor and the first and second temperature measuring elements and outputs a body temperature signal corrected for the ambient temperature of the infrared sensor and the temperature of the housing tip; and a display unit (30) that receives the body temperature signal and visually displays the body temperature.

According to the optical thermometer having the configurations of the first to third inventions described above, even if the temperature of the tip of the housing, which is the temperature measuring part, comes into contact with the ear canal, oral cavity, etc. of the human body, which is the part to be measured, and the temperature of the tip of the housing changes, an accurate body temperature with little measurement error can be measured quickly and easily.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing the basic configuration of an optical thermometer which is a first embodiment of the first invention; Fig. 2 is a schematic perspective view and a schematic cross-sectional view of an integrated lens-type optical thermometer; Fig. 3 is a schematic perspective view of a separate lens-type optical thermometer; Fig. 4 is a schematic perspective view and a schematic cross-sectional view of an integrated mirror-type optical thermometer; Fig. 5 is a schematic view of a separate mirror-type optical thermometer; Fig. 6 is a diagram showing the relationship between blackbody temperature and thermopile output; Figs. 7 and 8 are diagrams showing the structure of a thermal insulator; Fig. 9 is a diagram showing an example of the configuration of a processing unit;
FIG. 10 is a diagram showing another example of the configuration of the processing unit, FIG. 11 is a diagram showing the sensor unit of the second embodiment of the first invention, FIG. 12 is a schematic cross-sectional view showing the experimental data thereof, FIG. 13 is a schematic view of the third embodiment of the first invention, FIG. 14 is a diagram showing the experimental data thereof,
FIG. 15 is a schematic perspective view and a schematic cross-sectional view of an optical thermometer (mirror type) according to an embodiment of the second invention, FIG. 16 is a schematic perspective view of the tip of the probe, FIG. 17 is a diagram showing experimental data, and FIG. 18 is a diagram showing the experimental data.
19 is an explanatory diagram of the optical system in the probe; FIG. 20 is a schematic diagram showing the state in which the temperature measuring element is attached to the tip of the probe; FIGS. 21 and 22 are diagrams showing an example of the configuration of the processing unit; and FIG. 23 is a diagram showing the basic configuration of the optical thermometer according to the third embodiment of the present invention.
The figure is a schematic perspective view showing an application example of the embodiment of the third invention, and No. 24
25 is a schematic perspective view showing a second application example of the third embodiment of the present invention;
The figure is a schematic perspective view showing a third application example of the third embodiment of the present invention.
FIG. 27 is a schematic perspective view showing another application example of the embodiment of the third invention.

BEST MODE FOR CARRYING OUT THE INVENTION A first embodiment of the first invention will be described below with reference to Figs. 1 to 10. Figs. 1(a) and 1(b) are diagrams showing the basic configuration of an optical thermometer according to the first embodiment of the first invention. This optical thermometer can be broadly divided into a probe 10, a processing section, and a
20 and a display unit 30.

The probe 10 has a housing 11, in which an infrared sensor such as a thermopile 3, a support 2 for the sensor, and an optical system 5 (consisting of a lens in FIG. 1(a) and a mirror in FIG. 1(b)) are installed.
The housing 11 also has a tip 12 (having dimensions and shape suitable for insertion into an orifice such as an ear canal or oral cavity), and a thermal insulator 6 is attached to the tip. A temperature measuring element 4 is disposed on the support 2, and this is an infrared sensor 3.
The temperature sensor 4 measures the ambient temperature, and therefore the temperature of the sensor 3. The temperature sensor 4 is composed of a resistance temperature sensor such as a thermistor, a temperature sensor IC such as a diode or a transistor, or the like.

The tip 12 has an opening at the tip 12a, and infrared rays emitted from the opening pass through the opening 12a and enter the housing.
The infrared light is collected by an infrared lens or mirror 5 and enters the infrared sensor 3. A diaphragm 1 is placed on this incident path, and the portion of the support 2 that corresponds to the incident path forms an aperture, and the periphery 2a of the aperture is conical. This conical peripheral surface 2a, together with the diaphragm 1, determines the solid angle of the infrared light that enters the infrared sensor 3. The peripheral surface 2a is the periphery of the infrared light (wavelength 5 to 1000 kHz).
20 μm), and when infrared rays emitted from inside the housing 11 are incident on the peripheral surface 2 a, the infrared rays are absorbed,
This prevents the infrared rays from entering the infrared sensor 3. The inner surface of the housing 11 is plated or vapor-deposited with Al, Au, Cr, etc. to make it mirror-finished, thereby reducing the emissivity in the infrared wavelength range.

The processing unit 20 includes a signal amplifier 21 that amplifies the output Vs of the infrared sensor 3, a calculator 22 that converts the output (resistance change) of the temperature measuring element (thermistor) 4 into a voltage Vo, and a signal processor 23 that receives the output V of the amplifier 21 and the output Vo of the calculator 22 and outputs a body temperature signal S. The amplifier 21, calculator 22, and signal processor 23 may be configured individually or integrally.

The processing unit 20 and the display unit 30 may be configured integrally with the probe 10 as shown in Figures 2 to 5, or may be configured separately. Figures 2(a) and 2(b) are a schematic perspective view and a schematic cross-sectional view of a lens-type optical thermometer, in which the probe, processing unit, and display unit are integrally formed.
The figure is also a schematic perspective view of a lens-type optical thermometer, but the probe and the processing unit/display unit are separate.
Figures (a) and (b) are a schematic perspective view and a schematic cross-sectional view of a mirror-type optical thermometer, in which the probe, processing unit, and display unit are integrally formed. Figure 5(a) is also a schematic perspective view of a mirror-type optical thermometer, but the probe, processing unit, and display unit are separate. In the case of a separate configuration, the amplifier 21 may be placed inside the probe 10, as shown in Figure 5(b).

According to the above configuration, when measuring body temperature, the probe
When the tip 12 of the device 10 is inserted into the ear canal, for example, infrared rays emitted from the ear canal, i.e., the cavity, according to its temperature, pass through the opening 12a at the tip and enter the housing 11. The incident infrared rays are converged by the lens or mirror 5 and projected onto the infrared sensor 3. Therefore, the output Vs of the infrared sensor 3 corresponds to the incident infrared rays, and therefore to the temperature inside the ear canal, and ultimately to body temperature.

However, the output Vs of the infrared sensor 3 also changes depending on the ambient temperature, as shown in Figure 6. In Figure 6, the vertical axis represents the output Vs, and the horizontal axis represents the blackbody temperature (body temperature according to the ear canal temperature) Tb. Curves _C1 , _C2 , and _C3 represent the temperature at room temperature (ambient temperature) of 0°, 20°, and 40°C.
This is the Vs-Tb curve for the case where the infrared sensor output Vs is the temperature at which the body temperature is measured. As is clear from this graph, in order to determine the body temperature, it is necessary to know the room temperature, i.e., the temperature around the infrared sensor, in addition to the infrared sensor output Vs.
This room temperature is provided by the calculator 22.

When the housing tip 12 is inserted into the ear canal, the temperature of the tip 12 rises, changing (increasing) the amount of external radiation emitted by the tip 12, which results in an error. This type of phenomenon is common in infrared thermometry, but is hardly a problem when the temperature of the object being measured is high. However, when the temperature is low, such as body temperature, it can cause a slight error (such as an error of 0.1°C for a 2°C increase). The thermal insulator 6 covers the housing tip 12 to provide thermal insulation and prevents the housing tip 12 from heating up during temperature measurement.

The signal processor 23 receives the output voltage V of the amplifier 21 and the arithmetic unit 22
Using the output voltage Vo of the infrared sensor, a correct body temperature signal S is output that has been corrected for the ambient temperature of the infrared sensor, and the body temperature is displayed on the display 30. If the display is an analog type, the signal S is an analog signal, and if it is a digital type, it is a digital signal.

The following explains temperature correction of the output of the infrared sensor 3. The generated electromotive force Vs of the infrared sensor (thermopile) 3 is proportional to α(T ⁴ - To ⁴ ), where α is a coefficient, T is the temperature of the object, and To is room temperature (both T and To are absolute temperatures).
When the measurement range is narrow, the error is very small even when calculated using linear approximation. In other words, the generated electromotive force Vs can be considered to be proportional to β(T-To) (β: a constant determined by the measurement temperature range, a coefficient that depends on the components, lens, mirror, shape, solid angle, etc.).

If the temperature measuring element 4 is a resistance temperature measuring element such as a platinum resistor,
The change in resistance with respect to temperature can be expressed as Ro = (1 + γt).
Here, the resistance value at 0°C, γ is the temperature coefficient, and t is the measurement temperature. For platinum resistors, this is the JIS standard. It can also be used with thermosensitive elements that exhibit negative characteristics, such as thermistors.

The amplified voltage V of the output Vs of the thermopile 3 is an output proportional to the temperature difference between the temperature T in the ear canal and the room temperature To (V = β
(T - To), and the temperature difference ΔT (= T - To) can be calculated by V/β. Since the room temperature To can be determined from the output Vo of the temperature measuring element 4, the temperature T of the object to be measured can be calculated by To + V/β.

7 and 8 are diagrams showing the structure of the thermal insulator 6. In Fig. 7(a), the thermal insulator 6 is a thin-walled cap 6a with a protrusion 61 at its front or rear end that contacts the outer periphery of the housing tip portion 12, forming an air gap 13 between the inner surface of the cap and the outer periphery of the housing tip portion. This air gap 13 provides thermal insulation. That is, when the tip portion of the probe 10 is inserted into the ear canal or oral cavity, the temperature of the tip portion 12 rises due to body heat, increasing the amount of infrared rays emitted from its inner surface. If this infrared light enters the infrared sensor 3, it will cause a temperature measurement error. However, the presence of the air gap 13 prevents the temperature of the housing tip portion 12 from rising, preventing the above-mentioned error from occurring.

The projections 61 should preferably have a small area so as to minimize heat transfer through them, and for this purpose, in FIG. 7(b), three narrow projections 61 are provided at 120° intervals. In FIG. 7(c), two projections 61 are provided at 180° intervals.
The protrusion in Fig. 7(c) is designed for stability.
The width is wider than the projection in FIG. 7(b).

The material of the cap 6a needs to have a certain degree of rigidity, so metal, hard plastic, etc. are preferable, but the material is not limited to these.

In Figure 8(a), the thermal insulator is a cap of thick insulating material.
The cap 6b is 6b. Since it is fitted to the tip 12 of the housing, the inner peripheral surface has the same shape as the outer peripheral surface of the tip. Figure 8(b) shows a perspective view of the cap 6b. The cap 6b can be made of polyurethane, polystyrene foam, glass wool, paper,
Cotton is good.

The opening 12a of the tip casing 12 may be covered with a thin plate of an infrared-transmitting material, such as silicon, germanium, polyethylene, etc. In this case, the thin plate may be attached to the cap. The cap may be fixed to the tip casing 12 or may be removable.

The inner surface of the housing tip 12 (from the tip 12a to the lens or mirror 5
It is also effective to make the inner surface of the tip (the area between the tip and the tip) as mirror-finished as possible. In other words, a mirror-finished surface reduces the emissivity, so even if the temperature of the tip 12 of the housing rises during temperature measurement, the change in the infrared rays emitted from the inner surface of the tip is small, and therefore the measurement error is small. For this reason, it is extremely effective to treat the inner surface of the tip with gold vapor deposition, gold plating, or aluminum vapor deposition, aluminum plating, etc.

An example of the configuration of the processing unit 20 is shown in Figures 9(a) and (b). In Figure 9(a), 25 is an adder (subtractor) that receives the output of the infrared sensor (thermopile 3 in this example) and the output of the temperature measuring element (thermistor 4 in this example), and outputs a body temperature signal S from the sum of these. That is, since V = β(T - To), Vo ∝ To, body temperature T can be obtained by multiplying V by 1/β and then adding the signal To from the temperature measuring element. 26 is a resistor that is connected in series with the thermistor 4 between the power supplies, and outputs an output voltage Vo to the connection point P.
For example, as shown in Figure 6, the thermopile outputs at points a, b, and c are Va, Vb, and Vc, respectively, and the blackbody temperature is Tb ₁ and the room temperature is 2
The thermopile output at 0°C is Vb, which is lower than the output Va at room temperature of 0°C by Va-Vb.
If Vb is generated by the thermistor 4, the blackbody temperature Tb can be obtained from the thermopile output after calibration at 0°C.

In FIG. 9(b), the thermistor 4, variable resistor 27, and fixed resistor 28 are connected in series between the power supplies, one end of the thermopile 3 is connected to the slider of the variable resistor 27, and the other end outputs a temperature signal S
The above addition is also performed with this. The variable resistor 27 is used to adjust the temperature characteristics of the output Vo.

Another example of the configuration of the processing unit 20 is shown in Fig. 10. In Fig. 10, 51 is an amplifier, 52 is a double integrator circuit, 53 is a CPU for performing arithmetic processing, and 54 is a coefficient setting unit consisting of a diode D and a switch S. 55 is an input port, 56 is an output port, and 57 is a
is a ROM in which a program is written. The signals from the thermopile 3 and the temperature sensor (room sensor) 4 are converted into sufficiently large signals by amplifiers 51, each with an appropriate amplification factor, and then input to a double integrator circuit 52 (a type of A/D converter). The double integrator circuit 52 outputs pulses with a duration proportional to the signal magnitude to the CPU 53, which measures the duration of these pulses using an internal counter. The count values corresponding to the signals from the thermopile 3 and the temperature sensor 4 are multiplied by coefficients set by a coefficient setting unit 54 to correct for individual differences in sensor characteristics. The corrected count values are then processed by the CPU 53, and the calculated final temperature value is output as the display value to the display unit 30.
Here, the coefficient setting unit 54 is composed of an array of diodes D and switches S, and by connecting it to the input/output port 55 of the CPU 53, the set coefficient value is determined digitally, and the sensor characteristics can be corrected using coefficient values that do not change over time. This eliminates the need for RAM, thereby reducing power consumption. Note that the switches S may be thin-film conductors instead of the mechanical contacts shown in Figure 10. This makes the coefficient setting unit 54 smaller and less expensive than mechanical switches.

According to the first embodiment described above, the room temperature of the thermopile 3 can be corrected, and the thermal insulator 6 provided at the tip 12 can prevent the temperature of the tip 12 from rising during temperature measurement, thereby reducing the occurrence of measurement errors.

FIG. 11 shows the second embodiment of the optical thermometer of the first invention.
11(a) to 11(e) are schematic cross-sectional views showing a sensor unit consisting of a thermopile, a temperature measuring element, and a support.
14 is the sensor part, 3x and 3y are the lead wires of thermopile 3, 4x
4y is a lead wire of the temperature measuring element 4. Since this embodiment is similar to the first embodiment except for the sensor unit 14, a perspective view and a structural diagram of this embodiment will be omitted.
In the second embodiment shown in Figures 11(a) to (e), the third embodiment described below, and other embodiments of the present invention, elements having the same functions as those in the first embodiment shown in Figures 1 to 10 above are designated by the same reference numerals, and detailed descriptions thereof will be omitted.

The second embodiment of the present invention differs from the first embodiment in that a temperature sensor 4 as a room temperature sensor is bonded to the bottom surface of a thermopile 3 as an infrared sensor, and both are embedded in a support 2 including a highly thermally conductive material. The sensor part shown in Figure 11(a) has a temperature sensor 4 (e.g., a posistor) bonded to the bottom surface of a thermopile 3, and the temperature sensor 4 is attached to a support 2 about 5 mm in length.
The sensor is embedded in a copper block ₂₁ having a thickness of 1/4 inch, and the entire structure is surrounded by a plastic ₂₂ with good thermal insulation properties.
The sensor unit shown in Fig. 11(b) uses a thermopile 3 that is slightly smaller than that shown in Fig. 11(a), and both the thermopile 3 and the temperature measuring element 4 are embedded in the copper block _21. In the sensor unit shown in Fig. 11(c), in order to further reduce the influence of heat transfer from the outside, the thermopile 3 and the temperature measuring element 4 are embedded in the copper block ₂₁ , and a heat insulating material 23 (for example, polyurethane, ceramic, glass fiber, etc.) is placed on the outside of the copper block 21, and a further heat insulating material ₂₃ is placed on the outside of the copper block ₂₁ .
Place copper pipe 2 ₄ on the outside of 2 ₃ and connect them with plastic
11(c) and the sensor part shown in _FIG . 11(e) is a modification of the sensor part shown in FIG. 11(b).
The lead wires 3x, 3y, 4x, and 4y are led out of the sensor unit 14 through holes (not shown) drilled in the copper block _21. The lead wires 3x, 3y, 4x, and 4y are covered with a coating to prevent short circuits between the lead wires. The copper block ₂₁ may be made of any metal with good thermal conductivity, such as aluminum.

Figure 12 shows experimental data for temperature readings obtained when the optical thermometer of this embodiment was operated continuously for 10 minutes facing a 40°C blackbody furnace. (s) indicates the reading when no copper block is used, (a) indicates the reading when the sensor unit shown in Figure 11(a) is used, and (c) indicates the reading when the sensor unit shown in Figure 11(c) is used. As shown in Figure 12, when using only the thermopile 3 (without the copper block), a thermal imbalance occurs between the thermopile 3 and the temperature measuring element 4 due to environmental temperature fluctuations, resulting in a fluctuation of approximately ±0.2°C in the output. In contrast, when the sensor unit 14 shown in Figure 11(a) with the copper block ₂₁ is used, a stable reading is obtained.
Furthermore, when the sensor unit 14 shown in Fig. 11(c) is used, the stability is further increased.
Although not shown, the same effect was obtained when the sensor unit 14 (e) was used. Thus, according to this embodiment, by placing a copper block or the like with good thermal conductivity around the thermopile 3 to increase the heat capacity and to block heat conduction from the outside, it is possible to improve the stability of the measurement. Other functions and effects are the same as those of the first embodiment.

Fig. 13 shows an optical thermometer according to a third embodiment of the first invention, with Fig. 13(a) being a schematic perspective view thereof, and Figs. 13(b) and 13(c) being schematic perspective views of the housing around the sensor unit. In Fig. 13(a) to 13(c), 11a is a cooling vent formed in the housing 11, and 11b is a metal mesh part that allows good ventilation.

The third embodiment of the present invention differs from the first or second embodiment in that a ventilation section is provided in the housing 11 around the sensor section 14 to improve ventilation of the sensor section 14.
In FIG. 13(a), a plurality of ventilation holes 11a are provided in a housing 11 around a sensor part 14 made of plastic. In FIG. 13(b), instead of providing ventilation holes 11a, a plurality of ventilation holes 11a are provided around the sensor part 14 of the housing 11.
The ventilation section shown in Fig. 13(c) is a separate probe type optical thermometer in which the sensor part of the probe housing 11 is surrounded by a metal mesh similar to that shown in Fig. 13(b).

Figure 14 shows experimental data of temperature readings when the optical thermometer of this embodiment was operated continuously for 30 minutes while facing a 40°C blackbody furnace and heating the periphery of the housing with a 45°C vinyl heater. In Figure 14, x marks indicate data for an optical thermometer without a ventilation section, and ○ marks indicate data for an optical thermometer with a ventilation section. As shown in Figure 14, with an optical thermometer without a ventilation section, thermal imbalance occurs around the sensor over time, causing measurement errors.
In the optical thermometer provided with the ventilation opening 11a shown in FIG. 13(a),
The effect is small. The same effect was obtained with the optical thermometer with the structure shown in Figure 13(b). Thus, according to this embodiment, by making the sensor periphery of the housing 11 a well-ventilated structure, heat transfer from the hand gripping the thermometer case during measurement is prevented, and the cooling effect can eliminate thermal imbalance around the sensor. As a result,
It is possible to provide a stable optical thermometer free from measurement errors. Other functions and effects are the same as those of the first embodiment.

As explained in detail above, according to the first invention, it is possible to provide a highly accurate, relatively inexpensive optical thermometer that can measure temperature quickly and easily, with room temperature correction of the infrared sensor and avoiding measurement errors caused by temperature rise due to insertion of the tip of the housing into the ear canal, oral cavity, etc.

An embodiment of the second invention will be described with reference to Figures 15 to 17. Figures 15(a) and 15(b) are a schematic perspective view and a schematic cross-sectional view of an optical thermometer (mirror type) according to an embodiment of the second invention, and Figures 16(a) to 16(c) are schematic perspective views of the tip of the probe. In Figures 15 and 16, 61 is a tripod-shaped insertion part, 62 is a plastic holder for the insertion part 61, and 63 is a mesh-like insertion part.

In the embodiment of the present invention, the insertion part 61 of the tip part 12 of the optical thermometer
63 is formed by a metal rod or metal wire with good thermal conductivity,
The tip portion 12 has good heat dissipation properties.

16(a) and (b) show that the insertion part 61 of the tip part 12 is made of a three-legged metal, and the tip 61a is formed into a ring shape that is large enough to fit into the human ear canal.
It is desirable that the inserting portion 61a is made of a metal with high thermal conductivity, such as Cu or Al. In FIG. 16(a), the diameter of the tip 61a is about 8 mm, and the leg 61b of the inserting portion 61 is fixed in the holding portion 62 made of plastic. For example, the holding portion
When forming 62 by plastic injection molding,
The tip of the leg 61b of the insertion part 61 is fixed so as to be embedded in the tip of the holding part 62. The leg 61b of the insertion part 61 is tapered at the same angle as the side part of the holding part 62, and the whole tip part 12 is formed to have a substantially conical shape.
As in the first embodiment, the diameter of the tip 61a of the insertion part 61 is approximately 8 mm, but the holding part 62 is formed in a cylindrical shape. If the diameter of the tip 61a is reduced to approximately 6 mm, it can be used as an optical thermometer for children. In Fig. 16(c), instead of the three-legged structure of the insertion part 63, a mesh made of a highly thermally conductive metal, such as Al, is attached to the holding part 62. The other configurations are the same as those of the respective embodiments of the first invention.

Figure 17 shows experimental data from 100 consecutive body temperature measurements over approximately 30 minutes using the optical thermometer of this embodiment shown in Figure 16(a) and an optical thermometer whose probe tip is made entirely of plastic. In Figure 17, x marks indicate data from the optical thermometer whose probe tip is made entirely of plastic, and ◯ marks indicate data from the optical thermometer shown in Figure 16(a). As shown in Figure 17, with an optical thermometer whose probe tip is made entirely of plastic, the temperature reading increases by more than 1°C, resulting in an error. In contrast, with an optical thermometer whose probe tip is shaped as shown in Figure 16(a), there is almost no error. Although not shown, optical thermometers with the structures shown in Figures 16(b) and (c) also produce almost no error.

As explained above, according to the embodiment of the second invention, by forming the tip 12 using a metal rod or metal wire with good heat dissipation properties, it is possible to prevent the temperature of the tip 12 from rising during temperature measurement, thereby reducing measurement errors.
The effect is the same as that of the first invention.

An embodiment of the third invention will be described with reference to Figs. 18 to 22. Fig. 18 shows the basic configuration of an optical thermometer, which is an embodiment of the third invention. In this invention, a temperature measuring element 4b is also attached to the tip 12, so that temperature measurement errors caused by temperature changes in the tip 12 during temperature measurement can be corrected.

In FIG. 18, 4a is a temperature measuring element for measuring room temperature;
4b is a temperature measuring element for measuring the temperature of the tip 12, and 24 is a computing unit for converting the output of the temperature measuring element 4b into a voltage.
A temperature measuring element 4b is provided on the support 2, which measures the temperature of the tip of the infrared sensor 3. A temperature measuring element 4a is also provided on the support 2, which measures the temperature of the infrared sensor 3 according to the ambient temperature of the sensor. The temperature measuring elements 4a and 4b are resistance temperature detectors such as thermistors,
It is composed of a diode or a PN junction of a transistor.

The temperature measuring element 4b may be embedded in the tip 12 as a small, round or rectangular, single-point measuring element as shown in Figure 20(a), or may be attached to the inner surface of the tip as a wide-area thin film (0.1 mm thick, for example) element as shown in Figure 20(c), or may be ring-shaped and fitted to the inner surface of the tip as shown in Figure 20(d).
It is also effective to fit a cover 13 on the tip 12 as shown in Fig. 1 to prevent the temperature measuring element 4b from measuring the temperature of the peripheral surface of a hole, for example, an ear canal, and to prevent the temperature of the tip 12 from rising when inserted into the ear canal.

The processing unit 20 in FIG. 18 includes a signal amplifier 21 that amplifies the output Vs of the infrared sensor 3, a calculator 22 that converts the output (resistance change) of the temperature measuring element (thermistor) 4a into a voltage Vo, and a calculator 23 that converts the output (resistance change) of the temperature measuring element (thermistor) 4b into a voltage Vr.
24, and the output V of the amplifier 21 and the output Vo of the calculators 22 and 24,
The present invention is also provided with a signal processor 23 which receives Vr and outputs a body temperature signal S. The amplifier 21, computing units 22 and 24, and signal processor 23 may be configured separately or integrated as shown in Figures 21 and 22. The other configurations are the same as those of the first invention.

When the tip 12 of the housing is inserted into the ear canal, the temperature of the tip 12 rises, and the amount of infrared light emitted by the tip 12 changes (increases), which causes an error.
₂ is emitted from the inner surface of the housing tip 12 and is detected by the infrared sensor 3
This shows the infrared rays incident on the object. This type of phenomenon occurs in infrared thermometry, but it is hardly a problem when the object to be measured is at a high temperature. However, when the temperature is low, such as body temperature, this can cause a slight error (for example, an error of 0.1°C for a 2°C rise). Calculator 2
The output Vr of 3 corrects this.

Using these V, Vo, and Vr, the signal processor 23 corrects the ambient temperature of the infrared sensor 3 and
The correct temperature signal S is output after temperature correction of 12.
The body temperature is displayed on the display 30. If the display is an analog type, the signal S is an analog signal, and if it is a digital type, it is a digital signal.

The temperature correction of the tip 12 will be explained below. Once the design of the probe 10 is based on optical technology, the entire probe 10 is treated as a measuring instrument and calibrated in a blackbody furnace. Furthermore, a signal processor is used to process the signal so that it is not affected by room temperature. Therefore, if the temperature of the probe tip 12 and the probe body (the part where the infrared sensor 3 is located) are the same, there is no effect of the tip 12. However, although temperature measurement is completed in a few seconds when inserted into the ear canal, if repeated temperature measurements are required, the temperature of the tip 12 gradually rises above room temperature, increasing the amount of infrared radiation emitted from the tip and entering the infrared sensor 3, resulting in a higher temperature reading. The error that occurs may occur, for example, when the tip 12 is made of Delrin, the opening 12a is 5-6 mmφ, the housing diameter at the junction with the infrared lens 5 is 13 mm, the probe tip is 25 mm long, and the temperature is measured at a temperature of 25 mm.
The inner surface was mirror-finished by Al vapor deposition.
When the temperature difference between the two is 2°C, it becomes 0.1°C.

The generated electromotive force Vs of the infrared sensor (thermopile) 3 is α
It is proportional to (T ⁴ − To ⁴ ) (T: object temperature, To: room temperature).
α is a correction coefficient determined by the components of the probe 10 (optical elements: lenses, mirrors, shape, solid angle, etc.). However, when the measurement range is narrow, that is, near body temperature (35
At temperatures between 100°C and 40°C, the error is very small even when calculated using a linear approximation. In other words, the generated electromotive force Vs can be considered to be proportional to β(T-To) (β: a constant determined by the measurement temperature range, which also includes the effects of the components).

If the temperature measuring elements 4a and 4b are resistance temperature sensors such as thermistors, the resistance change with temperature can be expressed as Ro = (1 + γt). Here, the resistance value at 0°C, γ is the temperature coefficient, and t
is the measurement temperature (unit: °C). For platinum resistors, JI
It is S standard.

The amplified voltage V of the output Vs of the thermopile 3 is an output proportional to the temperature difference between the temperature T in the ear canal and the room temperature To (V = β
(T - To), and the temperature difference ΔT (= T - To) is calculated by V/β. Since the room temperature To is determined from the output Vo of the temperature measuring element 4a, the temperature T of the object to be measured can be calculated by ΔT + To.

The output Vr of the temperature measuring element 4b detects the temperature (Tr) of the tip 12. When the measured temperature Tr=To, no correction is necessary, but when Tr>To or Tr<To, correction is necessary.
At To, the amount of infrared light incident on the thermopile 3 increases,
When Tr<To, it decreases. Therefore, when Tr>To, the calculated temperature T
When Tr<To, T becomes low. The amount of correction is determined by the shape of the tip 12 of the probe and the optical elements.
In the case of the lens configuration described above, the temperature difference |Tr−To| is 2
°C, which is 0.1°C. The signal processor 23 processes the above content (digital calculation processing, analog calculation processing, or a combination of both processing) to obtain the true temperature T of the object to be measured and displays it on the display 30.

As shown in FIGS. 21 and 22, the processing unit 20 may incorporate all or part of the infrared sensor 3 and the temperature measuring elements 4a and 4b into a circuit to obtain a temperature compensated output S.

In Fig. 21(a), temperature measuring elements 4a and 4b are connected in series and a current I is passed from a constant voltage power supply E, and a voltage Vp proportional to the correction voltage Vo-Vr is generated at the series connection point P of these temperature measuring elements, and by calculating this with the output Vs of the infrared sensor 3 in a calculator 15, S = Vs + Vo-Vr is obtained (here, the coefficients of each voltage are omitted; the same applies below). R is a resistance, and VR is a variable resistor (subscript
₁ , ₂ , ... are used to distinguish one from another and will be omitted here as appropriate), and variable resistor _VR1 is used to adjust the output voltage Vr of temperature measuring element 4b.

In Figure 21(b), the temperature measuring element 4a, variable resistor _VR2 , temperature measuring element 4b, and resistor _R2 are connected in series in that order, current I is passed through the constant voltage power supply, and the infrared sensor 3 is connected to the wiper of variable resistor _VR2 . Since Vo - Vr is obtained at this wiper, the output S at the other end of the infrared sensor 3 becomes Vs + Vo - Vr.

In FIG. 21(c), a constant current source Io is used to pass a current through the temperature measuring element 4a to generate Vo, and the constant current source is used to
A current is passed through 4b to generate Vr, and the infrared sensor 3 is connected in series to the temperature measuring element 4a to obtain S=Vs+Vo-Vr at the output terminal.

In Fig. 21(d), the temperature measuring elements 4a and 4b are connected to a bridge together with resistors _R5 and _R6 , and a current is passed through the power supply E to obtain Vo-Vr.
This is added to the output of the infrared sensor 3 to obtain S=Vs+Vo-Vr.

In FIG. 21(e), current is passed through the temperature measuring elements 4a and 4b to measure Vo,
In response to this, a calculator 16 generates Vo-Vr, which is added to the output Vs of the infrared sensor 3 to obtain S=Vs+Vo-Vr.

22(a) and (b) show a case where a platinum resistor or other such resistor having a positive temperature coefficient is used as the temperature measuring element 4a for room temperature correction.
An example is shown in which a temperature measuring element 4b for correcting the temperature at the tip of the probe, which has a negative temperature coefficient like a normal thermistor, is used. Figure 22(a) shows the case where a constant voltage source E is used, and Figure 22(b) shows the case where a constant current source is used. In both cases, Vo - Vr is obtained at the output terminal P, so this can be added to the output of the infrared sensor.

This optical thermometer is inserted into an orifice such as the ear canal or mouth to measure the temperature, so hygiene must be taken into consideration. If a cover 13 is used as shown in Figure 20(b), this cover can be used as a disposable item or can be removed and washed, which is effective from a hygienic standpoint.

Furthermore, making the tip 12a an opening is effective in that it allows infrared light to enter the housing 11 without loss, but is disadvantageous in that it allows dust to enter the housing 11. To address this issue, it is conceivable to cover the tip 12a with an infrared-transmitting window.

Figure 23 is a schematic perspective view showing a first application example of the third invention, and Figures 24(a) and (b) show plot and print examples. This application example combines a memory module and a printer with the optical thermometer of the third invention, allowing data to be stored and recorded. In Figure 23, 71 is the measurement unit main body, 72 is the memory module, and 73 is the printer. The measurement unit main body 71 is equipped with a hold switch 71a, and the display unit 30 displays the symbol M, indicating that the current display is memory. The memory module 72 is equipped with a memory address display 72a, a button 72b for counting up and down the memory address, and a button 72c for switching between the actual measurement value and memory display.
The printer 73 also has a button 73a for printing a single piece of data,
A plot button 73b and a print button 73c for printing all data are attached. 80 is printing paper.

When measuring a single data item using this application example,
The memory module 72 and printer 73 are separated and used only with the measuring unit main body 71. When measuring a large amount of data, connect the memory module 72 to the measuring unit main body 71 to store the data. The memory module 72 may have a built-in calendar function and clock function. This allows the date and time to be automatically stored. When you want to know the measured value, you can use the memory module 72.
A printer 73 is connected to the printer 73 for printing. Pressing the plot button 73b will give the output shown in Figure 24(a), and pressing the print all data button 73c will give the output shown in Figure 24(b).

This application example is convenient when a large amount of measurement data is required, and is effective when used as a women's thermometer or when measuring the temperature distribution on the human body surface.

25 is a schematic perspective view showing a second application example of the third invention. This application example is a desktop version of the third invention. The probe 10 has a main body 39.
The processing unit 20 is mounted in the main body 39. The display unit 30 may be analog or digital, or may display body temperature as cartoons, dividing it into normal, fever, high fever, etc. In the latter case, a liquid crystal display or the like is suitable as the display. The main body 39 is also provided with a memory and a printing mechanism (not shown), 36 for printing paper, 37 for printing paper, etc.
31 to 34 are paper feed buttons, and 31 is the date of the temperature measurement.
32 is for storing the temperature measurement results in memory, 33 is for display instructions, and 34 is for printing instructions. 38 is a calendar.
It is driven by a clock mechanism built into the main body 39 and displays the date and time.

Figures 26(a) to (c) are schematic perspective views showing a third application example of the embodiment of the third invention. Figures 26(a) and (b) are diagrams showing an optical thermometer formed in a pencil shape. In this case, the probe 10 is integrated with the main body (processing unit 20 and display unit 30). 18 is a cap that covers the tip of the probe, and is inserted when not in use to protect the tip opening (12a) and other parts. For hygienic reasons, it is preferable to store a porous elastic body impregnated with a disinfectant such as alcohol inside the cap 18. 19 is a switch that commands the start of measurement (power on). Immediately after power on, the direction in which the probe 10 is pointed,
In other words, since the ambient temperature measured is lower than body temperature, it is advisable to provide a means (in processor-based systems, a routine to determine whether the temperature is 35°C or higher) such that the temperature measurement result will not be displayed on the display unless it is, for example, 35°C or higher.

A pressure sensor may be provided at the tip of the probe, and when the tip is inserted into the ear canal, the sensor responds to pressure and displays the temperature. A temperature measurement result holding means may be provided to display the maximum temperature until reset, allowing the user to know the body temperature by pulling the probe tip out of the ear canal and looking at the display 30. Figure 25(C) shows an optical thermometer shaped like a pistol.

27(a) to (e) are schematic perspective views showing other application examples of the embodiment of the third invention. Fig. 27(a) is modeled after a compact used by women, Fig. 27(b) is integrated with lipstick 43, Fig. 27(c) has a cylindrical probe 10 that can be separated from the main body at the socket 44. Fig. 27(d) is for children, and the probe is shaped like an animal's nose. Fig. 27(e) is for use in medical institutions, and has a main body 39.
The thermometer is provided with a long-term monitor/diagnostic memory, a recorder/plotter, etc. In the application examples shown in Figs. 23 to 27, the case of an optical thermometer with a temperature measuring element 4b attached to the tip has been explained, but these application examples are not limited to the above case, and the tip may be thermally insulated as shown in each embodiment of the first invention, or may be thermally insulated as shown in each embodiment of the second invention.
As shown in the embodiment of the invention, the tip of the housing may be made of a metal mesh or the like that has good heatability.

As described above in detail, the third invention makes it possible to provide an optical thermometer that is highly accurate, relatively inexpensive, and capable of measuring temperature quickly and easily, with room temperature compensation and temperature compensation at the tip of the probe.

The first and third aspects of the invention are not limited to the above-mentioned embodiments, and may be used to measure the body temperature of animals, etc., in addition to the human body.

Industrial Applications As described above, the optical thermometer of the present invention is useful as a thermometer for measuring the temperature of the human body, and is particularly suitable for situations where accurate temperature measurements must be taken in a short time, such as when measuring the temperatures of young children or sick people, or when measuring the temperatures of a large number of people.

──────────────────────────────────────────────────── Continued from the front page (72) Inventor: Hirokatsu Yashiro 1618 Ida, Nakahara-ku, Kawasaki City, Kanagawa Prefecture First Technical Research Institute, Nippon Steel Corporation (72) Inventor: Yoichi Nagatake 1618 Ida, Nakahara-ku, Kawasaki City, Kanagawa Prefecture First Technical Research Institute, Nippon Steel Corporation (56) References: JP 61-117422 (JP, A) JP 61-138130 (JP, A) JP 58-88627 (JP, A)

Claims (14)

[Claims] [Claim 1] An infrared sensor (3) housed in a housing (11), an optical system (5) that focuses infrared light incident from the tip of the housing inserted into a hole onto the infrared sensor, a side temperature element (4) that measures the ambient temperature of the infrared sensor, and a thin cap (6) that has protrusions on the front and/or rear ends and is attached to the tip of the housing so that the protrusions come into contact with the outer circumferential surface of the tip of the housing and an air gap is formed between the protrusions and the outer circumferential surface of the tip of the housing.
a processing unit (20) that outputs a body temperature signal corrected for the ambient temperature of the infrared sensor; and a display (30) that receives the body temperature signal and visually displays the body temperature. [Claim 2] An optical thermometer comprising an infrared sensor (3) housed in a housing (11), an optical system (5) that focuses infrared rays incident from the tip of the housing inserted into a hole onto the infrared sensor, a temperature measuring element (4) that measures the ambient temperature of the infrared sensor, a thermal insulator (6) attached to the tip, a processing unit (20) that outputs a body temperature signal corrected for the ambient temperature of the infrared sensor, and a display (30) that receives the body temperature signal and visually displays the body temperature, wherein the temperature measuring element (4) is attached to the bottom surface of the infrared sensor (3), and at least the temperature measuring element (4) of the temperature measuring element (4) and the infrared sensor (3) is embedded in a highly thermally conductive material. [Claim 3] The optical thermometer described in claim 2, characterized in that the thermal insulator (6) is a thin-walled cap (6a) that fits into the tip of the housing, the cap having a protrusion at the tip or rear end or both, which protrusion contacts the outer surface of the tip of the housing, and an air gap is formed between the inner surface of the cap and the outer surface of the tip of the housing. 4. The optical thermometer according to claim 2, wherein the thermal insulator (6) is a cap (6b) made of a thick heat insulating material that fits onto the tip of the housing. [Claim 5] An optical thermometer as described in any one of claims 2 to 4, characterized in that the temperature measuring element (4), the infrared sensor (3) and the highly thermally conductive member are surrounded by a heat insulating material. 6. The optical thermometer according to claim 1, wherein the housing (11) is provided with a ventilation section in a portion that houses the infrared sensor. [Claim 7] An optical thermometer comprising an infrared sensor (3) housed in a housing (11), an optical system (5) that focuses infrared rays incident from the tip of the housing inserted into a hole onto the infrared sensor, a temperature measuring element (4) that measures the ambient temperature of the infrared sensor, a processing unit (20) that outputs a body temperature signal corrected for the ambient temperature of the infrared sensor, and a display (30) that receives the body temperature signal and visually displays the body temperature, wherein the tip is formed from a linear member, a rod-shaped member or a metal mesh member. [Claim 8] An optical thermometer as described in claim 7, characterized in that the temperature measuring element (4) is attached to the bottom surface of the infrared sensor (3), and at least the temperature measuring element (4) of the temperature measuring element (4) and the infrared sensor (3) is embedded in a highly thermally conductive material. 9. The optical thermometer according to claim 8, wherein the temperature measuring element (4), the infrared sensor (3) and the highly thermally conductive member are surrounded by a heat insulating material. 10. The optical thermometer according to claim 7, wherein the housing (11) is provided with a ventilation section in a portion that houses the infrared sensor. [Claim 11] An infrared sensor (3) housed in a housing (11), an optical system (5) that focuses infrared rays incident from the tip of the housing inserted into the hole onto the infrared sensor, and a first temperature measuring element (4a) that measures the ambient temperature of the infrared sensor.
and a second temperature measuring element (4b) for measuring the temperature of the tip portion.
a processing unit (20) that receives the outputs of the infrared sensor and the first and second temperature measuring elements and outputs a body temperature signal corrected for the ambient temperature of the infrared sensor and the temperature of the tip of the housing, and a display unit (30) that receives the body temperature signal and visually displays the body temperature. 12. The present invention is characterized in that the first temperature measuring element (4a) is attached to the bottom surface of the infrared sensor (3), and at least the first temperature measuring element of the temperature measuring element and the infrared sensor is embedded in a highly thermally conductive member.
11. An optical thermometer as described in paragraph 11. 13. The optical thermometer according to claim 12, wherein the first temperature measuring element (4a), the infrared sensor (3) and the highly thermally conductive member are surrounded by a heat insulating material. 14. The optical thermometer according to claim 11, wherein the housing (11) is provided with a ventilation section in a portion that houses the infrared sensor.