JP3703272B2 - Infrared thermometer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an infrared thermometer.
[0002]
[Prior art]
In recent years, with the progress of infrared technology, infrared thermometers are often used.
[0003]
In the infrared thermometer, the intensity of infrared rays generated from the measurement site is detected by an infrared sensor, the ambient temperature is detected by a temperature sensor, and the body temperature is obtained in a short time from the infrared sensor output and the temperature sensor output. For this reason, there is a great advantage that the measurement time is extremely short (for example, about 1 to 2 seconds) compared with a conventional thermometer that has been used conventionally, for example, when measuring the body temperature of an infant or child who is restless Is extremely useful.
[0004]
However, the conventional infrared thermometer has the following drawbacks as a result of shortening the measurement time.
[0005]
As shown in FIG. 9, when an infrared thermometer is attached, the signal (TP ′ signal) from the infrared sensor is stabilized with a predetermined thermal time constant. The output value varies, and this reduces the accuracy of measuring body temperature. In spite of this, the conventional infrared thermometer does not take into account the timing of signal acquisition from the infrared sensor.
[0006]
[Problems to be solved by the invention]
The objective of this invention is providing the infrared thermometer which can improve a measurement precision, without increasing the measurement time of body temperature.
[0007]
[Means for Solving the Problems]
Such an object is achieved by the present inventions (1) to (5) below.
[0008]
(1) a temperature sensor that detects an environmental temperature, and an infrared sensor that detects the intensity of infrared rays emitted from a measurement site, the thermal response of which is worse than that of the temperature sensor, and the level of the signal from the temperature sensor or In an infrared thermometer that measures body temperature based on the length of time and the level of the signal from the infrared sensor,
The thermal response of the infrared sensor starts when the infrared thermometer is attached,
An infrared thermometer configured to detect the level of a signal from the infrared sensor after detecting the level or time length of the signal from the temperature sensor.
[0009]
(2) A temperature sensor that detects the environmental temperature, an infrared sensor that detects the intensity of infrared rays emitted from the measurement site, and a temperature detection that normalizes the signal from the temperature sensor. A temperature detection standardized signal generating means for generating a standardized signal; and an infrared detection standardized signal generating means for generating an infrared detection standardized signal for normalizing a signal from the infrared sensor, from the temperature sensor. Infrared that measures body temperature based on the level or time length of the signal, the level of the signal from the infrared sensor, the level or time length of the temperature detection standardized signal, and the level of the infrared detection standardized signal In the thermometer,
The thermal response of the infrared sensor starts when the infrared thermometer is attached,
An infrared thermometer configured to detect the level of a signal from the infrared sensor after detecting the level or time length of the signal from the temperature sensor.
[0010]
(3) Detection of the level or temporal length of the signal from the temperature sensor, detection of the level of the signal from the infrared sensor, detection of the level or temporal length of the temperature detection standardized signal, and the infrared detection standard The infrared thermometer according to (2), wherein the detection of the level of the signal from the infrared sensor is performed last in the detection of the level of the activation signal.
[0011]
(4) It is configured to detect the level or time length of the signal from the temperature sensor between the detection of the level of the infrared detection standardized signal and the detection of the level of the signal from the infrared sensor. The infrared thermometer according to (2) or (3) above.
[0012]
(5) Any one of the above (2) to (4) configured to detect the level of the infrared detection standardized signal after detecting the level or time length of the temperature detection standardized signal The infrared thermometer as described.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the infrared thermometer of the present invention will be described in detail based on a preferred embodiment shown in the accompanying drawings.
[0014]
1 and 2 are a front view and a side view of an infrared thermometer of the present invention (hereinafter simply referred to as “thermometer”), respectively, and FIG. 3 shows a state in which the probe cover is attached to the probe in the thermometer of the present invention. 1 is a cross-sectional side view schematically showing the internal structure of the thermometer of the present invention, FIG. 5 is a perspective view showing the structure of the temperature measuring unit, and FIG. 6 is the present invention. It is a block diagram which shows the circuit structural example of this thermometer. For convenience of explanation, the upper side of FIGS. 1 and 2 is called “upper”, the lower side is called “lower”, the upper side of FIGS. 3 and 4 is called “tip”, and the lower side is called “base”.
[0015]
As shown in FIGS. 1 to 4, the thermometer 1 of the present invention is an ear thermometer that detects body temperature by measuring the intensity of infrared rays emitted from the ear (the eardrum), and has a casing 21. A power switch 3 and a display unit 5 installed on the front surface of the thermometer body 2, and a measurement switch 4 installed on the upper back of the thermometer body 2.
[0016]
The probe 6 is detachably attached to the thermometer body 2 on the upper front side of the thermometer body 2. As shown in FIG. 3, the support base 7 has a large diameter portion 71 and a small diameter portion 72 on the distal end side thereof. Is formed.
[0017]
On the other hand, the proximal end of the tubular probe 6 has a base 61 that contacts the distal end surface of the large-diameter portion 71, and a female screw 62 that engages with the male screw 74 is formed on the inner surface of the proximal end of the probe 6. Is formed. The probe 6 is supported and fixed to the support base 7 by screwing the male screw 74 and the female screw 62 together.
[0018]
The probe 6 has a shape in which the outer diameter gradually decreases toward the tip, and the tip outer peripheral portion (edge) 63 of the probe 6 is in consideration of safety when inserted into the ear cavity. It has a rounded shape.
[0019]
A light guide (waveguide) 8 that guides infrared rays (heat rays) introduced from the tip of the support base 7 to the infrared sensor 101 of the temperature detection unit 10 is provided upright at the center of the support base 7. The light guide 8 is preferably made of a metal such as copper having good thermal conductivity, and the inner surface thereof is plated with gold.
[0020]
The light guide 8 is covered with a protective sheet 81 so as to cover the opening at the tip. This prevents dust, dust, etc. from entering the light guide 8. The protective sheet 81 has infrared transparency, and examples of the constituent material thereof include the same resin material as the probe cover 11 described later.
[0021]
A ring nut 9 is screwed into the large diameter portion 71 of the support base 7. That is, a female screw 91 is formed on the inner surface of the base end side of the ring nut 9, and the female screw 91 is engaged with the male screw 73 of the large-diameter portion 71 so that the ring nut 9 is supported by the support base 7. Fixed.
[0022]
The ring nut 9 has a tapered portion 92 whose outer diameter gradually decreases from the vicinity of the distal end of the female screw 91 toward the distal end. The inner surface of the tapered portion 92 engages with the body portion 12 of the probe cover 11. An engaging portion 93 is formed.
[0023]
When the probe cover 11 is put on the probe 6, the ring nut 9 is attached, and the body 12 of the probe cover 11 is screwed by rotating in a predetermined direction, the inclined portion 64 of the probe 6 and the engaging portion 93 of the ring nut 9 are engaged. The probe cover 11 is securely fixed to the probe 6.
[0024]
In addition, a flange mounting base or the like is provided around the open end (base end) of the probe cover 11 of the present embodiment, and the probe cover 11 may be fixed by sandwiching the flange or the like between the probe 6 and the ring nut 9. it can.
[0025]
Accordingly, it is possible to prevent the probe cover 11 from being displaced from the probe 6 or being easily detached during body temperature measurement or the like. Further, in order to remove the probe cover 11 from the probe 6, the ring nut 9 must be rotated with a considerable force to release the screwing with the large-diameter portion 71, so that the infant accidentally removes the probe cover 11. Inconvenience such as putting in the mouth is also prevented.
[0026]
The tip end surface 94 of the ring nut 9 constitutes a substantially flat surface. When the probe 6 is inserted into the ear cavity, the distal end surface 94 abuts in the vicinity of the ear cavity entrance, and regulates the insertion depth of the probe 6 into the ear cavity to a constant depth. For this reason, measurement under appropriate conditions is always possible, and measurement errors due to variations in the insertion depth into the ear cavity can be prevented, and the depth of the ear is damaged by entering too deeply into the ear cavity of the probe 6. There is no inconvenience.
[0027]
In addition, a plurality of grooves (anti-slip means) 95 exhibiting an anti-slip effect when the ring nut 9 is rotated in the tightening direction or the loosening direction are provided on the outer peripheral surface of the tapered portion 92 of the ring nut 9 in the circumferential direction. It is formed at a predetermined interval. In addition, the same function can be exhibited even if it is not only a recessed part like the groove | channel 95 but a convex part. Further, a high friction material such as rubber may be provided.
[0028]
The probe cover 11 has a shape in which the proximal end is open and the distal end is closed. The probe cover 11 includes a cylindrical body 12 whose outer diameter and inner diameter gradually decrease toward the tip, a film 14 that can transmit infrared rays formed at the tip of the body 12, and an outer periphery of the film 14. The ring-shaped lip portion 15 is formed and protrudes from the film 14 toward the distal end side.
[0029]
And the trunk | drum 12, the film | membrane 14, and the lip | rip part 15 are preferably formed integrally with the resin material. Examples of the resin material include polyolefin such as polyethylene, polypropylene, and ethylene-vinyl acetate copolymer, and polyester such as polyethylene terephthalate and polybutylene terephthalate.
[0030]
In the probe cover 11, since the lip portion 15 exists, the film 14 is lowered from the distal end of the probe cover 11 to the proximal end side by a predetermined distance. As a result, when the probe cover 11 is attached to the probe 6 and inserted into the ear cavity, the membrane 14 touches the inner surface of the ear cavity or the periphery thereof, or when the probe cover 11 is attached to or detached from the probe 6. Since the finger or the like is prevented from being touched and the surface of the film 14 can be kept clean, higher measurement accuracy can be maintained.
[0031]
The inside of the lip portion 15 has a shape that fits into the tip portion of the probe 6. That is, as shown in FIG. 3, in a state where the probe cover 11 is attached to the probe 6, the lip portion 15 is fitted to the distal end outer peripheral portion 63 of the probe 6. This prevents the tip of the probe cover 11 from being displaced with respect to the probe 6 during insertion into the ear cavity (measurement) or the like, and the membrane 14 is stretched with a constant tension. Since wrinkles and sagging are prevented from occurring, this contributes to improvement in measurement accuracy.
[0032]
Moreover, the tip of the lip portion 15 has a rounded shape. Thus, when inserted into the ear cavity, high safety is ensured without feeling pain or damaging the inner wall of the ear cavity.
[0033]
As shown in FIG. 4, a circuit board 30 is installed in the casing 21. As shown in FIGS. 4 and 6, the circuit board 30 includes a temperature measuring unit 10 and control means 31 including a microcomputer. Amplifying means 32, changeover switch 35, integration circuit 36, comparator 37, reference resistor 38, changeover switch 39, relay circuit 41 and buzzer 42 are mounted. In addition, a power supply unit 40 that houses a battery is installed in the casing 21, and electric power is supplied from the power supply unit 40 to each part of the circuit board 30.
[0034]
The temperature detection unit 10 includes an infrared sensor 101 and a temperature sensor 107.
[0035]
The control unit 31 includes a calculation unit 311, a memory (RAM, ROM, EEPROM) 312, a timer (including an auto power off timer) 313, and a counter 314.
[0036]
The control means 31 includes an auto power off timer in order to suppress wasteful power consumption.
[0037]
The auto power off timer automatically turns off the power after a predetermined time (for example, 60 seconds) from the start of the timer when the power switch 3 is left on. Even when the power switch 3 is turned off within a predetermined time from the start of the auto power off timer, the timer continues its counting operation (time measurement) until the predetermined time elapses.
[0038]
As shown in FIG. 5, the infrared sensor 101 includes a thermopile (thermocouple array) 102. The hot contact 103 of the thermopile 102 is installed in the heat collecting portion 106 located on the center side via the thermal insulation band 105, and the cold junction 104 is installed on the outer peripheral side of the thermal insulation band 105.
[0039]
A temperature sensor 107 is installed in the vicinity of the infrared sensor 101. The temperature sensor 107 detects the temperature on the outer peripheral side of the thermal insulation band 105 of the infrared sensor 101, that is, the temperature of the cold junction 104, and also detects the temperature of the atmosphere (environment temperature). As the temperature sensor 107, a sensor that measures temperature with a resistor is used. For example, a thermistor can be used as a sensor for measuring temperature with a resistor.
[0040]
In such a temperature detection unit 10, a signal corresponding to a temperature difference between the hot junction 103 heated by infrared irradiation and the cold junction 104 not irradiated with infrared rays by the infrared sensor 101 and the temperature sensor 107, and the vicinity of the cold junction 104. The body temperature can be measured by detecting a signal corresponding to the temperature (environment temperature).
[0041]
Next, the usage method, circuit configuration, and operation of the thermometer 1 will be described.
As described above, the probe 6 is screwed and attached to the small diameter portion 72 of the support base 7 of the thermometer main body 2, and the probe cover 11 is put on the probe 6. Next, from above, the ring nut 9 is inserted and screwed into the large diameter portion 71 of the support base 7. As a result, the body 12 of the probe cover 11 is sandwiched between the inclined portion 64 of the probe 6 and the engaging portion 93 of the ring nut 9, and the probe cover 11 is fixed to the probe 6. Thereby, the mounting of the probe cover 11 is completed.
[0042]
Next, the power switch 3 is turned on, and after a predetermined time has passed, the thermometer body 2 is gripped, and the probe 6 encapsulated by the probe cover 11 is inserted into the ear cavity.
[0043]
Next, the measurement switch 4 is pressed for a predetermined time. Thereby, the body temperature is measured. That is, infrared rays (heat rays) radiated from the ear (the eardrum) are sequentially transmitted through the membrane 14 and the protective sheet 81, introduced into the light guide 8, and repeatedly reflected on the inner surface of the infrared sensor 101 of the temperature detecting unit 10. And the heat collecting unit 106 is irradiated.
[0044]
As shown in FIG. 6, the infrared sensor 101 obtains an output signal (TP signal) from the hot junction 103 as a positive output terminal and an output signal (VREF signal) from the cold junction 104 as a negative output terminal.
[0045]
The level (voltage) of the VREF signal from the cold junction 104 of the infrared sensor 101 is constant (fixed) regardless of the environmental temperature.
[0046]
The amplifying unit 32 includes a first amplifier 33 and a second amplifier 34 connected to the output side of the first amplifier 33. Each of the first amplifier 33 and the second amplifier 34 is a differential amplifier.
[0047]
The TP signal output from the infrared sensor 101 is amplified by the first amplifier 33 and input to the second amplifier 34. The first amplifier 33 removes unnecessary frequency band components included in the TP signal and the VREF signal as necessary.
[0048]
Further, the VREF signal output from the infrared sensor 101 is input to the first amplifier 33 and the second amplifier 34. The second amplifier 34 also removes unnecessary frequency band components included in a TP ″ signal and a VREF signal, which will be described later, as necessary.
[0049]
In the first amplifier 33, the difference between the TP signal and the VREF signal is amplified, and a signal TP ″ signal obtained by adding the VREF signal is obtained. Further, in the second amplifier 34, the difference between the TP ″ signal and the VREF signal is obtained. Are amplified, and the VREF signal is added and output as a TP ′ signal. The level of this TP ′ signal corresponds to the temperature difference between the hot junction 103 and the cold junction 104. Unless otherwise specified, the signal from the infrared sensor means the TP ′ signal.
[0050]
When the changeover switch 35 is switched to the TP ′ signal side, the TP ′ signal is input to the comparator 37, and when the changeover switch 35 is switched to the VREF signal side, the VREF signal from the first amplifier 33 is input to the comparator 37. . The driving of the changeover switch 35 is controlled by the control means 31.
[0051]
The VREF signal from the first amplifier 33 is also an infrared detection standardized signal that standardizes the TP ′ signal. By standardizing the TP ′ signal with this VREF signal (strictly speaking, Ttp is standardized with Tvref, which will be described later), for example, it is possible to reduce (cancel) the influence of circuit stray capacitance and chip component variations. This improves the measurement accuracy. The cold junction 104 and the first amplifier 33 constitute infrared detection standardized signal generation means.
[0052]
A constant (fixed) level reference voltage is applied to the integrating circuit 36. The integration circuit 36 generates a reference signal based on the reference voltage, and the reference signal is input to the comparator 37. The reference voltage is set sufficiently higher than the level of the TP ′ signal and the level of the VREF signal.
[0053]
When detecting the TP ′ signal, the changeover switch 35 is switched to the TP ′ signal side by the control signal from the control means 31. Then, an STC signal (sampling start signal) is transmitted from the control means 31 to the integrating circuit 36.
[0054]
As shown in FIG. 7, when receiving the STC signal, the integration circuit 36 decreases (drops) the level of the reference signal from the reference voltage with a constant gradient (slope).
[0055]
As shown in FIG. 6, the comparator 37 compares the level of the reference signal with the level of the TP ′ signal. When the level of the reference signal matches the level of the TP ′ signal, the comparator 31 sends an EOC signal (sampling end). Signal) and a trigger signal to the integrating circuit 36.
[0056]
As shown in FIG. 7, when the integration circuit 36 receives the trigger signal, the level of the reference signal is instantaneously restored to the original level, that is, the reference voltage.
[0057]
In the control means 31, the timer 313 measures the time (Ttp) from when the STC signal is transmitted to when the EOC signal is received. This time information, that is, Ttp, is stored in the memory 312.
[0058]
The level of the TP ′ signal changes according to the temperature difference between the hot junction 103 and the cold junction 104, and Ttp also changes accordingly. In this case, as the temperature difference between the hot junction 103 and the cold junction 104 is larger, the level of the TP ′ signal is larger and Ttp is shorter (smaller).
[0059]
As shown in FIG. 6, when the VREF signal is detected (when the signal from the infrared detection standardized signal generating means is detected), the changeover switch 35 is switched to the VREF signal side by the control signal from the control means 31. . Then, the STC signal is transmitted from the control means 31 to the integrating circuit 36.
[0060]
As shown in FIG. 7, when receiving the STC signal, the integrating circuit 36 decreases the level of the reference signal from the reference voltage with a constant gradient.
[0061]
As shown in FIG. 6, the comparator 37 compares the level of the reference signal with the level of the VREF signal. When the level of the reference signal matches the level of the VREF signal, the comparator 37 transmits an EOC signal to the control means 31. A trigger signal is transmitted to the integrating circuit 36.
[0062]
As shown in FIG. 7, when the integration circuit 36 receives the trigger signal, the level of the reference signal is instantaneously restored to the original level, that is, the reference voltage.
[0063]
In the control means 31, the timer 313 measures the time (Tvref) from when the STC signal is transmitted to when the EOC signal is received. This time information, that is, Tvref is stored in the memory 312.
[0064]
As shown in FIG. 6, the relay circuit 41 includes a capacitor (not shown) and the like, and constitutes a part of an oscillation circuit (CR oscillation circuit).
[0065]
When the changeover switch 39 is switched to the temperature sensor 107 side, the relay circuit 41 and the temperature sensor 107 form an oscillation circuit. When the changeover switch 39 is switched to the reference resistor 38 side, the relay circuit 41 and the reference resistor 38 are connected to the oscillation circuit. Is configured. The driving of the changeover switch 39 is controlled by the control means 31.
[0066]
Although the resistance value TH of the temperature sensor 107 changes according to the environmental temperature, the resistance value RH of the reference resistor 38 is constant (fixed) regardless of the environmental temperature.
[0067]
When the resistance value TH of the temperature sensor 107 is detected (when a signal from the temperature sensor 107 is detected), the changeover switch 39 is switched to the temperature sensor 107 side by a control signal from the control means 31.
[0068]
Thus, the relay circuit 41 and the temperature sensor 107 constitute an oscillation circuit, and oscillation is generated by this oscillation circuit. The signal (oscillation signal) at that time, that is, the Fth signal is output from the relay circuit 41 and input to the control means 31.
[0069]
As shown in FIG. 8, in the control means 31, the counter 314 counts the number of pulses of the input Fth signal, and the timer 313 requires the counter 314 to count a predetermined number (for example, 256) of pulses. Time (Tth), that is, time (Tth) that is an integral multiple (for example, 256 times) of the cycle (wavelength) of the Fth signal is measured. This time information, that is, Tth is stored in the memory 312.
[0070]
The resistance value TH of the temperature sensor 107 changes according to the environmental temperature, and Tth also changes accordingly. In this case, the resistance value TH of the temperature sensor 107 increases as the environmental temperature decreases. In the CR oscillation circuit, since the period (wavelength) of the oscillation signal is proportional to the resistance value, the lower the environmental temperature, the longer the period of the Fth signal and the longer (large) Tth.
[0071]
As shown in FIG. 6, when the resistance value RH of the reference resistor 38 is detected (when the temperature detection standardization signal is detected), the changeover switch 39 is moved to the reference resistor 38 side by the control signal from the control means 31. Switch.
[0072]
Thus, the relay circuit 41 and the reference resistor 38 constitute an oscillation circuit, and oscillation is generated by this oscillation circuit. The signal (oscillation signal) at that time, that is, the Frh signal is output from the relay circuit 41 and input to the control means 31.
[0073]
The Frh signal is a temperature detection normalization signal that normalizes the Fth signal. By normalizing the Fth signal with this Frh signal (strictly speaking, Tth is normalized with Trh, which will be described later), for example, it is possible to reduce (cancel) the influence of circuit stray capacitance and chip component variations. This improves the measurement accuracy. The reference resistor 38 and the relay circuit 41 constitute a temperature detection standardized signal generating unit.
[0074]
As shown in FIG. 8, in the control means 31, the counter 314 counts the number of pulses of the input Frh signal, and the timer 313 requires the counter 314 to count a predetermined number (for example, 256) of pulses. Time (Trh), that is, a time (Trh) that is an integral multiple (for example, 256 times) of the period (wavelength) of the Frh signal is measured. This time information, that is, Trh, is stored in the memory 312.
[0075]
Since the resistance value RH of the reference resistor 38 is constant regardless of the environmental temperature, the period of the Frh signal is constant, and therefore Trh is constant.
[0076]
The calculation unit 311 of the control unit 31 reads Ttp, Tvref, Tth, and Trh from the memory 312, normalizes Ttp with Tvref, and normalizes Tth with Trh. That is, Ttp / Tvref and Tth / Trh are obtained, respectively.
[0077]
Then, based on these Ttp / Tvref and Tth / Trh, a predetermined calculation process is performed, and a predetermined temperature correction is performed as necessary to determine the temperature of the measurement site (heat source), that is, the body temperature.
[0078]
The obtained body temperature is displayed on the display unit 5. Further, when the measurement of the body temperature is completed, the buzzer 42 sounds to notify it. The operator pulls out the probe 6 from the ear cavity by the notification of the buzzer 42.
The control operation of the control means 31 will be described in detail later.
[0079]
In this thermometer 1, in the measurement of the body temperature, the above-described detection of the TP ′ signal (detection of the signal from the infrared sensor 101), that is, measurement of Ttp (measurement), detection of the VREF signal, that is, measurement of Tvref, and Fth signal (Detection of a signal from the temperature sensor 107), that is, measurement of Tth and detection of Frh signal, that is, measurement of Trh are performed in a predetermined order to be described later (performed in a time-sharing manner). Hereinafter, the order of signal detection (measurement) will be described.
[0080]
FIG. 9 is a graph showing the relationship between the elapsed time from when the thermometer 1 is worn on the ear and the level (voltage) of the TP ′ signal (thermal response characteristic of the TP ′ signal).
[0081]
As shown in the figure, when the thermometer 1 is worn on the ear, the TP ′ signal is stabilized with a predetermined thermal time constant. That is, the level (voltage) of the TP ′ signal reaches a stable level with a predetermined thermal time constant.
[0082]
However, the timing at which the operator turns on the measurement switch 4 after wearing the thermometer 1 on the ear is not always constant, and the measurement switch 4 is turned on when the elapsed time since the thermometer 1 is worn is relatively short. When it is turned on and the body temperature measurement time is relatively short, it is thermally unstable due to the influence of the timing at which the measurement switch 4 is turned on, and the level of the detected TP ′ signal, that is, Ttp varies. Arise.
[0083]
Therefore, the thermometer 1 detects the TP ′ signal, detects the VREF signal, detects the Fth signal, and detects the Frh signal so that the TP ′ signal is detected when the TP ′ signal becomes more stable. Of these, the order of signal detection is preferably set so that the TP ′ signal is detected last.
[0084]
Thus, when the body temperature is measured in a short time, the level of the detected TP ′ signal, that is, the variation in Ttp can be reduced, and thus the body temperature measurement accuracy can be improved.
[0085]
FIG. 10 is a graph showing the VREF signal side and the TP ′ signal when the changeover switch 35 is switched from the VREF signal side to the TP ′ signal side.
[0086]
As shown in the figure, t ₁ When the changeover switch 35 is switched from the VREF signal side to the TP ′ signal side, the TP ′ signal is stabilized with a predetermined electrical time constant. That is, the level (voltage) of the TP ′ signal reaches a stable level with a predetermined electrical time constant. t ₁ ~ T ₂ This period is a period in which the TP ′ signal is unstable (electrically).
[0087]
As shown in FIG. 10, immediately after the detection of the VREF signal, when the changeover switch 35 is switched from the VREF signal side to the TP ′ signal side to detect the TP ′ signal, before the TP ′ signal is stabilized, that is, t ₁ ~ T ₂ During this period, the level of the TP ′ signal matches the level of the reference signal. For this reason, a time shorter by Δt than the appropriate value is measured, and this is taken in as Ttp.
[0088]
Therefore, in the thermometer 1, t ₂ Thereafter, in order to provide a predetermined interval between the detection of the VREF signal and the detection of the TP ′ signal so that the level of the TP ′ signal matches the level of the reference signal, the detection of the VREF signal and the detection of the TP ′ signal are performed. The order of signal detection is preferably set so as to perform at least one of detection of the Frh signal and detection of the Fth signal.
[0089]
In this case, since the Fth signal and the TP ′ signal are temperature-dependent, in order to improve the measurement accuracy of the body temperature, the detection of the Fth signal and the detection of the TP ′ signal are made closer to each other. Each detection is preferably performed under the same conditions.
[0090]
Therefore, it is more preferable that the signal detection order is set so that the Fth signal is detected between the detection of the VREF signal and the detection of the TP ′ signal.
[0091]
Further, since the VREF signal is input to the changeover switch 35 via the amplifying means 32, the time from when the amplifying means 32 is turned on until the signal detection is made longer, and when the amplifying means 32 becomes more stable, VREF. It is better to perform signal detection.
[0092]
Therefore, as for the order of detection of the Frh signal and the detection of the VREF signal, it is preferable that the order of signal detection is set so that the VREF signal is detected after the detection of the Frh signal. Thereby, since the VREF signal can be detected when the amplification means 32 is more stable, the measurement accuracy of the body temperature is further improved.
[0093]
The order of signal detection described above can be summarized as follows: TP ′ signal detection, VREF signal detection, Fth signal detection and Frh signal detection order are first Frh signal detection, next VREF signal detection, It is particularly preferable that the next is set to detect the Fth signal and the last to detect the TP ′ signal.
[0094]
In the present invention, if the order of the detection of the TP ′ signal, the detection of the VREF signal, the detection of the Fth signal and the detection of the Frh signal is as described above, arbitrary processing is performed between these signal detections. It may be configured as follows.
[0095]
Next, the control operation of the control means 31 when measuring body temperature will be described.
FIG. 11 is a flowchart showing the control operation of the control means 31 when measuring the body temperature (in the order of Frh signal detection, VREF signal detection, Fth signal detection, and TP ′ signal detection). Hereinafter, description will be given based on this flowchart.
[0096]
When the power switch 3 is turned on, initialization is performed, the changeover switch 35 is switched to the VREF signal side, and the changeover switch 39 is switched to the reference resistor 38 side, and the relay circuit 41 and the reference resistor 38 constitute an oscillation circuit. Is done.
[0097]
After completion of the initial setting, the measurement switch 4 is waited for input, and it is determined whether or not the measurement switch 4 is turned on (step S101). When the measurement switch 4 is turned on, the process waits for a predetermined time (step S102).
[0098]
By this standby, the time from when the thermometer 1 is worn to the detection of the TP ′ signal in step S108 described later can be made longer, whereby the TP ′ signal can be made more stable. Therefore, the measurement accuracy of body temperature is further improved.
[0099]
Further, compared with the case where the standby time is adjusted only by standby in step S104, which will be described later, the time during which the first amplifier 33 and the second amplifier 34 are on can be shortened, thereby reducing the power consumption. it can.
[0100]
Next, the first amplifier 33 and the second amplifier 34 are turned on (step S103).
[0101]
Then, it waits for a predetermined time (step S104).
Due to this standby, the time from when the first amplifier 33 and the second amplifier 34 are turned on until the detection of the VREF signal in step S106 described later and the time until the detection of the TP ′ signal in step S108 may be made longer. Thus, the first amplifier 33 and the second amplifier 34 can be made more stable. Therefore, the measurement accuracy of body temperature is further improved.
[0102]
Next, the Frh signal is detected (step S105).
In this step S105, as described above, the counter 314 counts the number of pulses of the input Frh signal, and the timer 313 takes time required for the counter 314 to count a predetermined number of pulses (for example, 256) ( Trh) is measured, and this Trh is stored in the memory 312.
[0103]
In addition, the selector switch 39 is switched to the temperature sensor 107 side in preparation for detection of an Fth signal in step S107 described later. Thereby, the relay circuit 41 and the temperature sensor 107 constitute an oscillation circuit.
[0104]
Next, the VREF signal is detected (step S106).
In step S106, as described above, the VREF signal from the first amplifier 33 is input to the comparator 37, and the time from when the STC signal is transmitted to when the EOC signal is received by the timer 313 (Tvref) And Tvref is stored in the memory 312.
[0105]
In addition, the selector switch 35 is switched to the TP ′ signal side in preparation for the detection of the TP ′ signal in step S108 described later.
[0106]
Next, detection of the Fth signal (detection of a signal from the temperature sensor 107) is performed (step S107).
[0107]
In step S107, as described above, the counter 314 counts the number of pulses of the input Fth signal, and the timer 313 counts the time required for the counter 314 to count a predetermined number of pulses (for example, 256) ( Tth) is measured, and this Tth is stored in the memory 312.
[0108]
In addition, the selector switch 39 is switched to the reference resistor 41 side in preparation for the detection of the Frh signal in step S105 in the next body temperature measurement. As a result, the relay circuit 41 and the reference resistor 41 constitute an oscillation circuit.
[0109]
Next, detection of the TP ′ signal (detection of the signal from the infrared sensor 101) is performed (step S108).
[0110]
In step S108, as described above, the TP ′ signal is input to the comparator 37, and the timer 313 measures the time (Ttp) from when the STC signal is transmitted to when the EOC signal is received. Ttp is stored in the memory 312.
[0111]
In addition, the selector switch 35 is switched to the VREF signal side in preparation for the detection of the VREF signal in step S106 in the next body temperature measurement.
[0112]
Next, the first amplifier 33 and the second amplifier 34 are turned off (step S109).
[0113]
Next, a temperature calculation is performed to obtain the temperature of the measurement site (heat source), that is, the body temperature (step S110).
[0114]
In this step S110, as described above, Ttp, Tvref, Tth and Trh are read from the memory 312, and Ttp / Tvref and Tth / Trh are obtained, respectively. By substituting it into a predetermined relational expression, the temperature of the measurement site (heat source), that is, the body temperature is obtained.
[0115]
In addition, in this step S110, you may comprise so that predetermined | prescribed temperature correction may be performed with respect to the calculated | required body temperature.
[0116]
Subsequently, the body temperature calculated | required by step S110 is displayed on the display part 5 (step S111).
[0117]
After step S111, the process returns to step S101, and step S101 and subsequent steps are executed again.
[0118]
In addition, you may comprise so that the buzzer 33 may be sounded in order to alert | report the completion | finish of a measurement between the said step S110 and step S111 or after step S111. In this case, the operator can know that the measurement of the body temperature has ended by notifying the buzzer 33. The operator pulls out the probe 6 from the ear cavity by the notification of the buzzer 33.
[0119]
Further, the waiting in step S102 may be omitted.
Further, the waiting in step S104 may be omitted.
[0120]
As described above, according to the thermometer 1, the influence of the thermal time constant of the TP ′ signal can be reduced without increasing the measurement time of the body temperature, and thus more stable body temperature measurement is performed. be able to.
[0121]
As mentioned above, although the thermometer of this invention was demonstrated based on the Example shown to an accompanying drawing, this invention is not limited to this, The structure of each part is substituted by the thing of the arbitrary structures which have the same function. be able to.
[0122]
For example, although the said Example is an ear-type thermometer, if this invention detects the intensity | strength of the infrared rays emitted from a measurement site | part and is a thermometer which measures body temperature, it is not limited to an ear-type thermometer.
The present invention can also be applied to a general thermometer that is not a thermometer.
[0123]
【The invention's effect】
As described above, according to the infrared thermometer of the present invention, after detecting the signal from the temperature sensor when measuring the body temperature, the signal from the infrared sensor is detected, so the measurement time of the body temperature is shortened, The influence of the thermal time constant of the signal from the infrared sensor can be reduced, so that more stable body temperature measurement can be performed.
[Brief description of the drawings]
FIG. 1 is a front view of a thermometer according to the present invention.
FIG. 2 is a side view of the thermometer of the present invention.
FIG. 3 is a cross-sectional view taken along line AA in FIG. 1 showing a state in which the probe cover is attached to the probe in the thermometer of the present invention.
FIG. 4 is a cross-sectional side view schematically showing the internal structure of the thermometer of the present invention.
FIG. 5 is a perspective view showing a configuration example of a temperature detector in the thermometer of the present invention.
FIG. 6 is a block diagram showing a circuit configuration example of the thermometer of the present invention.
FIG. 7 is a timing chart showing a reference signal and a TP ′ signal or a VREF signal in the present invention.
FIG. 8 is a timing chart showing an Fth signal or an Frh signal in the present invention.
FIG. 9 is a graph showing the relationship between the elapsed time from when the thermometer is worn on the ear and the level (voltage) of the TP ′ signal (thermal response characteristic of the TP ′ signal).
FIG. 10 is a graph showing the VREF signal side and the TP ′ signal when the changeover switch is switched from the VREF signal side to the TP ′ signal side.
FIG. 11 is a flowchart showing the control operation of the control means when measuring body temperature (in the order of Frh signal detection, VREF signal detection, Fth signal detection, and TP ′ signal detection).
[Explanation of symbols]
1 Thermometer
2 Thermometer body
21 Casing
3 Power switch
4 Measurement switch
5 display section
6 Probe
61 Base
62 Male Screw
63 Tip outer periphery
64 Inclined part
7 Support stand
71 Large diameter part
72 Small diameter part
73, 74 Male screw
8 Light guide
81 Protective sheet
9 Ring nut
91 female screw
92 Tapered part
93 engaging part
94 Tip
95 groove
10 Temperature detector
101 Infrared sensor
102 Thermopile (thermocouple array)
103 Hot junction
104 Cold junction
105 Thermal insulation band
106 Heat collector
107 temperature sensor
11 Probe cover
12 Torso
14 Membrane
15 Lip part
30 Circuit board
31 Control means
311 Calculation unit
312 memory
313 timer
314 counter
32 Amplification means
33 First amplifier
34 Second amplifier
35 selector switch
36 Integration circuit
37 comparator
38 Reference resistance
39 changeover switch
40 Power supply
41 Relay circuit
42 Buzzer
S101 to S111 steps

Claims (5)

A temperature sensor for detecting an environmental temperature; and an infrared sensor for detecting the intensity of infrared rays emitted from a measurement site, the thermal response of which is worse than that of the temperature sensor, and the level or time length of a signal from the temperature sensor In an infrared thermometer that measures body temperature based on the level of the signal from the infrared sensor,
The thermal response of the infrared sensor starts when the infrared thermometer is attached,
An infrared thermometer configured to detect the level of a signal from the infrared sensor after detecting the level or time length of the signal from the temperature sensor. A temperature sensor that detects environmental temperature, an infrared sensor that detects the intensity of infrared rays emitted from the measurement site, and a temperature detection standardization signal that normalizes the signal from the temperature sensor. Temperature detection standardized signal generating means for generating the infrared detection standardized signal generating means for generating an infrared detection standardized signal for normalizing the signal from the infrared sensor, and the level of the signal from the temperature sensor Alternatively, in an infrared thermometer that measures body temperature based on the time length, the level of the signal from the infrared sensor, the level or time length of the temperature detection standardized signal, and the level of the infrared detection standardized signal,
The thermal response of the infrared sensor starts when the infrared thermometer is attached,
An infrared thermometer configured to detect the level of a signal from the infrared sensor after detecting the level or time length of the signal from the temperature sensor.   Detection of the level or temporal length of the signal from the temperature sensor, detection of the level of the signal from the infrared sensor, detection of the level or temporal length of the temperature detection normalized signal, and detection of the infrared detection normalized signal The infrared thermometer according to claim 2, wherein the detection of the level of the signal from the infrared sensor is performed last in the detection of the level.   The level or time length of the signal from the temperature sensor is detected between detection of the level of the infrared detection standardized signal and detection of the level of the signal from the infrared sensor. Item 4. The infrared thermometer according to Item 2 or 3.   The infrared thermometer according to any one of claims 2 to 4, wherein the infrared thermometer is configured to detect the level of the infrared detection standardized signal after detecting the level or time length of the temperature detection standardized signal.

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