JP6951805B1 - thermometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique capable of using a non-contact thermometer in an appropriate state under any environment, having excellent convenience for a user, and capable of performing temperature measurement with high accuracy. .. SOLUTION: An infrared sensor 31 that detects infrared rays from a measurement object, a measuring unit 51 that obtains the temperature of the measurement object based on the amount of infrared rays detected by the infrared sensor 31, the infrared sensor 31 and the measurement. A thermometer 1 includes a determination unit 52 that determines whether or not the unit 51 is in a temperature measurable state, and a notification unit 53 that vibrates to notify that the determination unit 52 has determined that the temperature can be measured. To configure. [Selection diagram] Fig. 3

Description

The present invention relates to a thermometer that measures temperature.

In recent years, the importance of non-contact thermometers has increased significantly from the viewpoint of preventing virus infection. As a non-contact type thermometer, one that measures body temperature without contact with the human body by using infrared rays is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-146748

A non-contact thermometer needs to be used in an appropriate state for accurate temperature measurement, for example, to maintain an appropriate distance between the human body to be measured and the thermometer. be. However, conventional non-contact thermometers are not always very convenient for users when used in an appropriate state.

The non-contact type thermometer is frequently used even in a noisy environment in recent years. In such a case, for example, a sound output such as a buzzer is used to notify the state of the thermometer. However, the sound output may not be heard, and as a result, it may be inconvenient for the user. In addition, non-contact thermometers are expected to be used at night in hospitals, long-term care facilities, etc., but notification using sound output may interfere with the sleep of the person being measured, and this is also used. It may be inconvenient for the person. Furthermore, when used at night, it may be difficult to visually recognize the display output even if the notification uses the display output on the liquid crystal screen of the thermometer, which may be inconvenient for the user. There is.

The present invention provides a technology that enables a non-contact thermometer to be used in an appropriate state in any environment, is highly convenient for the user, and can perform temperature measurement with high accuracy. The purpose is to do.

One aspect of the present invention has been devised to achieve the above object.
An infrared sensor that detects infrared rays from the object to be measured and
A measuring unit that obtains the temperature of the measurement target based on the amount of infrared rays detected by the infrared sensor, and
A determination unit for determining whether or not the infrared sensor and the measurement unit are in a temperature measurable state, and a determination unit.
A notification unit that vibrates to notify that the determination unit has determined that the temperature can be measured.
It is a thermometer equipped with.

According to the present invention, since the non-contact thermometer can be used in an appropriate state under any environment, it is convenient for the user and the temperature is measured with high accuracy. be able to.

It is a perspective view which shows the appearance composition example of the thermometer which concerns on one Embodiment of this invention. It is an exploded perspective view which shows the internal structure example of the thermometer which concerns on one Embodiment of this invention. It is a block diagram which shows the functional structure example of the thermometer which concerns on one Embodiment of this invention. It is a flowchart which shows a specific example of the procedure of the processing operation by the body temperature measurement function by the thermometer which concerns on one Embodiment of this invention. It is a flowchart which shows a specific example of the procedure of the processing operation by the object measurement function in the thermometer which concerns on one Embodiment of this invention. It is a flowchart which shows a specific example of the procedure of the processing operation by the air temperature measurement function in the thermometer which concerns on one Embodiment of this invention. It is explanatory drawing which shows one specific example of the vibration mode of the thermometer which concerns on one Embodiment of this invention.

Hereinafter, the thermometer according to the present invention will be described with reference to the drawings.

<1. Configuration example of thermometer>
The thermometer described by giving an example in the present embodiment is configured to measure the temperature of a measurement target body including the body temperature of the human body in a non-contact manner by using infrared rays. More specifically, it is configured to use infrared rays from the forehead of the human body for measuring the body temperature of the human body to be measured. Hereinafter, a configuration example of the thermometer will be described.

(Case configuration)
FIG. 1 is a perspective view showing an example of an external configuration of a thermometer according to the present embodiment.
The thermometer 1 of the present embodiment includes a rod-shaped (stick-shaped) thermometer housing 10 formed so that the user (that is, the person performing the measurement) can grasp the thermometer 1.

An opening for introducing infrared rays (hereinafter referred to as “infrared ray introducing opening”) 11 is provided at one end of the thermometer housing 10. Further, on one surface of the thermometer housing 10, a screen display unit 12 for displaying and outputting information, and a measurement switch 13 and a mode switch 14 for the measurement actor to operate are arranged. The screen display unit 12 is composed of, for example, an LCD (liquid crystal display) panel. Further, the measurement switch 13 and the mode switch 14 are composed of, for example, a push button switch.

An opening / closing lid (not shown) that can be opened / closed is arranged on the other surface of the thermometer housing 10, and a dry battery (also not shown) as a power source is used in the thermometer housing with the opening / closing lid open. It can be worn inside the body 10.

FIG. 2 is an exploded perspective view showing an example of the internal configuration of the thermometer according to the present embodiment.
Inside the thermometer housing 10, a space capable of accommodating various parts is provided. The components mounted in the internal space of the thermometer housing 10 include, at least, a sensor board 21, a main board 22, and an actuator unit 40, in addition to a dry battery as a power source.

(Board configuration)
The sensor board 21 is a printed circuit board (PCB) on which an infrared sensor 31, a temperature sensor 32, and a distance sensor 33 are mounted. The details of the infrared sensor 31, the temperature sensor 32, and the distance sensor 33 will be described later.

The main board 22 is at least a printed circuit board (PCB) on which a control unit 50 configured by a CPU (central processing unit) or the like is mounted. The details of the control unit 50 will be described later. Further, on the main board 22, in addition to the control unit 50, a screen display unit 12 such as an LCD panel, a measurement switch 13 such as a push button switch, a mode switch 14, and the like are mounted. Further, the communication module 60 may be mounted on the main board 22. The details of the communication module 60 will be described later.

It is preferable that the sensor substrate 21 and the main substrate 22 are respectively configured as separate substrates. If each is a separate board, even if the main board 22 is equipped with electronic components that generate heat (for example, the control unit 50 and the communication module 60), the influence of the heat generation affects the sensor board 21. This is because it can suppress. Even if the boards are separate, they are electrically connected to each other via conductive cable members (but not shown) such as FPC (flexible printed circuits) or FFC (flexible flat cable). do.

(Sensor configuration)
As described above, the infrared sensor 31, the temperature sensor 32, and the distance sensor 33 are mounted on the sensor substrate 21.

The infrared sensor 31 detects infrared rays incident on the sensor package 30. More specifically, the infrared sensor 31 is made of, for example, a thermopile chip, and is configured to generate thermoelectromotive force according to the amount of incident energy of infrared rays received through the filter. The infrared sensor 31 may be provided with a wavelength selection filter that selectively transmits infrared rays having a predetermined wavelength.

The temperature sensor 32 detects the air temperature (ambient temperature) of the environment in which the infrared sensor 31 is placed. More specifically, the temperature sensor 32 is arranged in the vicinity of the infrared sensor 31 and is configured to output a voltage corresponding to the temperature of the arranged portion. The infrared sensor 31 is compensated for cold contact during temperature measurement. It makes it feasible to correct the temperature dependence of. As the temperature sensor 32, for example, a thermistor attached to the infrared sensor 31 constituting the sensor package may be used, but from the viewpoint of followability to temperature changes, the temperature sensor 32 is provided separately from the infrared sensor 31. Is preferably used. The temperature detection method is not particularly limited, and known methods can be used.

The distance sensor 33 detects the distance from the forehead of the human body to be measured. More specifically, the distance sensor 33 is composed of, for example, an infrared distance measuring sensor module, has a light emitting element that emits infrared rays and a light receiving element that receives reflected light, and uses the principle of triangular surveying to measure an object (measurement target body ( Specifically, it is configured to measure the distance to the subject's forehead).

Each of these sensors 31, 32, 33 is arranged on the sensor substrate 21 as described below. That is, on the sensor substrate 21, the temperature sensor 32 is arranged in the vicinity of the infrared sensor 31, and the infrared sensor 31 and the distance sensor 33 are arranged side by side. Then, in the sensor substrate 21, the infrared sensor 31 can receive infrared rays from the outside through the infrared introduction opening 11 of the thermometer housing 10, and the distance sensor 33 emits infrared rays and receives the reflected light thereof. It is arranged in the vicinity of the infrared ray introduction opening 11 in the thermometer housing 10 so as to be able to do so.

(Actuator part)
The actuator unit 40 mounted in the internal space of the thermometer housing 10 converts an electric signal from the control unit 50 of the main board 22 into a physical motion called vibration, and the entire thermometer housing 10 is converted by the physical motion. It is configured to transmit vibrations to. The vibration generation method is not particularly limited, and is known, for example, a linear resonance actuator method that produces linear vibration, an eccentric rotational mass method that produces circular motion, a piezo actuator method that uses a piezo element, and the like. It is possible to use. Further, the actuator unit 40 is not limited in its arrangement as long as it can transmit vibration to the entire thermometer housing 10, and may be mounted on, for example, the main board 22.

(Control unit)
FIG. 3 is a block diagram showing a functional configuration example of the thermometer according to the present embodiment.
The control unit 50 mounted on the main board 22 controls the processing operation of the thermometer 1. Therefore, the control unit 50 is electrically connected to the infrared sensor 31, the temperature sensor 32, and the distance sensor 33, and is configured to receive the electric signal which is the detection result from each of the sensors 31, 32, and 33. ing. Further, the control unit 50 is electrically connected to the measurement switch 13 and the mode switch 14, and is configured to receive an electric signal about the operating state from each of the switches 13 and 14. Further, the control unit 50 is electrically connected to the screen display unit 12, and is configured to output an electric signal instructing the content of the information display output to the screen display unit 12. Further, the control unit 50 is electrically connected to, for example, a sound output unit 16 such as a buzzer or a speaker, and is configured to output an electric signal instructing the content of the sound output to the sound output unit 16. ing. Further, the control unit 50 is electrically connected to the actuator unit 40, and is configured to output an electric signal instructing the operation content (a mode of vibration) to the actuator unit 40.

The control unit 50 controls the processing operation in the thermometer 1 by executing a preset control program. More specifically, the control unit 50 performs control processing necessary for temperature measurement by the thermometer 1, but by executing the control program, it functions as at least the measurement unit 51, the determination unit 52, and the notification unit 53. It is configured in.

(Measurement unit)
The measuring unit 51 is a function of performing a control process for obtaining the temperature of the object to be measured. The control process performed by the measurement unit 51 includes at least a mode selection process and an arithmetic process.

The mode selection process is a process for the thermometer 1 to select the corresponding operation mode. That is, the measuring unit 51 is configured to select one of the body temperature mode, the object mode, and the room temperature mode in the mode selection process.
The body temperature mode is an operation mode for measuring the body temperature of the human body to be measured.
The object mode is an operation mode for measuring the temperature of an object to be measured.
The room temperature mode is an operation mode for measuring the room temperature (ambient temperature).
The details of the mode selection process (procedure for switching each mode, etc.) will be described later.

The calculation process is a process of performing calculations necessary for obtaining a temperature measurement result based on the detection results of the infrared sensor 31 and the temperature sensor 32. That is, the measuring unit 51 is configured to perform a predetermined calculation on the received electric signal based on the electric signals from the infrared sensor 31 and the temperature sensor 32 in the arithmetic processing to obtain the temperature of the object to be measured. ing. The arithmetic processing performed by the measuring unit 51 includes at least a first correction process, a second correction process, and a third correction process.
The first correction process is an arithmetic process for converting the amount of incident energy of infrared rays detected by the infrared sensor 31 (hereinafter, simply referred to as “infrared ray amount”) into a temperature value. It is assumed that this first correction process is performed according to a predetermined relational expression defined based on, for example, the Stefan-Boltzmann Law.
The second correction process is an arithmetic process for correcting the temperature dependence of the infrared sensor 31 based on the detection result of the temperature sensor 32.
The third correction process derives the intracerebral temperature of the human body from the temperature value obtained as the temperature of the forehead of the human body to be measured based on the preset relationship data between the forehead temperature and the intracerebral temperature. It is an arithmetic process. It is assumed that the relational data required for the third correction process is specified in advance through simulations, tests, and the like, and is stored in a storage area that can be read by the control unit 50.
The specific contents of these arithmetic processes will be described in detail later.

(Judgment department)
The determination unit 52 is a function of determining whether or not the infrared sensor 31, the temperature sensor 32, and the measurement unit 51 are in a state in which temperature measurement can be performed (hereinafter, simply referred to as “temperature measurable state”). .. For example, the determination unit 52 is configured to determine that the temperature can be measured and measured when the detection result of the distance sensor 33 is within a predetermined distance range. Further, for example, the determination unit 52 is configured to determine that the temperature can be measured when the detection result of the temperature sensor 32 is within a predetermined temperature range. The specific content of the process for determining whether or not the temperature can be measured will be described in detail later.

(Notification unit)
The notification unit 53 is a function for notifying the user of the state of the thermometer 1. The state of the thermometer 1 includes the above-mentioned temperature measurable state. The notification unit 53 notifies the state of the thermometer 1 by issuing at least one of an information display output instruction to the screen display unit 12, a sound output instruction to the sound output unit 16, and an operation instruction to the actuator unit 40. It is configured. That is, the notification unit 53 is configured to be able to perform notification by vibration of the actuator unit 40, and means other than vibration (that is, display output by the screen display unit 12 or sound output by the sound output unit 16). It is configured so that it can also be notified by. The specific contents of the notification process will be described in detail later.

(Communication module)
The communication module 60 mounted on the main board 22 communicates with an external device. Examples of external devices include personal computer devices and portable information terminal devices such as smartphones and tablets. The communication module 60 is configured to perform short-range wireless communication with an external device, for example, in accordance with Bluetooth (registered trademark). The communication module 60 is not an indispensable configuration and may not be provided in the thermometer 1.

<2. Example of processing operation in thermometer>
Next, an example of processing operation in the thermometer 1 having the above-described configuration will be described.
The processing operation in the thermometer 1 includes at least a preparatory operation and a measurement operation.

(Preparatory operation)
When using the thermometer 1, after the power is turned on, ON / OFF of the vibration notification by the actuator unit 40 is set. For example, when there is a long press operation of the measurement switch 13, the notification unit 53 assumes that the vibration notification is set to ON. At this time, the notification unit 53 may give an operation instruction to the actuator unit 40 in response to a long press operation of the measurement switch 13, and notify the actuator unit 40 that the vibration notification is set to ON by the vibration of the actuator unit 40. .. Then, when the vibration notification is set to ON, after that, the notification unit 53 notifies the state of the thermometer 1 by the vibration of the actuator unit 40. In the following description, the case where the vibration notification is set to ON will be taken as an example.

Further, when using the communication with the external device by the communication module 60, the connection ID required for the communication is registered by using the dedicated application in the external device. As a result, when communication with the external device is established, the measurement result by the thermometer 1 can be output by the external device. Further, by storing and storing the measurement result in an external device, it is possible to manage the measurement result.

(Measurement operation)
After the completion of the preparatory operation, the control unit 50 sets the state of the thermometer 1 into a measurement standby state in which the temperature measurement using the thermometer 1 can be started. In the measurement standby state, the thermometer 1 can select the corresponding operation mode.

For example, when the power supply of the thermometer 1 is turned on, it is assumed that the measuring unit 51 is set to select the body temperature mode as the operation mode. Then, when the mode switch 14 is pressed and held in the measurement standby state, the measurement unit 51 performs the mode selection process in the following procedure. That is, if the set operation mode is the body temperature mode, the measurement unit 51 switches the selection of the operation mode from the body temperature mode to the object mode, and returns to the measurement standby state. If the set operation mode is the object mode, the operation mode selection is switched from the object mode to the room temperature mode, and the state returns to the measurement standby state. If the set operation mode is the room temperature mode, the operation mode selection is switched from the room temperature mode to the body temperature mode, and the state returns to the measurement standby state.

That is, the measurement unit 51 switches the selection of the set operation mode each time the mode switch 14 is operated in the measurement standby state. As a result, the measuring actor who operates the thermometer 1 can switch the operation mode of the thermometer 1 to either the body temperature mode, the object mode, or the room temperature mode by operating the mode switch 14. When the operation mode is set, the notification unit 53 causes the screen display unit 12 to display and output which operation mode it is in a visually recognizable manner.

If there is a short press operation of the measurement switch 13 in the measurement standby state after the operation mode is set, the measurement unit 51 starts the temperature measurement processing operation according to the operation mode. For example, when the body temperature mode is set, the measuring unit 51 starts the processing operation by the body temperature measuring function. If the object mode is set, the measurement unit 51 starts the processing operation by the object measurement function. If the room temperature mode is set, the measuring unit 51 starts the processing operation by the air temperature measuring function. Hereinafter, the procedures for these processing operations will be described in order.

(Processing by body temperature measurement function)
The processing operation by the body temperature measuring function is a processing operation performed to measure the body temperature of the human body (that is, the person to be measured) to be measured in the body temperature mode.
FIG. 4 is a flowchart showing a specific example of the procedure of the processing operation by the body temperature measuring function in the thermometer according to the present embodiment.

When the operation mode of the thermometer 1 is set to the body temperature mode and there is a short press operation of the measurement switch 13 (step 101, hereinafter the step is abbreviated as "S"), the notification unit 53 is sent to the actuator unit 40. An operation instruction is given, and the vibration of the actuator unit 40 notifies that the processing operation by the body temperature measurement function is started (S102). The vibration mode of the actuator unit 40 at this time will be described in detail later.

When the processing operation by the body temperature measurement function is started, the determination unit 52 first receives an electric signal from the temperature sensor 32 and reads the voltage value of the electric signal to measure the temperature of the environment in which the thermometer 1 is placed. Measure (S103). Then, the determination unit 52 determines whether or not the temperature measurement result is an appropriate temperature within a predetermined temperature range (S104). Specifically, if the temperature measurement result is within the preset allowable lower limit temperature (for example, 5 ° C) and the allowable upper limit temperature (for example, 40 ° C), it is judged that the temperature is appropriate, and otherwise. If so, it is judged that the temperature is not appropriate. If the temperature is appropriate, the determination unit 52 determines that the thermometer 1 is in a temperature-measurable state with respect to the air temperature (ambient temperature). On the other hand, if it is determined that the temperature is not appropriate, the determination unit 52 cannot guarantee the normal operation of the thermometer 1, and therefore causes, for example, the screen display unit 12 to output an alarm to that effect (S105). This avoids the use of the thermometer 1 in an environment where normal operation cannot be guaranteed.

If the temperature is appropriate, the determination unit 52 subsequently causes the distance sensor 33 to start measuring the distance (S106) and starts monitoring the detection result. When the distance sensor 33 starts the distance measurement, the measuring actor, for example, opens the infrared introduction opening 11 of the thermometer housing 10 of the person to be measured (the person may be the same person as the measuring person or a different person). Gradually bring the thermometer 1 closer to the forehead while facing the forehead. Then, the determination unit 52 monitors the detection result of the distance sensor 33 regarding the distance between the forehead of the person to be measured and the thermometer 1, and determines whether or not the detection result is within a predetermined distance range. (S107). Specifically, when the distance detection result by the distance sensor 33 becomes equal to or less than a preset distance upper limit value (for example, 5 cm) while the thermometer 1 is gradually approaching the forehead, the detection result is predetermined. Judge that it is within the distance range. Further, if the thermometer 1 is brought too close to the forehead and the distance detection result by the distance sensor 33 becomes less than the preset lower limit of the distance (for example, 2 cm), the distance is out of the predetermined distance range. It is judged that the result is not within the predetermined distance range. That is, the determination unit 52 determines whether or not the detection result by the distance sensor 33 is within the predetermined distance range, and if it is within the predetermined distance range, the thermometer 1 is located at an appropriate distance for measuring the body temperature. , It is determined that the thermometer 1 is in a state where the temperature can be measured with respect to the distance. If the detection result by the distance sensor 33 does not fall within the predetermined distance range even after a predetermined time has elapsed from the start of the distance measurement, the determination unit 52 sets a time-out (S108) and turns off the power of the thermometer 1. conduct.

As described above, when the detection result of the distance sensor 33 is within the predetermined distance range and the detection result of the temperature sensor 32 is within the predetermined temperature range, the thermometer 1 can measure the temperature. Judge that. Here, an example is given in which it is determined that the temperature can be measured when both the temperature and the distance are satisfied, but the condition is not necessarily limited to this, and one of the conditions is used. It may be determined that the temperature can be measured when the above conditions are satisfied, or it may be determined that the temperature can be measured based on completely different conditions.

When the determination unit 52 determines that the temperature can be measured (S107), the notification unit 53 gives an operation instruction to the actuator unit 40, and the actuator unit 40 indicates that the thermometer 1 is in the temperature measurable state. It is notified by the vibration of (S109). As a result, the person performing the measurement is in a temperature environment in which the thermometer 1 is in a temperature measurable state (for example, the thermometer 1 is located at an appropriate distance for measuring the body temperature, and normal operation is guaranteed. That) can be recognized by the vibration transmitted to the hand holding the thermometer 1 without relying on sight, hearing, or the like. The details of the vibration mode of the actuator unit 40 at this time will be described later.

If the communication module 60 is provided, the communication module 60 establishes communication with an external device according to the determination by the determination unit 52 that the temperature can be measured. As a result, the notification unit 53 causes the screen display unit 12 to display and output a predetermined communication mark (for example, the Bluetooth (registered trademark) mark), thereby notifying that communication with an external device is possible.

When the thermometer 1 is in a temperature measurable state, the measuring unit 51 receives an electric signal from the infrared sensor 31 at that time (S110). Further, the measuring unit 51 receives the electric signal from the temperature sensor 32 together with the electric signal from the infrared sensor 31.

In this way, the measuring unit 51 indicates that the detection result of the distance sensor 33 has changed from outside the predetermined distance range to within the predetermined distance range in the body temperature mode, and the temperature gauge 1 is in the temperature measurable state. And the start of acquisition of each detection result of the temperature sensor 32. Therefore, when the thermometer 1 is in a temperature measurable state, the detection result by the infrared sensor 31 or the like is automatically obtained (that is, without the operation by the measuring actor), so that the operability for the measuring actor is operability. Is improved, and it becomes very convenient for the person performing the measurement and the person to be measured. In addition, by using the state transition within the predetermined distance range as one of the triggers, for example, the thermometer 1 can be used in a form of gradually approaching the forehead when measuring the body temperature. It can be used with confidence even for elderly people. Here, as an example of the state transition to the predetermined distance range, the case of gradually approaching the forehead is given, but the case of gradually moving away from the position below the lower limit of the distance and becoming within the predetermined distance range is also mentioned. It is assumed to be included in the state transition referred to here.

Upon receiving the electric signals from the infrared sensor 31 and the temperature sensor 32, the measuring unit 51 performs arithmetic processing on the received electric signals. Specifically, the measurement unit 51 performs a first correction process (S111), a second correction process (S112), and a third correction process (S113) as arithmetic processing.

In the first correction process (S111), based on the voltage value of the electric signal from the infrared sensor 31, an arithmetic process for converting the amount of infrared rays incident on the infrared sensor 31 uniquely corresponding to the voltage value into a temperature value is performed. .. This first correction process may be performed according to a predetermined relational expression. Examples of the predetermined relational expression include the following equation (1) defined based on Stefan-Boltzmann's law. In equation (1), V is a voltage value [unit: mV] uniquely corresponding to the amount of infrared rays, T is a temperature value [unit: K], and σ is a proportional coefficient (Stefan-Boltzmann constant).

V = σT ⁴ ... (1)

In the second correction process (S112), the temperature of the environment in which the thermometer 1 is placed at the time when the detection result of the infrared sensor 31 is obtained is measured based on the voltage value of the electric signal from the temperature sensor 32. , The temperature value obtained based on the detection result of the infrared sensor 31 is subjected to arithmetic processing for correction in consideration of the measurement result of the air temperature. That is, in the second correction process (S112), an arithmetic process for correcting the temperature dependence of the infrared sensor 31 is performed based on the detection result of the temperature sensor 32. As a result, the influence of the air temperature on the detection result of the infrared sensor 31 can be eliminated, and the accuracy of the detection result of the infrared sensor 31 can be improved. Specifically, in order to correct the temperature dependence of the infrared sensor 31, the above equation (1) is converted as the following equation (2). In equation (2), Tb is the temperature value [unit: K] obtained based on the detection result of the infrared sensor 31, and Ts is the temperature value [unit: K] obtained based on the detection result of the temperature sensor 32. be.

V = σ (Tb ^4- Ts ⁴ ) ... (2)

In the third correction process (S113), the temperature value obtained through the first correction process (S111) and the second correction process (S112) is set as the temperature value for the forehead of the person to be measured and is set in advance. Based on the relationship data between the forehead temperature and the intracerebral temperature, the arithmetic processing for deriving the intracerebral temperature of the subject to be measured from the temperature value of the forehead of the subject is performed. In this way, the intracerebral temperature is derived from the forehead temperature because it is generally considered that the body temperature of the human body is equal to the intracerebral temperature, and the intracerebral temperature is expressed in the forehead by heat conduction. The related data required for the arithmetic processing at this time is about heat conduction from the brain to the forehead, and it is specified and measured in advance after analysis by heat conduction simulation and verification by clinical tests. It may be stored in a storage area that can be read by the unit 51. The data table and calculation method for the related data are not particularly limited as long as the brain temperature can be derived from the forehead temperature.

By performing the above arithmetic processing, the measuring unit 51 obtains the value of the temperature in the brain of the person to be measured as the measurement result of the body temperature of the person to be measured. Moreover, since the measurement result has undergone the distance monitoring (S107) by the distance sensor 33, the first correction process (S111), the second correction process (S112), and the third correction process (S113), it is extremely difficult. It will be highly accurate.

After obtaining the measurement result of the body temperature of the person to be measured, the measuring unit 51 determines whether or not the measurement result is within the appropriate temperature range (S114). Specifically, it is determined whether or not the measurement result of the body temperature is within the temperature range that can be assumed as the body temperature of the human body (for example, within the range of 32 ° C. to 42.5 ° C.). Then, if it is not within the appropriate temperature range, it is determined that the measurement is defective, and an alarm output to that effect is output to, for example, the screen display unit 12 (S115). As a result, the use of the thermometer 1 in a state where measurement failure has occurred is avoided.

If the measurement result is within the appropriate temperature range, the measuring unit 51 determines that the body temperature of the person to be measured has been measured normally. Then, the measurement unit 51 stores the temperature value of the measurement result as a measurement history in a readable storage area, for example, in association with related information such as the measurement date and time (S116). .. The measurement result can be stored, for example, for a maximum of 10 times. Further, the measuring unit 51 outputs the temperature value of the measurement result to the screen display unit 12 as the measurement result of the body temperature of the person to be measured, and causes the screen display unit 12 to display and output the temperature value (S117). If the mode switch 14 is operated when the past measurement result is stored, the display output content on the screen display unit 12 is switched, and each time the mode switch 14 is operated, the latest measurement result is old. It is assumed that the display is output retroactively to the measurement result.

When the screen display unit 12 outputs a display, the notification unit 53 gives an operation instruction to the actuator unit 40, and the screen display unit 12 displays and outputs the measurement result of the body temperature of the person to be measured by the vibration of the actuator unit 40. Notify (S118). As a result, the measuring actor can recognize that the measurement of the body temperature of the person to be measured is completed by the vibration transmitted to the hand holding the thermometer 1. Therefore, even when the detection by the infrared sensor 31 or the like is automatically started by using the distance sensor 33, the measuring actor can clearly grasp the completion of the measurement, so that the measuring actor can clearly grasp the completion of the measurement. Usability is improved. The details of the vibration mode of the actuator unit 40 at this time will be described later.

If the communication module 60 is provided, the communication module 60 transfers the latest one-time measurement result data to an external device in response to the completion of the measurement of the body temperature of the person to be measured. As a result, the measurement result by the thermometer 1 can be output by an external device and managed by the external device.

After that, the control unit 50 determines whether or not to end the processing operation by the series of body temperature measurement functions described above, depending on whether or not the measurement switch 13 is pressed and held by the measurement actor, for example (S119). If it does not end, it returns to the measurement standby state. On the other hand, when terminating, the power of the thermometer 1 is turned off (S120), and the processing operation by the series of body temperature measuring functions is terminated. Even if there is no operation by the measurement actor, if the measurement standby state continues for a predetermined time (for example, about 1 minute) or more after the measurement is completed, the control unit 50 automatically turns off the power of the thermometer 1.

(Processing operation by object measurement function)
Next, the processing operation by the object measurement function will be described. The processing operation by the object measurement function is a processing operation performed to measure the temperature of the object to be measured in the object mode.
FIG. 5 is a flowchart showing a specific example of the procedure of the processing operation by the object measurement function of the thermometer according to the present embodiment.

A state in which the operation mode of the thermometer 1 is set to the object mode, the thermometer 1 is aimed at the object to be measured, and is located within a predetermined distance range (for example, within a range of 2 cm to 5 cm) from the object. Then, when there is a short press operation of the measurement switch 13 (S201), the notification unit 53 gives an operation instruction to the actuator unit 40 and notifies the actuator unit 40 that the processing operation by the object measurement function is started by the vibration of the actuator unit 40 (S201). S202). The vibration mode of the actuator unit 40 at this time will be described in detail later.
If the communication module 60 is provided, the communication module 60 establishes communication with an external device. As a result, the notification unit 53 causes the screen display unit 12 to display and output a predetermined communication mark (for example, the Bluetooth (registered trademark) mark), thereby notifying that communication with an external device is possible.

When the processing operation by the object measurement function is started, the determination unit 52 first measures the air temperature of the environment in which the thermometer 1 is placed based on the electric signal from the temperature sensor 32 (S203), and the measurement result of the air temperature is obtained. It is determined whether or not the temperature is appropriate (S204). Then, when it is determined that the temperature is not appropriate, the determination unit 52 causes, for example, the screen display unit 12 to output an alarm to that effect (S205). Up to this point, it is the same as the case of the processing operation by the body temperature measurement function described above.

If the temperature is appropriate, at that time, the measuring unit 51 receives the electric signal from the infrared sensor 31 (S206), and also receives the electric signal from the temperature sensor 32. Also at this time, the measuring actor is in a state where the infrared introduction opening 11 of the thermometer housing 10 is directed toward the object to be measured, and the thermometer 1 is within a predetermined distance range (for example, within a range of 2 cm to 5 cm) from the object. Is positioned.

As described above, in the processing operation by the object measurement function, unlike the case of the processing operation by the body temperature measurement function described above, each detection result of the infrared sensor 31 and the temperature sensor 32 is not based on the detection result by the distance sensor 33. To get. This is because when the measurement target is an object, the object does not move during the measurement, and it is considered very easy to maintain the state in which the thermometer 1 is located within an appropriate distance range. Furthermore, since the reflectance of infrared rays differs depending on the surface color of the object to be measured, there is a possibility that erroneous detection may occur in the distance sensor 33, and this is to eliminate the influence of the influence on the temperature measurement result. be.

Upon receiving the electric signals from the infrared sensor 31 and the temperature sensor 32, the measuring unit 51 performs arithmetic processing on the received electric signals. Specifically, the measuring unit 51 performs a first correction process (S207) and a second correction process (S208) as arithmetic processing.

In the first correction process (S207), the voltage value is based on the voltage value of the electric signal from the infrared sensor 31 as in the first correction process (S111) in the case of the processing operation by the body temperature measurement function described above. A calculation process is performed to convert the amount of infrared rays incident on the infrared sensor 31 uniquely corresponding to the above into a temperature value.

Further, in the second correction process (S208), the temperature depends on the infrared sensor 31 based on the detection result of the temperature sensor 32, as in the second correction process (S112) in the case of the processing operation by the body temperature measurement function described above. Performs arithmetic processing to correct the sex.

However, unlike the case of the processing operation by the body temperature measurement function described above, the third correction processing (S113) is not performed. This is because in the processing operation by the object measurement function, the temperature value of the surface of the object to be measured is used as the measurement result of the temperature of the object. That is, instead of estimating the brain temperature (that is, body temperature) from the surface temperature of the forehead of the subject as in the case of the processing operation by the body temperature measurement function, in the processing operation by the object measurement function, the surface of the object. This is because the temperature value of can be used as the measurement result as it is.

By performing the above arithmetic processing, the measuring unit 51 obtains the value of the surface temperature of the object to be measured as the measurement result of the temperature of the object. Moreover, when the measurement result is obtained, the first correction process (S207) and the second correction process (S208) are performed, while the distance monitoring by the distance sensor 33 and the third correction process are unnecessary, so that the measurement is performed. While achieving high accuracy of the results, it will be possible to speed up the processing by reducing the load.

After obtaining the measurement result of the temperature of the object to be measured, the measuring unit 51 determines whether or not the measurement result is within the appropriate temperature range (S209). Specifically, it is determined whether or not the measurement result of the temperature of the object is within the temperature range that can be assumed as the temperature of the object (for example, within the range of 0 ° C. to 100 ° C.). Then, if it is not within the appropriate temperature range, it is determined that the measurement is defective, and an alarm output to that effect is output to, for example, the screen display unit 12 (S210). As a result, the use of the thermometer 1 in a state where measurement failure has occurred is avoided.

If the measurement result is within the appropriate temperature range, the measurement unit 51 determines that the temperature of the object to be measured has been measured normally. Then, the measurement unit 51 stores the temperature value of the measurement result as a measurement history in a readable storage area, for example, in association with related information such as the measurement date and time (S211). .. The measurement result can be stored, for example, for a maximum of 10 times. Further, the measuring unit 51 outputs the temperature value of the measurement result to the screen display unit 12 as the measurement result of the temperature of the object to be measured, and causes the screen display unit 12 to display and output the temperature value (S212). If the mode switch 14 is operated when the past measurement result is stored, the display output content on the screen display unit 12 is switched, and each time the mode switch 14 is operated, the latest measurement result is old. It is assumed that the display is output retroactively to the measurement result.

When the screen display unit 12 outputs a display, the notification unit 53 gives an operation instruction to the actuator unit 40, and the actuator unit 40 displays and outputs the measurement result of the temperature of the object to be measured on the screen display unit 12. Notify by vibration (S213). As a result, the measuring actor can recognize that the measurement of the temperature of the object is completed by the vibration transmitted to the hand holding the thermometer 1. The vibration mode of the actuator unit 40 at this time will be described in detail later.

If the communication module 60 is provided, the communication module 60 transfers the latest one-time measurement result data to an external device in response to the completion of the measurement of the temperature of the object to be measured. As a result, the measurement result by the thermometer 1 can be output by an external device and managed by the external device.

After that, the control unit 50 determines whether or not to end the processing operation by the series of object measurement functions described above, depending on whether or not the measurement switch 13 is pressed and held by the measurement actor, for example (S214). If it does not end, it returns to the measurement standby state. On the other hand, when terminating, the power of the thermometer 1 is turned off (S215), and the processing operation by the series of object measurement functions is terminated. Even if there is no operation by the measurement actor, if the measurement standby state continues for a predetermined time (for example, about 1 minute) or more after the measurement is completed, the control unit 50 automatically turns off the power of the thermometer 1.

(Processing operation by temperature measurement function)
Next, the processing operation by the air temperature measurement function will be described. The processing operation by the air temperature measurement function is a processing operation performed to measure the room temperature (ambient temperature) of the environment in which the thermometer 1 is placed in the room temperature mode.
FIG. 6 is a flowchart showing a specific example of the procedure of the processing operation by the air temperature measurement function in the thermometer according to the present embodiment.

When the operation mode of the thermometer 1 is set to the room temperature mode, the control unit 50 starts the processing operation by the air temperature measurement function. In the processing operation by the air temperature measurement function, first, the measurement unit 51 receives an electric signal from the temperature sensor 32 and reads the voltage value of the electric signal (S301). Then, the measuring unit 51 obtains a measurement result of the air temperature (that is, room temperature) of the environment in which the thermometer 1 is placed by converting the voltage value of the received electric signal into a temperature value (S302).

After obtaining the measurement result of the room temperature, the measuring unit 51 determines whether or not the measurement result is the appropriate temperature (S303), and if the measurement result is not the appropriate temperature, causes, for example, the screen display unit 12 to output an alarm to that effect. (S304).

If the temperature is appropriate, the measuring unit 51 determines that the room temperature has been measured normally. Then, the measuring unit 51 outputs the temperature value of the measurement result to the screen display unit 12 as the measurement result of the room temperature (that is, the ambient temperature of the thermometer 1), and causes the screen display unit 12 to display and output the temperature value (S305). ). As a result, the measurement result of the room temperature (ambient temperature) can be notified to the person performing the measurement using the thermometer 1.

After that, the control unit 50 determines whether or not to end the processing operation by the series of temperature measurement functions described above, depending on whether or not the measurement switch 13 is pressed and held by the measurement actor, for example (S306). If it does not end, it returns to the measurement standby state. On the other hand, when terminating, the power of the thermometer 1 is turned off (S307), and the processing operation by the series of air temperature measurement functions is terminated. Even if there is no operation by the measurement actor, if the measurement standby state continues for a predetermined time (for example, about 1 minute) or more after the measurement is completed, the control unit 50 automatically turns off the power of the thermometer 1.

(Vibration mode of actuator)
In the series of processing operations described above, the notification unit 53 notifies the state of the thermometer 1 by vibration of the actuator unit 40. The states of the thermometer 1 to be notified include, for example, (i) ON setting of vibration notification in the preparatory operation, (ii) Short press operation of the measurement switch 13 for starting measurement in body temperature mode or object mode (FIG. 4). S102, S202 in FIG. 5, (iii) Judgment that the temperature can be measured in the body temperature mode (S109 in FIG. 4), (iv) Output of the measurement result in the body temperature mode or the object mode (S118 in FIG. 4). , S213) in FIG. Further, in addition to these, the notification by the vibration of the actuator unit 40 may be performed according to at least one of (i)'when the thermometer 1 is turned on and when the subsequent operation mode selection is determined.

That is, in addition to the temperature measurable state of (iii) above, the notification unit 53 also notifies the predetermined states of (i), (i)', (ii), and (iv) by vibration of the actuator unit 40. Is supposed to do. When performing such vibration notification, the notification unit 53 is at least in the case where the temperature can be measured in the above (iii) and in the predetermined cases (i), (i)', (ii), and (iv). It is preferable to perform notification by vibration in a different mode depending on the case of the state. This is so that the measuring actor having the thermometer 1 can grasp the difference in the state of the thermometer 1.

Hereinafter, the vibration mode of the actuator unit 40 will be described with reference to specific examples.
FIG. 7 is an explanatory diagram showing a specific example of the vibration mode of the thermometer according to the present embodiment.

For example, in the cases (i), (i)', and (ii) above, it is sufficient if the measuring actor can grasp that the switch operation or the like has been accepted. Therefore, in the cases of (i), (i)', and (ii) above, the notification unit 53 causes the actuator unit 40 to perform a vibration operation that does not continue in a relatively short operation time. Specifically, the notification unit 53 gives an operation instruction to the actuator unit 40 so that, for example, an operation having a length of 200 milliseconds (mS) is performed only once. If the actuator unit 40 is operated in such a vibration mode, the actuator unit 40 is wasted more than necessary while making the measuring actor know that the states (i), (i)', and (ii) are present. It is possible to suppress such an operation.

Further, for example, in the case of (iii) above, it is necessary to have the measuring actor maintain the temperature measurable state. On the other hand, vibrations that interfere with the actions of the measuring actor or that the measuring actor feels annoying should be avoided. Therefore, in the case of (iii) above, the notification unit 53 performs a vibration operation on the actuator unit 40 in an intermittent manner in which vibration and stop are repeated, and in a mode in which the notification unit 53 continues while the temperature can be measured. Let me. Specifically, the notification unit 53 refers to the actuator unit 40 so as to continuously perform an intermittent operation of repeating ON at a length of 200 mS and OFF at a length of 100 mS while the temperature can be measured. And give an operation instruction. If the actuator unit 40 is operated in such a vibration mode, the measuring actor can be made aware of the state of (iii) depending on the presence or absence of the vibration operation, and the intermittent operation including the vibration stop period can be performed. It is possible to suppress the hindrance of the measurement actor's actions and the annoyance of the measurement actor.
When a time-out occurs in the temperature measurable state (S108 in FIG. 4), for example, an intermittent operation of ON for a length of 200 mS and OFF for a length of 100 mS is repeated four times, thereby indicating that the time-out occurs. Notification may be performed.

Further, for example, in the case of (iv) above, it is necessary to surely inform the measurement actor that the temperature measurement is completed and the measurement result is obtained. Therefore, in the case of the above (iv), the notification unit 53 causes the actuator unit 40 to perform a vibration operation in a mode that does not continue for a relatively long operation time and in a mode different from the case of the above (iii). Specifically, the actuator unit 40 is such that the notification unit 53 performs an operation having a length of 400 mS, which is longer than that of the above cases (i), (i)', and (ii), only once. Give an operation instruction to. If the actuator unit 40 is operated in such a vibration mode, the difference in mode from the case of (iii) above is clear (that is, continuous operation within a limited time rather than intermittent operation), and the above (that is, continuous operation within a limited time). Since the operation is performed for a longer time than in the cases of i), (i)', and (ii), it is possible to make the measuring actor surely grasp the state of the above (iv).

<3. Effect of this embodiment>
According to this embodiment, one or more of the following effects are achieved.

(A) In the present embodiment, when the determination unit 52 determines that the temperature can be measured, the notification unit 53 notifies the notification by vibration of the actuator unit 40. As a result, the measuring actor is in a state where the temperature can be measured (for example, the thermometer 1 is located at an appropriate distance for measuring the body temperature and is in a temperature environment where normal operation is guaranteed). It can be recognized by the vibration transmitted to the hand holding the thermometer 1 without relying on sight, hearing, or the like. Therefore, even when used in a noisy environment or at night, it is possible to guarantee the use of the thermometer 1 in an appropriate state, which enables accurate temperature measurement, and as a result, the user. It is very convenient for (both the person performing the measurement and the person being measured). That is, according to the present embodiment, the non-contact thermometer 1 can be used in an appropriate state under any environment, which is convenient for the user and highly accurate temperature measurement. You will be able to do it.

(B) In the present embodiment, the determination unit 52 determines that the temperature can be measured on the condition that the detection result of the distance sensor 33 is within a predetermined distance range. As a result, the non-contact type thermometer 1 is required to maintain an appropriate detection distance in order to perform temperature measurement with high accuracy, and the use of the thermometer 1 in an appropriate state for the detection distance is guaranteed. This is a very important matter for the non-contact thermometer 1. That is, according to the present embodiment, it is possible to guarantee the use in an appropriate state particularly with respect to the detection distance, which is very useful in configuring the non-contact thermometer 1.

(C) In the present embodiment, the determination unit 52 determines that the temperature can be measured on the condition that the detection result of the temperature sensor 32 is within a predetermined temperature range. As a result, when the non-contact type thermometer 1 is expected to be used in various environments, the use of the thermometer 1 in an appropriate state with respect to the temperature of the environment in which the thermometer 1 is placed is guaranteed. That is, according to the present embodiment, it is possible to guarantee the use in an appropriate state particularly with respect to the environmental temperature, which is very useful in constructing a non-contact thermometer 1 that can be used in various environments. ..

(D) In the present embodiment, in addition to the determination unit 52 determining that the temperature can be measured, the notification unit 53 also notifies that the thermometer 1 is in a predetermined state by the vibration of the actuator unit 40. It has become. Specifically, for example, not only the case of the above (iii) but also the states of the above (i), (i)', (ii), and (iv) are notified by the vibration of the actuator unit 40. As a result, the measuring actor can recognize that the thermometer 1 is in a predetermined state by the vibration transmitted to the hand holding the thermometer 1 without relying on sight, hearing, or the like. That is, according to the present embodiment, the measuring actor can accurately grasp the state of the thermometer 1 even when the thermometer is used in a noisy environment or at night, which is convenient for the user. It will be very useful in improving.

(E) In the present embodiment, at least, the case where the temperature can be measured in the above (iii) and the case where the above (i), (i)', (ii), and (iv) are in the predetermined state are notified. The unit 53 notifies by vibrations of different modes. As a result, the measuring actor having the thermometer 1 can grasp the difference in the state of the thermometer 1. In this respect as well, it is very useful in improving the convenience for the user.

(F) In the present embodiment, when the notification unit 53 notifies by the vibration of the actuator unit 40, the above cases (i), (i)', and (ii) do not continue in a relatively short operation time. The actuator unit 40 is made to perform the vibration operation of the embodiment. As a result, it is possible to prevent the actuator unit 40 from performing unnecessary unnecessary operations while making the measuring actor know that the states (i), (i)', and (ii) are present.

(G) In the present embodiment, when the notification unit 53 notifies by the vibration of the actuator unit 40, in the case of (iii) above, the vibration and the stop are repeated in an intermittent manner, and the temperature is measured. The actuator unit 40 is made to perform a vibration operation in a continuous mode while it is in a possible state. As a result, the measuring actor can be made aware of the state of (iii) above depending on the presence or absence of the vibration operation, and the intermittent operation including the vibration stop period hinders the measurement actor's action or the measurement action. It is possible to prevent a person from feeling annoyed.

(H) In the present embodiment, when the notification unit 53 notifies by the vibration of the actuator unit 40, in the case of the above (iv), the mode does not continue for a relatively long operation time, and the above (iii). The actuator unit 40 is made to perform a vibration operation in a mode different from that in the above case. As a result, the difference in the mode from the case of the above (iii) is clear, and it is possible to surely make the measuring actor grasp the state of the above (iv).

<4. Modification example>
Although the embodiments of the present invention have been specifically described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist thereof.

In the present embodiment, if the detection result of the distance sensor 33 is within the predetermined distance range and the detection result of the temperature sensor 32 is within the predetermined temperature range, the determination unit 52 determines that the temperature can be measured. However, the present invention is not limited to this. That is, the temperature measurable state may be either a state in which the detection result of the distance sensor 33 is within a predetermined distance range or a state in which the detection result of the temperature sensor 32 is within a predetermined temperature range. .. Further, even when completely other conditions are satisfied, if the infrared sensor 31, the temperature sensor 32, and the measuring unit 51 are in a state where the temperature can be measured, it is determined that the temperature can be measured. It doesn't matter.

In the present embodiment, the temperature value, the distance value, the vibration time value, etc. are explained with specific examples, but these numerical values are merely specific examples and are limited to specific values. is not it.

In the present embodiment, the case where the thermometer housing 10 has a rod shape (stick shape) has been given as an example, but the present invention is not limited to this, and measurement is performed in a non-contact manner using infrared rays. If there is, it can be applied even if it is formed in another shape.

1 ... Thermometer, 10 ... Thermometer housing, 21 ... Sensor board, 22 ... Main board, 31 ... Infrared sensor, 32 ... Temperature sensor, 33 ... Distance sensor, 40 ... Actuator section, 50 ... Control section, 51 ... Measuring section, 52 ... Judgment unit, 53 ... Notification unit, 60 ... Communication module

Claims (5)

A thermometer that measures the temperature of the body to be measured in a non-contact manner with the body to be measured.
An infrared sensor for detecting infrared rays from the human body of forehead is the measured object without contact,
A measuring unit that obtains the temperature of the measurement target based on the amount of infrared rays detected by the infrared sensor, and
A distance sensor that detects the distance to the forehead and
A temperature sensor that detects the temperature of the environment in which the infrared sensor is placed, and
When the detection result of the distance sensor is within a predetermined distance range and the detection result of the temperature sensor is within a predetermined temperature range, it is determined that the infrared sensor and the measuring unit are in a temperature measurable state. Judgment department and
A notification unit that vibrates to notify that the determination unit has determined that the temperature can be measured.
A thermometer equipped with. It is provided with an image display unit that outputs the temperature value obtained by the measuring unit.
The thermometer according to claim 1, wherein the notification unit notifies by vibration that the image display unit outputs the temperature value. The thermometer according to claim 2, wherein the notification unit notifies by vibration in a different mode depending on whether the temperature is measurable or the image display unit outputs the temperature value. According to claim 3, the notification unit performs a vibration operation in an intermittent manner in which vibration and stop are repeated in the temperature measurable state, and in a continuous manner while the temperature measurable state is reached. The listed thermometer. The thermometer according to claim 3 or 4, wherein the notification unit performs a vibration operation for a predetermined time only once when the image display unit outputs the temperature value.

Images