JP2022093972A - Body temperature measurement device and body temperature management system - Google Patents

Abstract

To simply and accurately measure a body temperature.SOLUTION: A body temperature measurement device 1 comprises: a face shield 2 which is attached to a user P1 to cover the face of the user P1 and provided with a first collimation part 5 of a sight line; an infrared sensor 9 attached to the face shield 2; and a second collimation part 7 attached to the face shield 2 and disposed in front of the first collimation part 5 in a sight line direction L1 of the user P1. The infrared sensor 9 is provided so as to detect infrared energy from a measured person located in the sight line direction L1 of the user P1 regulated by the first and second collimation parts 5 and 7.SELECTED DRAWING: Figure 2

Description

The present invention relates to a body temperature measuring device for measuring body temperature and a body temperature management system for managing body temperature measured by the body temperature measuring device.

Conventionally, a device for measuring body temperature in a non-contact manner in a facility such as a hospital is known (see, for example, Patent Document 1). The device of Patent Document 1 detects infrared rays emitted from a person to be measured by a device having an infrared sensor installed in the vicinity of the person to be measured, thereby measuring the body temperature of the person to be measured.

Japanese Unexamined Patent Publication No. 2014-135991

However, in the device described in Patent Document 1, since the body temperature is measured by a device installed in the vicinity of the person to be measured, it is necessary to set the positional relationship between the device and the person to be measured in advance, and the body temperature is measured accurately. It is difficult to do.

The body temperature measuring device according to one aspect of the present invention is attached to a face shield that is attached to the user to cover the user's face and is provided with a first aiming portion of the line of sight, an infrared sensor attached to the face shield, and a face shield. It comprises a second aiming portion that is attached and located in front of the first aiming portion in the user's line of sight. The infrared sensor is provided so as to detect infrared energy from a person to be measured located in the line-of-sight direction of the user defined by the first aiming unit and the second aiming unit.

The body temperature management system according to another aspect of the present invention includes a body temperature measuring device and a body temperature management device that manages the body temperature of the person to be measured measured by the body temperature measuring device.

According to the present invention, the body temperature can be measured easily and accurately.

The figure which shows the application example of the body temperature measuring apparatus which concerns on embodiment of this invention schematically. The perspective view which shows typically an example of the body temperature measuring apparatus which concerns on embodiment of this invention. A side view showing the vicinity of the second aiming portion of FIG. 2 in an enlarged manner. It is a figure for demonstrating the field of view of the user wearing the face shield of FIG. 2 in the state that the aim of the line of sight is fixed to the person to be measured. The figure for demonstrating the field of view of the user wearing the face shield of FIG. 2 in the state that the aim of the line of sight is not fixed to the person to be measured. 2 is a side view for explaining the relationship between the line-of-sight direction of the user wearing the face shield of FIG. 2 and the shooting direction of the camera and the detection direction of the infrared sensor. The figure for demonstrating the detection range of the infrared sensor of FIG. The front view schematically showing an example of the internal structure of the housing of FIG. 2 on the cover part side. The front view schematically showing an example of the internal structure of the housing of FIG. 2 on the base portion side. The block diagram which shows the whole structure of the body temperature management system which has the body temperature measuring apparatus which concerns on embodiment of this invention. The flowchart which shows an example of the process executed by the body temperature measuring apparatus which concerns on embodiment of this invention. The figure for demonstrating an example of the body temperature information managed by the management server of FIG.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 10. The body temperature measuring device according to the embodiment of the present invention measures the body temperature T of the person to be measured P2 facing the user P1. In particular, an example of measuring the body temperature T of the resident facing the long-term care staff of the long-term care facility will be described below.

In the long-term care facility, the temperature of the resident (body temperature measurement) is measured by the long-term care staff in order to manage the health condition of the resident. When measuring the temperature using a thermometer, it is a burden for the care staff because it is necessary to interrupt other work and record the temperature measurement result. Therefore, in the embodiment of the present invention, the body temperature measuring device is provided as follows so that the temperature can be easily and accurately measured by using the infrared sensor attached to the face shield worn by the nursing staff and the burden on the nursing staff can be reduced. Configure.

FIG. 1 is a diagram schematically showing an application example of the body temperature measuring device (device) 1 according to the embodiment of the present invention. As shown in FIG. 1, the long-term care staff (user) P1 faces the resident (measured person) P2 and provides long-term care such as meals and walking assistance. The average distance D1 between the user P1 and the person to be measured P2 when performing long-term care is, for example, a distance within an easily reachable range (for example, a little less than 1 m). The user P1 wears a face shield 2 that covers his / her face to provide nursing care in order to prevent droplets from the mouth and nose of the person to be measured P2.

FIG. 2 is a perspective view schematically showing an example of the device 1, and shows the device 1 in a state of being mounted on the user P1. In the following, along the shield surface of the face shield 2, the vertical direction, the horizontal direction, and the front-back direction as seen from the user P1 are defined as shown in the figure.

As shown in FIG. 2, the device 1 has a face shield 2. The face shield 2 is composed of, for example, a commercially available disposable face shield, and has a band-shaped band portion 3 that is wrapped around the head of the user P1 in a headband shape and attached, and the face of the user P1 downward from the lower end of the band portion 3. It has a shield portion 4 extending so as to cover the above. The band portion 3 is made of flat rubber or the like, and has a cushion portion 3a having a wall thickness (for example, about several centimeters) such as urethane resin in a portion corresponding to the forehead of the user P1. The cushion portion 3a secures a space between the face of the user P1 and the shield portion 4.

The shield portion 4 is made of an amorphous PET resin (A-PET) or the like, and has permeability and flexibility. The shield portion 4 is provided with a first aiming portion 5 at a position corresponding to the line-of-sight direction L1 when the user P1 faces the front. The first aiming portion 5 is provided on the center line CL in the left-right direction of the shield portion 4 and below the predetermined distance D2 from the upper end of the shield portion 4, and is provided on one side of the shield portion 4 (for example, as a rectangular frame line). , Front) is marked with ink. The first aiming portion 5 can be marked with, for example, a rubber stamp or a writing tool. By using a jig that defines the position of the first aiming portion 5 with respect to the face shield 2, the first aiming portion 5 is provided (marked) at an accurate position even when the disposable face shield 2 is replaced and used. Can be done.

A housing 6 for accommodating an infrared sensor or the like is detachably attached to the center of the band portion 3 above the first aiming portion 5 via, for example, double-sided tape. The housing 6 is made of a lightweight member such as a flexible resin, and has a base portion 6a attached to the band portion 3 and a cover portion 6b attached to the base portion 6a so as to be openable / closable or detachable. Have.

By using a jig that defines the mounting position of the housing 6 with respect to the face shield 2, the housing 6 can be mounted at an accurate position even when the disposable face shield 2 is replaced and used. Further, by using a jig that defines the positions of the first aiming portion 5 and the housing 6 with respect to the face shield 2, the relative positional relationship between the first aiming portion 5 and the housing 6 on the face shield 2 can be accurately determined. Can be specified in.

Below the housing 6, a second aiming portion 7 is provided in front of the first aiming portion 5 in the line-of-sight direction L1 when the user P1 faces the front. FIG. 3 is an enlarged side view showing the vicinity of the second aiming portion 7. As shown in FIG. 3, the second aiming portion 7 has a first extending portion 7a extending downward from the lower end of the housing 6 along the shield portion 4 and a front extending portion 7a from the lower end of the first extending portion 7a. It is attached to the housing 6 so as not to be movable relative to the housing 6 via the extending second extending portion 7b.

As shown in FIGS. 2 and 3, the second aiming portion 7 and the first and second extending portions 7a and 7b are integrally formed of a lightweight linear member such as a metal wire. For example, by bending both ends of one wire (linear member) as the upper ends of the first extending portion 7a, the second aiming portion 7 and the first and second extending portions 7a and 7b are integrally formed. Can be configured. The second aiming portion 7 can be configured by forming the central portion of the linear member in the shape of a quadrangular frame, for example.

4A and 4B are diagrams for explaining the field of view of the user P1 when the face shield 2 is attached and faces the person to be measured P2, and the first and second aiming portions 5 and 5 are in the field of view of the user P1. The aiming range AR1 defined by 7 will be described. As shown in FIG. 2, when the user P1 horizontally attaches the band portion 3 to the face shield 2 so that the shield portion 4 and the center of the face coincide with each other and looks at the person to be measured P2, FIG. 4A shows. As described above, the person to be measured P2 located in front of the line of sight of the user P1 enters the aiming range AR1. That is, the aim of the line of sight of the user P1 is determined by the person to be measured P2.

On the other hand, when the user P1 does not wear the face shield 2 straight or the line of sight is not aligned with the person to be measured P2, the aiming range AR1 is set by the first and second aiming portions 5 and 7, as shown in FIG. 4B. Is not specified, and the person to be measured P2 does not enter the aiming range AR1. That is, the aim of the line of sight of the user P1 is not determined by the person to be measured P2. As shown in FIG. 4A, the device 1 is configured to measure the body temperature T of the person to be measured P2 in a state where the aim of the line of sight of the user P1 is fixed to the person to be measured P2.

As shown in FIGS. 2 and 3, the housing 6 has a camera so as to photograph the person to be measured P2 located in front of the line of sight of the user P1 defined by the first and second aiming portions 5 and 7. 8 is attached. Further, the infrared sensor 9 is attached so as to detect the infrared energy from the person to be measured P2 located in front of the line of sight of the user P1. The infrared sensor 9 is configured as an infrared array sensor in which the light receiving units 9a have a plurality of (for example, 8 × 8 = 64) light receiving elements. The camera 8 and the infrared sensor 9 are partially housed inside the housing 6 so that the lens portion 8a on the front surface of the camera 8 and the light receiving portion 9a on the front surface of the infrared sensor 9 are exposed to the outside of the housing 6. ..

FIG. 5 is a side view for explaining the relationship between the line-of-sight direction L1 of the user P1 wearing the face shield 2 and the shooting direction L2 of the camera 8 and the detection direction L3 of the infrared sensor 9. As shown in FIG. 5, when the user P1 and the person to be measured P2 face each other so that their lines of sight coincide with each other, the face corresponding to the line of sight of the person to be measured P2 is in front of the line of sight direction L1 of the user P1. Located near the center. In the first and second aiming units 5 and 7, when the user P1 and the person to be measured P2 face each other at an average distance D1, the face of the person to be measured P2 enters the aiming range AR1 in the field of view of the user P1. Is set to.

When the user P1 and the person to be measured P2 face each other in this way, the vicinity of the forehead of the person to be measured P2 is located in front of the shooting direction L2 of the camera 8 and the infrared sensor 9. At this time, the upper part of the face of the person to be measured P2 including at least the forehead and both eyes of the person to be measured P2 is included in the shooting range AR2 of the camera 8 and the detection range AR3 of the infrared sensor 9. In FIG. 5, the shooting range AR2 of the camera 8 and the detection range AR3 of the infrared sensor 9 are shown to match, but the shooting range AR2 of the camera 8 and the detection range AR3 of the infrared sensor 9 are the shooting range AR2 of the camera 8 and the infrared sensor 9. It depends on the specifications and does not always match.

FIG. 6 is a diagram for explaining the detection range AR3 of the infrared sensor 9, and shows a plurality of (64 in the figure) light receiving ranges C1 to C64 for each light receiving element of the infrared sensor 9. The infrared sensor 9 detects infrared energy in each of the light receiving ranges C1 to C64 by each light receiving element, and outputs a data signal corresponding to the infrared energy detected in each of the light receiving ranges C1 to C64.

FIG. 7A is a front view schematically showing an example of the internal configuration of the housing 6 on the cover portion 6b side, and shows a rear view of the camera 8 and the infrared sensor 9. As shown in FIG. 7A, the cover portion 6b is provided with a through hole 6b1 corresponding to the lens portion 8a of the camera 8 and a through hole 6b2 corresponding to the light receiving portion 9a of the infrared sensor 9.

The camera 8 is configured as a camera unit in which a lens unit 8a, an input / output unit 8c, and the like are mounted on a substrate 8b, and is provided on a cover portion 6b via a plurality of (four in the figure) through holes 8d provided on the substrate 8b. It is attached. More specifically, the camera 8 is attached to the cover portion 6b from the inside of the housing 6 so that the lens portion 8a is exposed to the outside of the housing 6 through the through hole 6b1. The input / output unit 8c is configured as, for example, a flat cable connector to which a flat cable can be connected.

The infrared sensor 9 is configured as a sensor unit in which a light receiving unit 9a, an input / output unit 9c (9c1 to 9c5), and the like are mounted on a substrate 9b, and has a plurality of (two in the figure) through holes 9d provided on the substrate 9b. It is attached to the cover portion 6b via the cover portion 6b. More specifically, the infrared sensor 9 is attached to the cover portion 6b from the inside of the housing 6 so that the light receiving portion 9a is exposed to the outside of the housing 6 via the through hole 6b2.

FIG. 7B is a front view schematically showing an example of the internal configuration of the housing 6 on the base portion 6a side, and shows a front view of the controller 10 connected to the camera 8 and the infrared sensor 9. As shown in FIG. 7B, the controller 10 is a single board computer such as a Raspberry Pi in which a processing unit 12 or the like for processing signals from a camera 8 and an infrared sensor 9 is mounted on a single substrate 11. It is composed. In the following, an example of using Raspberry Pi Zero W (length: about 65 mm; width: about 30 mm) as the controller 10 will be described.

In addition to the processing unit 12, a camera input port 13, a micro USB power supply port 14, a micro USB port 15, a print antenna 16, and a mini HDMI (registered trademark) output port 17 are mounted on the board 11. Further, a micro SD card slot 18 and a general-purpose input / output port 19 are mounted. The substrate 11 is attached to the base portion 6a via through holes 11a provided at a plurality of (four in the figure) corner portions.

The camera input port 13 is connected to the input / output unit 8c of the camera 8 via the flat cable 13a. As a result, power is supplied from the controller 10 to the camera 8 via the flat cable 13a, and an image signal from the camera 8 is input to the controller 10.

For example, an L-shaped micro USB cable 14a is connected to the micro USB power supply port 14, and power is supplied to the controller 10 from the external battery 20 (FIG. 1) via the micro USB cable 14a. As the battery 20, for example, a mobile battery that can be accommodated in a pocket of clothes of the user P1 can be used. Since the power consumption of the controller 10 during operation is, for example, about 300 mA / h, for example, by using a battery 20 having a capacity of about 6700 mAh, the controller 10 can be continuously operated all day without charging or replacing the battery 20. Can be made to.

The print antenna 16 is configured as a print pattern on the substrate 11 and transmits / receives signals to / from the outside by wireless communication. That is, the print antenna 16 functions as an information output unit that outputs various information from the controller 10 to the outside.

A micro SD card 18a is inserted into the micro SD card slot 18. A program such as an operating system (OS) of the controller 10 is stored in advance in the micro SD card 18a. That is, the micro SD card 18a functions as a storage unit for storing various types of information.

The general-purpose input / output port 19 is composed of a plurality of (40 in the figure) terminals, and some of the terminals are connected to the input / output unit 9c of the infrared sensor 9. For example, the 3.3V output terminal 19_1, the serial data input / output terminal 19_3, the serial clock input terminal 19_5, and the ground terminal 19_9 are connected to the input / output units 9c1, 9c4, 9c5, 9c2 of the infrared sensor 9, respectively. As a result, power is supplied from the controller 10 to the infrared sensor 9, and a data signal from the infrared sensor 9 is input to the controller 10. More specifically, a data signal corresponding to the infrared energy detected for each of the plurality of light receiving ranges C1 to C64 (FIG. 6) of the infrared sensor 9 is input to the controller 10.

The processing unit 12 is configured as a SoC (System-on-a-chip) in which a CPU core, a GPU, a memory, and other peripheral circuits are integrated on a single semiconductor chip. The processing unit 12 processes the signals from the camera 8 and the infrared sensor 9 according to the program stored in the storage unit (micro SD card) 18a in advance. The processing result by the processing unit 12 is output to the outside of the controller 10 via the information output unit (print antenna) 16.

FIG. 8 is a block diagram schematically showing the overall configuration of the body temperature management system 100 having the device 1. As shown in FIG. 8, the body temperature management system 100 manages the device 1 for measuring the body temperature T of the resident (measured person P2) of the nursing facility and the body temperature T for each measured person P2 measured by the device 1. It has a management server 30 to be used. Although only one device 1 is shown in FIG. 8, a plurality of devices 1 constituting the body temperature management system 100 are provided, for example, according to the number of care staff (users) P1 in the care facility.

The management server 30 is configured to include a computer having a CPU, ROM, RAM, HDD, and other peripheral circuits, and is a device of each user P1 via a wireless LAN network in a nursing care facility such as Wi-Fi (registered trademark). It is connected to 1 (controller 10). The management server 30 stores and manages information such as a long-term care record including a temperature measurement result for each resident in association with the resident ID, for example.

Nursing staff and doctors who manage the health status of residents of nursing facilities can access the management server 30 via user terminals such as personal computers and tablet terminals to record nursing care records for each resident as necessary. Information can be displayed and edited. For example, the daily change in body temperature T for a specific resident can be displayed in a graph format.

Authentication information for face recognition of the person to be measured P2 is registered in advance in the controller 10 of the device 1 and stored in the storage unit (micro SD card) 18a. For example, the image data of the face of each resident is stored as authentication information in association with the resident ID. As such authentication information, image data in a state where the entire face is exposed without wearing a mask and image data in a state where only the upper part of the face including the forehead and both eyes is exposed with the mask attached are registered. As a result, face recognition can be performed accurately regardless of whether or not the person to be measured P2 wears a mask.

The processing unit 12 of the controller 10 has, as a functional configuration, a face recognition unit 12a for face recognition of the person to be measured P2 and a body temperature determination unit 12b for determining the body temperature T of the person to be measured P2 whose face has been recognized. In other words, the processing unit 12 functions as a face recognition unit 12a and a body temperature determination unit 12b.

The face recognition unit 12a faces the person to be measured P2 based on the image signal from the camera 8 input via the camera input port 13 and the authentication information stored in advance in the storage unit (micro SD card) 18a. Authenticate. More specifically, as shown in FIG. 5, the user P1 wearing the face shield 2 and the person to be measured P2 face each other, and the face of the person to be measured P2 including at least the forehead and both eyes in the shooting range AR2 of the camera 8. When the upper part is entered, the person to be measured P2 is face-authenticated and the resident ID is specified.

The body temperature determination unit 12b is based on the data signal from the infrared sensor 9 input via the general-purpose input / output port 19 when the subject P2 is face-authenticated by the face authentication unit 12a and the resident ID is specified. , Determine the body temperature T of the subject P2. More specifically, based on the data signals corresponding to the infrared energies detected in each of the plurality of light receiving ranges C1 to C64 (FIG. 6) of the infrared sensor 9, the temperatures T1 to T64 in each of the plurality of light receiving ranges C1 to C64. Is calculated, and the maximum temperature in the temperature is determined as the body temperature T of the person to be measured P2. For example, the temperatures T36 and T37 of the light receiving ranges C36 and C37 (FIG. 6) corresponding to the vicinity of the forehead of the person to be measured P2 are determined as the body temperature T of the person to be measured P2.

The information on the body temperature T of the subject P2 determined by the body temperature determination unit 12b is associated with the resident ID of the subject P2 identified by the face recognition unit 12a via the information output unit (print antenna) 16. Is transmitted to the management server 30.

FIG. 9 is a flowchart showing an example of the processing executed by the controller 10 of the apparatus 1, and shows the processing executed by the processing unit 12 according to the program stored in the storage unit (micro SD card) 18a in advance. The process shown in this flowchart is started, for example, when power is supplied from the battery 20 to the controller 10, and is repeated every predetermined time (for example, 10 seconds).

As shown in FIG. 9, first, in step S1, it is determined whether or not the person to be measured P2 has face recognition. Step S1 is repeated until affirmed. If affirmed in step S1, the process proceeds to step S2, and the body temperature T of the subject P2 is determined. Next, the process proceeds to step S3, and the information of the body temperature T determined in step S3 is transmitted to the management server 30 in association with the resident ID specified in step S1. That is, when the line of sight of the user P1 is set to the person to be measured P2 (FIG. 4A) and the person to be measured P2 enters the shooting range AR2 of the camera 8 and the detection range AR3 of the infrared sensor 9 (FIG. 6), the person to be measured P2 is face-authenticated and the body temperature T is automatically measured (step S1 → S2). As a result, every time the line of sight of the user P1 is set to the person to be measured P2, the resident ID is specified, the temperature is measured, and the temperature measurement result is recorded automatically. Therefore, it is simple and frequent regardless of the operation of the user P1. In addition, the temperature of the person to be measured P2 can be measured with high accuracy.

FIG. 10 is a diagram for explaining an example of information on the body temperature T managed by the management server 30. As shown in FIG. 10, the information on the body temperature T is stored in the management server 30 as time-series information with the information on the time t attached to each resident. The body temperature T of each resident is measured by the device 1 each time each resident faces the care staff (user) P1 as the person to be measured, and is transmitted to the management server 30 together with the time information and accumulated. In the example of FIG. 10, the body temperature TA of the resident A at time t1, the body temperature TB of the resident B at time t2, and the body temperature TC of the resident C at time t3 are measured by the device 1 and recorded in the management server 30. There is. In this way, the body temperature T of each resident is automatically measured and recorded each time a plurality of long-term care staff members of the long-term care facility face the resident, so that the resident's temperature and temperature can be measured frequently without the burden of the long-term care staff. Results can be recorded.

According to this embodiment, the following effects can be obtained.
(1) The body temperature measuring device 1 includes a face shield 2 which is attached to the user P1 to cover the face of the user P1 and is provided with a first aiming portion 5 of the line of sight, an infrared sensor 9 attached to the face shield 2, and an infrared sensor 9. A second aiming portion 7 attached to the face shield 2 and arranged in front of the first aiming portion 5 in the line-of-sight direction L1 of the user P1 is provided (FIG. 2). The infrared sensor 9 is provided so as to detect infrared energy from the subject P2 located in the line-of-sight direction L1 of the user P1 defined by the first and second aiming portions 5 and 7 (FIG. 5).

As a result, the body temperature T of the person to be measured P2 facing the user P1 wearing the face shield 2 can be automatically measured. Therefore, for example, the care staff of the care facility measures the temperature of the resident and records the temperature measurement result. It is possible to reduce the work load due to. Further, since the detection direction L3 of the infrared sensor 9 is set according to the line-of-sight direction L1 of the user P1, the infrared energy from the face of the person to be measured P2 facing the user P1 is detected, and the body temperature T is measured accurately. be able to.

(2) The device 1 further includes a camera 8 attached to the face shield 2 and a controller 10 attached to the face shield 2 and connected to the camera 8 and the infrared sensor 9 (FIGS. 2, 7A, 7B). , FIG. 8). The controller 10 includes a storage unit (micro SD card) 18a that stores authentication information for face recognition of the person to be measured P2, a signal from the camera 8, and authentication information stored in the storage unit (micro SD card) 18a. When the measured person P2 is face-recognized by the face recognition unit 12a that authenticates the face of the person to be measured P2 based on the above, and the face recognition unit 12a by the face recognition unit 12a based on the signal from the infrared sensor 9. An information output unit (print antenna) that outputs information on the body temperature T determined by the body temperature determination unit 12b that determines the body temperature T of the person to be measured P2 and the body temperature T determined by the body temperature determination unit 12b in association with the authentication result by the face recognition unit 12a. ) 16 (FIG. 7B, FIG. 8).

As a result, for example, the device 1 side of each long-term care staff (user) P1 of the long-term care facility performs face authentication of the resident (measured person) P2 based on the authentication information of the resident of the long-term care facility, and for each resident. Information on the body temperature T can be transmitted to the management server 30 of the long-term care facility and managed. That is, it can be accumulated and managed as time-series body temperature information for each resident.

(3) The infrared sensor 9 is composed of an infrared array sensor having a plurality of light receiving elements. The body temperature determining unit 12b determines the maximum temperature among the plurality of temperatures detected for each of the plurality of light receiving elements as the body temperature T of the person to be measured P2. That is, since the surface temperature near the forehead of the high temperature in the face of the person to be measured P2 facing the user P1 is determined as the body temperature T, the body temperature T can be measured more accurately.

(4) The face shield 2 has a band-shaped band portion 3 attached to the head of the user P1 and a shield portion 4 extending downward from the lower end of the band portion 3 so as to cover the face of the user P1. (Figs. 2 and 5). As a result, the relative positional relationship between the face shield 2 to which the infrared sensor 9 is attached and the line-of-sight direction L1 of the user P1 is fixed, so that the body temperature T can be measured more accurately.

(5) The device 1 includes a housing 6 attached to the band portion 3 and accommodating the infrared sensor 9, and a first extending portion 7a extending downward from the lower end of the housing 6 along the shield portion 4. A second extending portion 7b extending forward from the lower end of the first extending portion 7a is further provided (FIGS. 2 and 3). The second aiming portion 7 is provided at the front end portion of the second extending portion 7b (FIG. 3). By providing the first aiming portion 5 and the second aiming portion 7 apart from each other in this way, the user's line-of-sight direction L1 can be accurately defined as shown in FIG. 5, and the body temperature T can be more accurately defined. Can be measured.

(6) The first extending portion 7a and the second extending portion 7b are composed of linear members (FIGS. 2 and 3). As a result, the entire device 1 can be configured to be lightweight, and the view of the user P1 can be less likely to be obstructed.

(7) The housing 6 is detachably provided on the band portion 3 (FIG. 2). As a result, the device 1 can be used repeatedly while replacing the face shield 2.

(8) The body temperature management system 100 includes a device 1 and a management server 30 that manages the body temperature T of the person to be measured P2 measured by the device 1 (FIG. 8). Thereby, for example, the time-series body temperature information for each of the plurality of residents (measured persons) P2 facing the plurality of care staff (users) P1 of the care facility can be managed by a single management server 30.

In the above embodiment, the user P1 of the device 1 is described as the care staff of the care facility, and the person to be measured P2 whose body temperature T is measured by the device 1 is described as a resident of the care facility. The measurer is not limited to these. For example, a doctor or a nurse may be a user, an inpatient may be a subject, a nursery teacher may be a user, and a kindergarten child may be a subject.

In the above embodiment, the average distance D1 between the user P1 and the person to be measured P2 is illustrated as a distance within an easily reachable range in FIG. 1 and the like, but the distance between the user and the person to be measured is illustrated. Is not limited to such things.

In the above embodiment, the specific shape of the face shield 2 is illustrated in FIG. 2 and the like, but the face shield worn by the user and covering the user's face is not limited to such a shape. For example, it may be worn on the neck to cover the face from below, glasses or masks worn over the ears with a shield attached, or a hat with a shield attached.

In the above embodiment, the detection direction L3 of the infrared sensor 9 is made parallel to the line-of-sight direction L1 of the user P1 in FIG. If it is detected, it may be provided in any way. That is, the mounting direction of the infrared sensor 9 can be appropriately adjusted according to the shape of the face shield 2, the average distance D1 between the user P1 and the person to be measured P2, and the like.

In the above embodiment, specific shapes of the first and second aiming portions 5 and 7 are illustrated in FIG. 2, but the first and second aiming portions are not limited to such a shape. For example, it may be a border other than a quadrangle such as a circle, or it may be a pointer having an arbitrary shape. In this case, for example, by aligning the pointer with the vicinity of the forehead of the person to be measured P2, the aim of the line of sight of the user P1 can be determined.

In the above embodiment, the device 1 and the management server 30 that measure and manage the body temperature T of the person to be measured P2 are exemplified in FIG. 8, but the body temperature measuring device and the body temperature management device are not limited to such devices. It may be the one that further acquires and manages biological information other than body temperature. For example, the blood pressure of the person to be measured P2 may be further measured and managed based on the signals from the camera 8 and the infrared sensor 9. Further, it may be configured to notify when the body temperature, blood pressure, or the like deviates from the normal range for each resident, or when the measurement is never performed within a predetermined period.

The above description is merely an example, and the present invention is not limited to the above-described embodiments and modifications as long as the features of the present invention are not impaired. It is also possible to arbitrarily combine one or a plurality of the above-described embodiments and the modified examples, and it is also possible to combine the modified examples.

1 Body temperature measuring device (device), 2 Face shield, 3 Band part, 4 Shield part, 5 1st aiming part, 6 housing, 7 2nd aiming part, 7a 1st extension part, 7b 2nd extension part, 8 camera, 9 infrared sensor, 10 controller, 11 board, 12 processing unit, 12a face authentication unit, 12b body temperature determination unit, 13 camera input port, 14 micro USB power supply port, 16 print antenna, 18 micro SD card slot, 18a micro SD card, 19 general-purpose I / O port, 20 battery, 30 management server, 100 body temperature management system

Claims (8)

A face shield that is attached to the user to cover the user's face and is provided with the first aiming part of the line of sight.
The infrared sensor attached to the face shield and
A second aiming portion attached to the face shield and arranged in front of the first aiming portion in the user's line-of-sight direction.
The infrared sensor is a body temperature measuring device provided so as to detect infrared energy from a person to be measured located in a user's line-of-sight direction defined by the first aiming unit and the second aiming unit. In the body temperature measuring device according to claim 1,
The camera attached to the face shield and
Further equipped with a controller attached to the face shield and connected to the camera and the infrared sensor.
The controller
A storage unit that stores authentication information for face recognition of the person to be measured,
A face recognition unit that authenticates the face of the person to be measured based on the signal from the camera and the authentication information stored in the storage unit,
When the person to be measured is face-recognized by the face recognition unit, the body temperature determination unit that determines the body temperature of the person to be measured whose face is authenticated by the face recognition unit based on the signal from the infrared sensor, and the body temperature determination unit.
A body temperature measuring device comprising: an information output unit which outputs information of a body temperature determined by the body temperature determination unit in association with an authentication result by the face authentication unit. In the body temperature measuring device according to claim 2,
The infrared sensor is composed of an infrared array sensor having a plurality of light receiving elements.
The body temperature determining unit is a body temperature measuring device characterized in that the maximum temperature among the temperatures detected for each of the plurality of light receiving elements is determined as the body temperature of the person to be measured. In the body temperature measuring device according to any one of claims 1 to 3.
The face shield is
A band-shaped band worn on the user's head,
A body temperature measuring device comprising a shield portion extending downward from the lower end of the band portion so as to cover the user's face. In the body temperature measuring device according to claim 4,
A housing attached to the band portion and accommodating the infrared sensor,
A first extending portion extending along the shield portion downward from the lower end of the housing,
A second extending portion extending forward from the lower end of the first extending portion is further provided.
The second aiming portion is a body temperature measuring device provided at the front end portion of the second extending portion. In the body temperature measuring device according to claim 5,
The body temperature measuring device, wherein the first extending portion and the second extending portion are composed of a linear member. In the body temperature measuring device according to claim 5 or 6.
The body temperature measuring device is characterized in that the housing is detachably provided on the band portion. The body temperature measuring device according to any one of claims 1 to 7.
A body temperature management system including a body temperature management device for managing the body temperature of a person to be measured measured by the body temperature measuring device.

Images