TWI648030B - Physiological signal monitoring device - Google Patents

Abstract

The physiological signal monitoring device comprises: at least one connecting component and a physiological signal monitoring device. The connection assembly includes a first connector and a second connector. The physiological signal monitoring device is configured to detachably couple with a fixing portion through the connecting component, and the physiological signal monitoring device is configured to monitor at least a temperature change and a displacement change of the living body when the fixing portion is attached to the living body. The physiological signal monitoring device has: at least one engaging member and at least one contact member, the engaging member is at least partially matched with the second connecting body of the connecting component, and the connecting member elastically protrudes from the opening of the engaging member And for temperature sensing. The second connection system of the connection component is fixed to the outside of the connection area of the fixing portion to be combined with the first connection body of the connection component.

Description

Physiological signal monitoring device

The present invention relates to a physiological signal monitoring device, and more particularly to a physiological signal monitoring device that is detachably attached to a living body.

The conventional physiological signal monitoring device requires the sensor to be closely attached to the user. When the type of physiological signal detected by the physiological signal monitoring device increases, the area of the sensor that is closely attached to the user is also It will increase. In addition, in the case where it is necessary to increase the accuracy, for example, in the case of detecting the temperature of the human body surface, it also means that the number of sensors and the number of parts covered must be increased. However, configuring the sensor in this way will result in reduced comfort for the user. If it takes a long time to detect the physiological signal, it will cause the user to feel inconvenient or uncomfortable. During the user's rest or sleep, the user may unconsciously remove the sensor and lose the sense of detection.

In addition, in some applications, such as the physiological signal detection requirements of infants, children or the elderly, if the physiological signal monitoring device is not comfortable, it will cause the users to have emotional or unwilling to use. Therefore, how to reduce the contact area between the sensor of the physiological signal monitoring device and the user's body and increase the comfort is a direction for improvement.

An object of the present invention is to provide a physiological signal monitoring device that is detachably attached to a living body and can detect a physiological signal of a user by using a small contact method, thereby providing a better user experience. .

In order to achieve at least the above object, the present invention provides a physiological signal monitoring device comprising: at least one connection component and a physiological signal monitoring device. The connecting component includes a first connecting body and a second connecting body, and the first connecting body and the second connecting system exist in a state of being combined or separated from each other. The physiological signal monitoring device is configured to detachably couple with a fixing portion through the connecting component, and the physiological signal monitoring device is configured to monitor at least a temperature change and a displacement of the living body when the fixing portion is attached to the living body. The physiological signal monitoring device has: at least one engaging member and at least one contact member, the first side of the engaging member is at least partially matched with the second connecting body of the connecting component, the contact member is elastically from the The opening on the first side of the joint protrudes and is used for temperature sensing. The second connection system of the connection component is fixed to the outside of the connection area of the fixing part to be coupled with the first connection body of the connection component, so that the physiological signal monitoring device is detachably connected to the connection through the joint component. The assembly is detachably coupled to the fixing portion, and when the fixing portion is attached to the living body, the contact member is used to indirectly or directly contact the living body for temperature sensing.

In an embodiment of the present invention, the first connection system of the connecting component is fixed to the inner side of the connecting portion of the fixing portion to be coupled with the second connecting body of the connecting component to allow the physiological signal monitoring device to pass through the The engaging member is detachably coupled to the connecting component to be coupled to the fixing portion, and when the fixing portion is attached to the living body, the contact member is used for indirect or direct contact with the living body for temperature sensing.

In an embodiment of the invention, the first side of the second connecting body of the connecting component is at least partially matched with the first side of the engaging member, and has a hole for allowing the contact to pass indirectly or Temperature sensing is performed by directly contacting the organism.

In an embodiment of the invention, the physiological signal monitoring device comprises: a detecting module and a monitoring module. The detection module is configured to be detachably coupled to the fixing portion through the at least one connecting component and output the detecting data when contacting the living body, the detecting module comprising: a first temperature detecting unit having The joint member and the contact member are configured to detect a temperature of the living body toward the living body and output a first temperature signal; and a second temperature detecting unit for detecting outside the living body Measuring the temperature of the surrounding environment and outputting a second temperature signal. The monitoring module is coupled to the detection module for receiving at least the first temperature signal and the second temperature signal to monitor a temperature change of the living body and monitor a change in the displacement of the living body.

In an embodiment of the invention, the monitoring module comprises: a displacement sensing unit, a control unit, an output unit, and a wireless transmission unit. The displacement sensing unit is configured to detect a displacement change of the living body cavity activity and generate a displacement signal accordingly. The control unit is electrically coupled to the first temperature detecting unit, the second temperature detecting unit, the displacement sensing unit, and the output unit, wherein the control unit is based on the first temperature signal and the second a temperature warning signal is generated when the temperature of the living body satisfies a temperature warning condition, and a displacement is issued when the control unit determines that the displacement change of the living body meets a displacement warning condition according to the displacement signal Warning signal. The output unit is electrically coupled to the control unit. The wireless transmission unit is electrically coupled to the control unit for wirelessly connecting a terminal monitoring device, and transmitting the temperature data according to the first temperature signal and the second temperature signal, and transmitting the displacement data according to the displacement signal to The terminal monitoring device.

In an embodiment of the invention, the first temperature detecting unit further comprises: a temperature sensor and an elastic member. The temperature sensor is disposed in the contact for outputting the first temperature signal. The elastic member is engaged with the first end of the contact member such that the second end of the contact member protrudes from the opening of the first side of the engaging member.

In an embodiment of the invention, the detecting module further comprises: a connecting housing. The connecting housing has a connecting portion and a plurality of extending portions. The connecting portion is configured to at least partially cover a periphery of the monitoring module and is detachably connected to the monitoring module. The extensions extend outward from the connecting portion, and the first temperature detecting unit and the second temperature detecting unit are respectively disposed in the receiving spaces in the extending portions. The extension portion corresponding to the first temperature detecting unit has a first detecting opening for extending the engaging member and the contact member of the first temperature detecting unit from the accommodating space in the extending portion to the first One detects the outside of the opening.

In an embodiment of the present invention, the extension portion corresponding to the second temperature detecting unit has a second detecting opening, and the second detecting opening is configured to sense a temperature of the second temperature detecting unit. The detector senses the temperature of the environment indirectly or directly from the second detecting opening, wherein the first detecting opening is directed inward for the temperature detecting direction of the living body, and the second detecting opening is facing outward The direction of temperature detection in the environment.

In an embodiment of the present invention, the connecting portion has a plurality of connecting openings, and the detecting module further includes a plurality of connecting ends, wherein the connecting ends are respectively disposed in the connecting openings and the inner sides of the connecting portions In at least one of the first temperature detecting unit and the second temperature detecting unit, the monitoring module is electrically coupled to the first temperature detecting unit and the second temperature detecting unit.

In an embodiment of the invention, the physiological signal monitoring device further includes the fixing portion for attaching to the living body, the fixing portion comprising a wearing body, the connecting region being located on the wearing body.

In an embodiment of the invention, the wearing system of the fixing portion comprises a cleanable material, and the fixing portion can be cleaned separately when separated from the physiological signal monitoring device.

In an embodiment of the present invention, the wearing system of the fixing portion is configured to be fixed around the surface of the living body by means of a cross strap or a devil felt, so that the physiological signal monitoring device is detachably When the fixing portion is combined, the temperature change and the displacement change of the living body are monitored.

Therefore, the embodiment of the physiological signal monitoring device is detachably attached to the living body, and can detect the physiological signal of the user by using a small contact method, so that the user can obtain better use. Experience.

In order to fully understand the objects, features and advantages of the present invention, the present invention will be described in detail by the following specific embodiments and the accompanying drawings.

Please refer to Figure 1 to Figure 4. FIG. 1 is a schematic diagram of a physiological signal monitoring device according to an embodiment of the present invention. FIG. 2 is a schematic diagram of a combination of a physiological signal monitoring device according to an embodiment of the present invention. FIG. 3 is a schematic diagram of the connecting component 20 in the fixing portion 10 according to an embodiment of the invention. 4 is a schematic illustration of one embodiment of a connection assembly 20. As shown in FIG. 1 to FIG. 3, the physiological signal monitoring device 1 includes at least one connecting component 20 and a physiological signal monitoring device 30.

As shown in FIG. 3 and FIG. 4, the connecting component 20 includes a first connecting body 21 and a second connecting body 22, and the first connecting body 21 and the second connecting body 22 are coupled to each other or separated from each other. presence. For example, the first connecting body 21 and the second connecting body 22 have irregularities or any intermeshing structure to each other for bonding. Moreover, the first connecting body 21 and the second connecting body 22 each have at least one hole.

As shown in FIG. 1 and FIG. 2, the physiological signal monitoring device 30 is detachably coupled to a fixing portion 10 through the connecting component 20, and the physiological signal is when the fixing portion 10 is attached to the living body BD. The monitoring device 30 is at least used to monitor temperature changes and displacement changes of the living body. The fixing portion 10 includes a wearing body 11 and a connecting area 12 for attaching to the living body BD. For example, the fixing portion 10 is an object that can be attached to the living body BD, such as a wearable object; and the living body BD is a human body such as an infant, a teenager, an adult or an elderly person; or the living body BD is an animal, such as Pets of cats and dogs, horses, cattle or other animals, etc.; however, the implementation of the present invention is not limited by the examples of fixed parts and detected objects.

As shown in FIG. 2, FIG. 5 and FIG. 6, the physiological signal monitoring device 30 has at least one engaging member 31 and at least one contact member 32. The first side of the engaging member 31 is coupled to the second side of the connecting member 20. The connector 22 is at least partially mating, and the contact member 32 is elastically protruded from the opening of the first side of the engaging member 31 and is used for temperature sensing.

As shown in FIG. 2, FIG. 5 and FIG. 6, the second connecting body 22 of the connecting component 20 is fixed to the outside of the connecting region 12 of the fixing portion 10 to be coupled with the first connecting body 21 of the connecting component 20. The physiological signal monitoring device 30 is detachably coupled to the fixing portion 10 through the connecting member 31, and is coupled to the fixing portion 10 when the fixing portion 10 is attached to the living body. The organism is contacted indirectly or directly for temperature sensing.

As shown in FIG. 2, FIG. 5 and FIG. 6, the first connecting body 21 of the connecting component 20 is fixed to the inner side of the connecting region 12 of the fixing portion 10 to be combined with the second connecting body 22 of the connecting component 20. The physiological signal monitoring device 30 is detachably coupled to the fixed portion 10 through the joint member 31, and the contact member 32 is used for indirect when the fixed portion 10 is attached to the living body. Or directly contact the organism for temperature sensing. In addition, as shown in FIG. 3 and FIG. 5, the region of the fixing portion 10 corresponding to the hole of the connecting component 20 also has a hole for the engaging member 31 to pass.

FIG. 7 is a schematic diagram of an embodiment in which the connection assembly 20 is coupled to the fixed portion 10. Compared with FIG. 5, the connecting component 20 shown in FIG. 7 can also be fixed to the outer side of the fixing portion 10. In FIG. 7, the fixing portion 10 may be, for example, a wearable fabric, and the user may sew the connecting member 20 to the outer side of the fixing portion 10. For example, the fixing portion 10 in FIG. 7 may be any wearable object, and the connecting component 20 is fixed to the fixing portion 10 in a buried or embedded manner.

For example, the first side of the second connecting body 22 of the connecting component 20 is at least partially mated with the first side of the engaging member 31 and has at least one hole for the contact 32 to pass through. Temperature sensing is performed by indirect or direct contact with the organism. In addition, FIG. 8 is a schematic diagram of another embodiment of a connection assembly. The connector assembly 20A shown in Figure 8 has two holes for the contacts to pass. Please refer to FIG. 9 , which is a schematic diagram of another embodiment in which the physiological signal monitoring device is detachably coupled to the fixed portion 10 through the connecting component 20A. As shown in Fig. 9, the physiological signal monitoring device has a concave-convex engaging member 31A and two contact members 32A matched with the connecting member 20A.

In addition, in the implementation of any of the above embodiments, the connecting component can also be implemented in other manners, such as the connecting component including a first connecting body and a second connecting body, wherein the second connecting body has a hole for Engaging with the engaging member, and the first connecting body has no through hole corresponding to the hole of the second connecting body, such that after the first connecting body and the second connecting body are coupled to the fixing portion 10, one side of the first connecting body Can be used to contact with the organism BD. By way of other implementations of the connection assembly, for the engagement member 31 and the contact member 32 of the appropriately configured physiological signal monitoring device 30 (such as changing the length of both), the engagement member 31 can pass through the connection assembly The two connectors are fixed to obtain a fixing effect, and the contact member 32 can further contact the first connecting body of the connecting component such that one side of the first connecting body contacting the living body BD is used for the sensing region extending from the contact member 32. Wherein the first connector is a metal or has a conductive or thermally conductive material. In addition, for example, in FIG. 6 or FIG. 9 , outside the first connecting body below, the connecting component may further comprise an extension body capable of abutting the contact member 32 , the extension body being sleeved on the first connection The outside of the body 20, thereby obtaining the function of the sensing area of the extended contact 32.

FIG. 10 is a block diagram showing an embodiment of a physiological signal monitoring device 30. As shown in FIG. 10, the physiological signal monitoring device 30 includes a detection module 310 and a monitoring module 320.

The detecting module 310 is configured to detachably couple with the fixing portion 10 through the at least one connecting component 20 and output the detecting data when contacting the living body. The detection module 310 includes: at least one first temperature detecting unit 311 and at least one second temperature detecting unit 312. The first temperature detecting unit 311 has the engaging member 31 and the contact member 32 for detecting the temperature of the living body toward the living body and outputting a first temperature signal. The second temperature detecting unit 312 is configured to detect a temperature of the surrounding environment in a direction other than the living body and output a second temperature signal.

The monitoring module 320 is coupled to the detection module 310 for receiving at least the first temperature signal and the second temperature signal to monitor temperature changes of the living body and to monitor changes in the displacement of the living body. As shown in FIG. 10, the monitoring module 320 includes a displacement sensing unit 321, a control unit 322, an output unit 323, and a wireless transmission unit 324. The monitoring module 320 can further communicate with an external device in a wireless manner to transmit the monitored temperature change and displacement to an external device, as shown in FIG.

The displacement sensing unit 321 is configured to detect a displacement change of the living body cavity of the living body and generate a displacement signal accordingly.

The control unit 322 is electrically coupled to the first temperature detecting unit 311, the second temperature detecting unit 312, the displacement sensing unit 321, and the output unit 323, wherein the control unit 322 is configured according to the first When the temperature of the living body and the second temperature signal are measured, the temperature warning signal is sent when the temperature of the living body meets a temperature warning condition, and the displacement change of the living body measured by the control unit 322 according to the displacement signal satisfies A displacement warning signal is issued when the warning condition is shifted. For example, if the temperature warning condition is when the temperature of the living body is greater than a temperature upper threshold, such as when the temperature is greater than 38 degrees Celsius, a temperature warning signal is issued; or when the temperature of the living body is less than a lower temperature threshold, If it is less than 37 degrees Celsius, a temperature warning signal is issued. For example, the displacement warning condition is such that when the displacement of the living body is greater than a displacement upper threshold value, a displacement warning signal is issued; or when the displacement of the living body is less than a lower displacement threshold value, a displacement warning signal is issued. For example, the detection module 310 can have a plurality of first temperature detecting units 311, and obtain a plurality of temperature values representing the living body, whereby the control unit 322 can utilize statistical methods or time units. The average value is used to obtain an estimated value of the temperature of the living body, or a maximum temperature value or a minimum temperature value, thereby being used to determine whether the organism has an abnormal temperature condition. Further, for example, the displacement sensing unit 321 outputs a variation amount of three coordinate axes or more of the displacement amount, and the control unit 322 may be based on a displacement variation amount of the three coordinate axes (for example, a sum of absolute values of displacement changes of the three coordinate axes or The sum of squares is used to indicate the amount of displacement of the organism. However, implementations of the invention are not limited by these examples.

The output unit 323 is electrically coupled to the control unit 322. For example, a display such as a liquid crystal display, an electronic paper or an OLED can be used to display the detected temperature, the temperature of the ring, the displacement data or the warning signal, or can be used for the user interface to facilitate the user to operate or set the physiological signal monitoring device 30.

The wireless transmission unit 324 is electrically coupled to the control unit 322 for wirelessly connecting a terminal monitoring device 90, and according to the first temperature signal and the second temperature signal, the temperature data is shifted according to the displacement signal. The data is transmitted to the terminal monitoring device 90 as shown in FIG. For example, the wireless transmission unit 324 is, for example, Bluetooth, Low Power Bluetooth (BLE), Infrared or Zigbee or other wireless communication protocols.

In addition, the monitoring module 320 further includes other components as needed; for example, the memory unit 325 is configured to store input or output data from other units or external devices, or is configured to operate the monitoring module 320; Such as wired communication units such as USB connection circuits, power circuits, rechargeable batteries, solar cells, warning lights or buzzers. Furthermore, for example, on any of the monitoring module 320 or the detection module 310, other sensors, such as a heart rate sensor, etc., may be provided; however, the implementation of the present invention is not limited thereto.

Various implementations of the internal structure of the first temperature detecting unit 311 of the detecting module 310 are further illustrated below. As described above, the first temperature detecting unit 311 has the engaging member 31 and the contact member 32. Please refer to FIG. 12, which is a schematic view of one embodiment of the joint member. FIG. 13 is a cross-sectional view of the joint member 410 of FIG. 12 along line A-A. As shown in FIG. 13, the underside of the engaging member 410 has a convex shape, and the engaging member 31 has a hole 411 for accommodating the contact member 420. Please refer to FIG. 14 , which is an exploded perspective view of an embodiment of the first temperature detecting unit 311 . FIG. 15 is a cross-sectional view of an embodiment of the first temperature detecting unit 311 . As shown in FIG. 14 , the first temperature detecting unit 311 further includes: an elastic member 430 and a temperature sensor 440 . The temperature sensor 440 is disposed in the contact 420 for outputting the first temperature signal. For example, in FIG. 14, the contact 32 includes 421 and 422; when the temperature sensor 440 is placed between the first sub-contact 421 and the second sub-contact 422 and the first sub-contact 421 is After the second sub-contacts 422 are combined, the temperature sensor 440 will be disposed in the first sub-contact 421 as shown in FIG. 14, such as the position PT indicated by the dashed oval, and the two signal lines 450 of the temperature sensor 440. It can be guided to the two contact ends through the holes of 422 to be electrically coupled to the monitoring module 320. In addition, as shown in FIG. 14 and FIG. 15, the elastic member 430 is engaged with the first end of the contact member 420 such that the second end of the contact member 420 is from the first side of the engaging member 410. The opening is convex.

Other embodiments of the physiological signal monitoring device 30 are further illustrated below.

Please refer to FIG. 16 to FIG. 20, which is another embodiment of the physiological signal monitoring device 30. Figure 16 is a top perspective view of another embodiment of a physiological signal monitoring device. Figure 17 is a bottom view of the physiological signal monitoring device 30A of Figure 16 . Figure 18 is a front elevational view of the physiological signal monitoring device 30A of Figure 16 . Figure 19 is a rear elevational view of the physiological signal monitoring device 30A of Figure 16 . FIG. 20 is a schematic diagram showing the combination of the physiological signal monitoring device 30A of FIG. 16 and the connection assembly 20 and the fixing portion 10A.

In some embodiments of the physiological signal monitoring device according to the present invention, the physiological signal monitoring device may include a fixing portion (such as 10 or 10A), wherein the wearing portion (such as 11 or 11A) of the fixing portion includes a cleanable material ( At least partially or wholly. For example, the fixed portion can be cleaned separately when separated from the physiological signal monitoring device (such as 30 or 30A). In addition, for example, the wearing system of the fixing portion is configured to be fixed around the surface of the living body such as the chest, the abdomen, the hand or other parts by means of a cross strap or a devil felt. The physiological signal monitoring device is detachably coupled to the fixed portion to monitor temperature changes and displacement changes of the living body. However, the implementation of the present invention is not limited by the example of the fixed part; that is, when the physiological signal monitoring device is implemented or sold, the fixed part is regarded as an environment or according to the user's demand or the product specification requirements. One of the options.

In addition, in the embodiment of the physiological signal monitoring device 30A of FIG. 16, the detection module 310A and the monitoring module 320A of the physiological signal monitoring device 30A can be configured as a detachably coupled structure and an electrical coupling relationship. This makes it easy to maintain, repair, or to update or upgrade hardware or software. FIG. 21 and FIG. 22 are schematic diagrams showing a detachable embodiment of the detection module 310A and the monitoring module 320A of the physiological signal monitoring device 30A of FIG. As shown in FIG. 21, the detecting module 310A further includes a connecting housing 500. The connecting housing 500 includes a connecting portion 510 and a plurality of extending portions 521 and 522. As shown in FIG. 22, the housing 600 of the monitoring module 320A includes an upper cover 610, a side cover 601, and a lower cover 620.

As shown in FIG. 21, the connecting portion 510 is configured to at least partially or completely cover a periphery of the monitoring module 320A, and is detachably connected or coupled to the monitoring module 320A. For example, the connecting portion 510 has a ring structure for covering a side cover 601 around one of the casings 600 of the monitoring module 320A as shown in FIG. The plurality of first temperature detecting units 311 of the detecting module 310A are respectively disposed in the receiving spaces of the extending portions 521; the detecting module is configured to extend outwardly from the connecting portion 510; One of the second temperature detecting units 312 of the 310A is disposed in the accommodating space in the extending portion 522.

FIG. 23 is a schematic exploded view of an embodiment of the detection module 310A of FIG. 21. Referring to FIG. 17 , FIG. 21 and FIG. 23 , in an embodiment, the extension portion 521 corresponding to the first temperature detecting unit 311 has a first detecting opening 531 for the first temperature detecting unit. The engaging member 410 and the contact member 420 of the 311 extend from the accommodating space in the extending portion 521 to the outside of the first detecting opening 531.

Referring to FIG. 19, FIG. 21 and FIG. 23, in an embodiment, the extension portion 522 corresponding to the second temperature detecting unit 312 has a second detecting opening 532, and the second detecting opening 532 is configured to The temperature sensor 481 of the second temperature detecting unit 312 senses the temperature of the environment, for example, indirectly through the sensing member 480 or directly from the second detecting opening 532, wherein the first detecting opening 531 faces the inside. For the direction of temperature detection of the living body, the second detecting opening 532 faces the external direction for temperature detection of the environment. In addition, as shown in FIG. 19 and FIG. 23, a first detecting opening 531 may be defined under the extending portion 522 for engaging a joint member 410A protruding from the first detecting opening 531 with the connecting component 20, wherein The joint member 410A does not have a hole; however, this is an optional implementation, and the present invention is not limited thereto.

As shown in FIG. 21 and FIG. 23, the connecting portion 510 has a plurality of connecting openings 535, and the detecting module 310A further includes a plurality of connecting ends (such as 541 and 542), and the connecting ends are respectively disposed at: At least one of the connection opening 535 and the inner side of the connection portion 510, such as part or all of the connection ends, may be disposed on the inner side of the connection opening 535 or the connection portion 510. When the connection unit 510 is detachably connected to the monitoring module 320A, the monitoring module 320A is electrically coupled to the first temperature detecting unit 311 and the second temperature detecting unit 312 through the connecting ends. .

In addition, as shown in FIG. 23, the connection housing 500 can be implemented to include an upper housing portion 551 and a lower housing portion 552. Referring to FIGS. 21 and 23, the connection ends 541 and 542 of the detection module 310A are disposed on the inner side of the upper casing portion 551 (or may be regarded as the inner side of the connection portion 510). For example, the connection terminal 541 is used for temperature signal transmission and the connection terminal 542 is used for grounding. After the detection module 310A is detachably coupled to the monitoring module 320A, the connection ends 541 and 542 of the detection module 310A are electrically coupled to the connection end 631 of the monitoring module 320A of FIG. 22, respectively. 632, wherein the connecting ends 631, 632 can be disposed in the hole of the housing 600 such as the side cover 601 or the hole, or can be configured to protrude beyond the hole of the side cover 601. As shown in FIG. 23 , the output of the first temperature detecting unit 311 (or the second temperature detecting unit 312 ) is electrically coupled to the corresponding connecting end 541 by the conductive member 560 disposed near the connecting opening 535 . For example, the first temperature detecting unit 311 and the second temperature detecting unit 312 can be configured to have a common grounding point, and the grounding point is electrically coupled to the connecting end 542; A partition member 570 is disposed on the inner side of the upper casing portion 551 so that the conductive members 560, the connecting ends 541, 542, and the connecting wires for grounding do not interfere with each other, thereby effectively using the capacity provided by the connecting housing 500. The space is configured to enable the physiological signal monitoring device 30A to realize the detachable mechanical and electrical coupling of the detection module 310A and the monitoring module 320A in a small volume. However, the present invention is not limited by the implementation manner of the connection end in this example, and may be implemented in other manners; for example, the connection end may be provided at the connection opening 535, and the above mechanical and electrical coupling effects may also be achieved.

The embodiment of the physiological signal monitoring device as described above is detachably attached to the living body. Since the contact member is used to contact the living body, the contact signal can be used to detect the physiological signal of the user, thereby Users get a better experience. If applied to the physiological signal detection needs of infants, children or the elderly, the comfort of the physiological signal monitoring device is improved, and the user can obtain a better user experience when the physiological signal detection is required for a long time. .

The invention has been described above in terms of the preferred embodiments, and it should be understood by those skilled in the art that the present invention is not intended to limit the scope of the invention. It should be noted that variations and permutations equivalent to those of the embodiments are intended to be included within the scope of the present invention. Therefore, the scope of protection of the present invention is defined by the scope of the patent application.

1‧‧‧physical signal monitoring equipment

10, 10A‧‧‧ fixed department

11, 11A‧‧‧ wearable body

12, 12A‧‧‧Connected area

20, 20A‧‧‧Connecting components

21‧‧‧First connector

22‧‧‧Second connector

30, 30A‧‧‧ Physiological signal monitoring device

31, 31A‧‧‧ joints

32, 32A‧‧‧Contacts

90‧‧‧ terminal monitoring device

310, 310A‧‧‧Detection Module

311‧‧‧First temperature detection unit

312‧‧‧Second temperature detection unit

320, 320A‧‧‧ monitoring module

321‧‧‧displacement sensing unit

322‧‧‧Control unit

323‧‧‧Output unit

324‧‧‧Wireless transmission unit

325‧‧‧ memory unit

410, 410A‧‧‧ joints

411‧‧‧ hole

420‧‧‧Contacts

421‧‧‧First sub-contact

422‧‧‧Second sub-contact

430‧‧‧Flexible parts

440‧‧‧temperature sensor

450‧‧‧Signal line

480‧‧‧Sensors

481‧‧‧temperature sensor

500‧‧‧Connecting housing

510‧‧‧Connecting Department

521, 522‧‧‧ extensions

531‧‧‧First detection opening

532‧‧‧Second detection opening

535‧‧‧Connecting opening

551‧‧‧Upper casing

552‧‧‧ Lower housing

541, 542‧‧‧ connection

560‧‧‧Electrical parts

570‧‧‧Parts

600‧‧‧Monitoring module housing

601‧‧‧ side cover

610‧‧‧上盖

620‧‧‧Under the cover

631, 632‧‧‧ connection

BD‧‧ ‧ organisms

PT‧‧‧ position

1 is a schematic diagram of a physiological signal monitoring device according to an embodiment of the present invention. 2 is a schematic diagram of combining physiological signal monitoring devices in an embodiment of the present invention. FIG. 3 is a schematic view of a connecting component in a fixing portion according to an embodiment of the present invention. [Fig. 4] is a schematic view showing an embodiment of a connection assembly. [Fig. 5 to Fig. 6] are schematic views showing an embodiment in which the physiological signal monitoring device is detachably coupled to the fixed portion through the connecting member. Fig. 7 is a schematic view showing an embodiment in which a connecting member and a fixing portion are combined. [Fig. 8] is a schematic view showing another embodiment of a connection assembly. Fig. 9 is a schematic view showing another embodiment in which a physiological signal monitoring device is detachably coupled to a fixing portion through a connecting member. FIG. 10 is a block diagram showing an embodiment of a physiological signal monitoring device. [Fig. 11] is a block diagram showing the communication between the physiological signal monitoring device and the terminal monitoring device. Fig. 12 is a schematic view showing an embodiment of a joint member. Fig. 13 is a cross-sectional view showing the engaging member of Fig. 12. FIG. 14 is an exploded perspective view showing an embodiment of a first temperature detecting unit. FIG. 15 is a schematic cross-sectional view showing an embodiment of a first temperature detecting unit. Fig. 16 is a top perspective view showing an embodiment of a physiological signal monitoring device. Fig. 17 is a bottom view of the physiological signal monitoring device of Fig. 16. Fig. 18 is a front elevational view showing the physiological signal monitoring device of Fig. 16. Fig. 19 is a rear elevational view showing the physiological signal monitoring device of Fig. 16. 20 is a schematic view showing the combination of the physiological signal monitoring device of FIG. 16 and the connection assembly and the fixing portion. FIG. 21 is a schematic diagram of an embodiment of a detection module of the physiological signal monitoring device according to FIG. 16. FIG. 22 is a schematic diagram of an embodiment of a monitoring module according to the physiological signal monitoring device of FIG. 16 [FIG. 23] is a schematic diagram of disassembly of the detecting module of FIG. 21.

Claims (10)

A physiological signal monitoring device includes: at least one connecting component, the connecting component includes a first connecting body and a second connecting body, and the first connecting body and the second connecting system are combined or separated from each other a physiological signal monitoring device for detachably coupling with a fixing portion through the connecting component, and when the fixing portion is attached to a living body, the physiological signal monitoring device is configured to monitor at least a temperature change of the living body and The physiological signal monitoring device has: at least one engaging member and at least one contact member, wherein the first side of the engaging member is at least partially matched with the second connecting body of the connecting component, the contact member is elastically self-contained The opening of the first side of the engaging member is convex and used for temperature sensing; wherein the second connecting system of the connecting component is fixed to the outside of the connecting portion of the fixing portion to be combined with the first connecting body of the connecting component, The physiologic signal monitoring device is detachably coupled to the fixing portion by being detachably coupled to the connecting component through the engaging member, and is attached to the fixing portion When the object, the contact for the indirect or direct contact with a living body for temperature sensing. The physiological signal monitoring device of claim 1, wherein the first connection system of the connection component is fixed to the inner side of the connection portion of the fixing portion to be combined with the second connector of the connection component to allow the physiological signal The monitoring device is detachably coupled to the fixing portion through the connecting member, and when the fixing portion is attached to the living body, the contact member is used for indirect or direct contact with the living body for temperature sensing. . The physiological signal monitoring device according to claim 1 or 2, wherein a first side of the second connecting body of the connecting component is at least partially matched with the first side of the engaging member, and has a hole for the The contact is passed through and indirectly or directly in contact with the organism for temperature sensing. The physiological signal monitoring device of claim 1, wherein the physiological signal monitoring device comprises: a detecting module, configured to detachably couple with the fixing portion through the at least one connecting component and contact the living body The detection module includes: a first temperature detecting unit having the engaging member and the contact member for detecting the temperature of the living body toward the living body and outputting a first And a second temperature detecting unit for detecting a temperature of the surrounding environment and outputting a second temperature signal to the outside of the living body; a monitoring module coupled to the detecting module, Receiving at least the first temperature signal and the second temperature signal to monitor a temperature change of the living body, and monitoring a change in the displacement of the living body. The physiological signal monitoring device of claim 4, wherein the monitoring module comprises: a displacement sensing unit configured to detect a displacement change of the living body cavity activity and generate a displacement signal; a control unit, the electric Is coupled to the first temperature detecting unit, the second temperature detecting unit, the displacement sensing unit, and the output unit, wherein the control unit is measured according to the first temperature signal and the second temperature signal When the temperature of the living body meets a temperature warning condition, a temperature warning signal is issued, and when the control unit detects that the displacement change of the living body according to the displacement signal satisfies a displacement warning condition, a displacement warning signal is issued; The unit is electrically coupled to the control unit; a wireless transmission unit is electrically coupled to the control unit for wirelessly connecting a terminal monitoring device, and the temperature data is based on the first temperature signal and the second temperature signal And transmitting the displacement data to the terminal monitoring device according to the displacement signal. The physiological signal monitoring device of claim 4, wherein the first temperature detecting unit further comprises: a temperature sensor disposed in the contact for outputting the first temperature signal; Engaging a first end of the contact member such that a second end of the contact member projects from the opening of the first side of the engagement member. The physiological signal monitoring device of claim 4 or 6, wherein the detecting module further comprises: a connecting housing, having: a connecting portion for at least partially covering a periphery of the monitoring module and being detachable The grounding is connected to the monitoring module; and the plurality of extending portions extend outward from the connecting portion, and the first temperature detecting unit and the second temperature detecting unit are respectively disposed in the extending portions The accommodating space has a first detecting opening for the engaging portion and the contact member of the first temperature detecting unit from the accommodating space in the extending portion Extending beyond the first detection opening. The physiological signal monitoring device of claim 7, wherein the extension portion corresponding to the second temperature detecting unit has a second detecting opening, and the second detecting opening is configured to enable the second temperature detecting unit The temperature sensor senses the temperature of the environment indirectly or directly by the second detecting opening, wherein the first detecting opening faces inward for the temperature detecting direction of the living body, and the second detecting opening The outward direction is used for the direction of temperature detection of the environment. The physiological signal monitoring device of claim 7, wherein the connecting portion has a plurality of connecting openings on the inner side thereof, the detecting module further includes a plurality of connecting ends, wherein the connecting ends are respectively disposed at the connecting openings and the connecting At least one of the inner side of the portion is electrically connected to the first temperature detecting unit and the second temperature detecting unit through the connecting end when the connecting portion is detachably connected to the monitoring module Coupling. The physiological signal monitoring device of claim 1, wherein the physiological signal monitoring device further comprises the fixing portion, the fixing portion is for attaching to the living body, the fixing portion comprises a wearing body, and the connecting region is located in the wearing The wearing system of the fixing portion comprises a cleanable material, and the fixing portion can be separately cleaned when separated from the physiological signal monitoring device; the wearing system of the fixing portion is configured to be a cross strap or a devil felt The adhesive sheet is fixedly attached to the surface of the living body to allow the physiological signal monitoring device to be detachably coupled with the fixed portion to monitor temperature changes and displacement changes of the living body.