TWM514827U - Flexible physiological detection structure - Google Patents

Description

Elastic physiological detection structure

The present invention relates to an elastic physiological detecting structure, in particular, a combination design of a fabric, a body, an elastic member and a detecting module, so that the detecting module can be attached to the fabric by the elastic member. Increase the pressure on the surface of the body to enhance the adhesion of the detection module to the surface of the body. It is suitable for physiological detection clothing, tilt detection clothing, etc. or similar structures.

In recent years, under the development of science and technology, it has begun to develop a combination of detection modules and clothes to facilitate the detection and recording of the physiological state of the body, and is easy to apply to home health management or preventive medicine.

The current detection module and the clothes are mostly fixed, that is, the detection module is stitched to the required detection position (such as the chest), so that the detection module can contact the skin surface. In order to detect the physiological signals of the human body.

However, it is customary to use a fixed type of clothing in the clothing because it is easy to cause a signal to be detected when there is a signal that there is no signal at all, so that the measurement physiological signal cannot be continued, and must be repeated. Once, it is easy to increase the burden on the tester.

Therefore, in view of the above-mentioned deficiencies, the present author can propose an elastic physiological detection structure that enables the detection module to have improved performance of dynamic detection stability, so that the user can easily Operational assembly is a painstaking research and design system to provide user convenience and is the creative motive for the creators.

The main purpose of the present invention is to provide an elastic physiological detecting structure comprising a combination of a fabric, a body, an elastic member and a detecting module, the system being integrated on the inner layer of the fabric, and the body The upper system is provided with at least one opening, and the elastic member is coupled to one surface of the body, and the detecting module is coupled to the elastic member and exposed outside the opening of the body, thereby enabling the detecting The module can apply pressure to the surface of the body by the elastic member, so that the detecting module exposed outside the opening of the body can be closely attached to the surface of the body at the desired detection position to enhance the detection. The adhesion of the module to the surface of the body is measured, and the stability of the motion detection is improved, thereby increasing the overall practicality.

The second objective of the present invention is to provide an elastic physiological detecting structure, wherein the opening of the body has a certain length, and the elastic member has a reserved length, so that the detecting module can be used by the elastic member The reserved length is displaced at the opening of the body, so that the detecting module can move left and right at the opening of the body, so as to have the effect of changing the detecting position, and the physiological signal of different positions of the body can be detected. And the non-coupling design provides stability of the detection module, and improves the skin redness caused by prolonged compression at the same position or the body discomfort caused by prolonged compression. Increase the overall practicality.

Another object of the present invention is to provide an elastic physiological detecting structure by which the elastic member has an extension which extends to the suture of the fabric to enable bonding The flatness of the detecting module on the elastic member is exposed to the opening of the body, and the elastic member is used to bond the surface layer of the body, so that the detecting module exposed outside the opening of the body can be attached to It is necessary to detect the position of the skin, thereby increasing the overall utility.

For the above purposes, the elastic physiological detection structure of the present invention comprises: a fabric, a body, an elastic member and a detecting module, the system is integrated on the inner layer of the fabric, and the body is attached At least one opening is provided, and the elastic member is coupled to one side of the body, and the detecting module is coupled to the elastic member and exposed outside the opening of the body, so that the detecting module can borrow The pressure is increased by the elastic member.

The above and other objects and advantages of the present invention will become more apparent from the detailed description and the accompanying drawings.

Of course, the present invention is allowed to differ in some of the parts, or the arrangement of the parts, but the selected embodiments are described in detail in the present specification, and the construction thereof is shown in the drawings.

10‧‧‧ fabric

20‧‧‧ body

21‧‧‧ openings

30‧‧‧Flexible parts

31‧‧‧Snaps

32‧‧‧Reserved length

33‧‧‧Inelastic section

34‧‧‧Extension

40‧‧‧Detection module

401‧‧‧electrode

402‧‧‧Microcontroller

41‧‧‧Snap Department

50‧‧‧ slice

51‧‧‧ corresponding opening

60‧‧‧Signal transmission contacts

Fig. 1 is a perspective view showing the stereoscopic appearance of the first embodiment of the present invention.

FIG. 2 is a schematic diagram of the displacement operation of the detection module of the first embodiment of the present invention.

Figure 3 is a schematic perspective view of the second embodiment of the present invention.

Figure 4 is a schematic exploded view of the second embodiment of the present invention.

FIG. 5 is a schematic diagram of the displacement operation of the detection module of the second embodiment of the present invention.

Fig. 6 is a schematic view showing the inner surface of the opening of the second embodiment of the present invention.

Figure 7 is a schematic perspective view of the third embodiment of the present invention.

Figure 8 is a schematic view showing the extension of the elastic member of the fourth embodiment of the present invention combined with a single fabric stitch.

Figure 9 is a schematic view showing the extension of the elastic member of the fourth embodiment of the present invention combined with the stitches on both sides of the fabric.

Fig. 10 is a schematic view showing a winding of the elastic piece of the fourth embodiment of the present invention.

Figure 11 is a schematic view showing the inner surface of the opening of the fourth embodiment of the present invention combined with the inner surface of the fabric.

Figure 12 is a schematic view showing two sets of detecting modules on the elastic member of the fourth embodiment of the present invention.

Please refer to the figures 1 to 12, which are schematic diagrams of the present embodiment, and the best embodiment of the elastic physiological detection structure of the present invention is applied to detect changes in the physiological signal or body tilt angle of the body surface, and has an improvement. The effectiveness of the stability of the dynamic detection to enhance the adhesion to the surface of the body, thereby increasing the overall practicality.

The first embodiment of the present flexible physiological detection structure includes a fabric 10, a body 20, an elastic member 30, and a detecting module 40, which is coupled to the inner layer of the fabric 10, and The bonding system adopts any one of a stitching method, an ultrasonic method, a heat fusion method or an adhesive method, and the fabric 10 is any one of clothing, pants, gloves, underwear, vest, bra, and blouse ( Moreover, the fabric 10 of the present embodiment is exemplified by a large cloth that has not been sewn into the above-mentioned pants type. The body 20 is provided with at least one opening 21, wherein the opening 21 can be horizontal or straight (the embodiment is presented in a two-straight opening 21) (as shown in FIG. 1). ) and the The body 20 is a fabric, a fabric, a film, and the like (the embodiment of the present invention is represented by a cloth), and the film may be a plastic film, a metal film, or a carbon material. A diaphragm or the like or a diaphragm of other materials.

Furthermore, the elastic member 30 is coupled to one surface of the body 20, wherein the bonding system may be any one of a stitching method, an ultrasonic method, a heat fusion method or an adhesive method, or the elastic member 30. The two ends of the body and the body 20 are respectively provided with corresponding joints (such as buttons, buckles, devil felts, etc.) (and the present embodiment is presented by stitching). The detecting module 40 is coupled to the elastic member 30, wherein the detecting module 40 and the elastic member 30 are respectively provided with corresponding latching portions 31 and 41 (such as a concave and convex member, a male The female member...etc.) (please refer to FIG. 4), or directly fix the detecting module 40 to the elastic member 30 (such as suture method, ultrasonic method, heat fusion method or adhesive method). Any one of them). The detecting module 40 is exposed outside the opening 21 of the body 20 (in this embodiment, the elastic member 30 is passed through the two straight openings 21 of the body 20, and the detecting module 40 is allowed to be used. The detection module 40 has a contact surface, wherein the contact surface of the detection module 40 is used to contact the surface layer of the body to detect the physiology of the surface layer of the body. The detection module 40 can be used to press the elastic member 30 on the fabric 10 to apply pressure to the surface of the body, so that the detecting module 40 exposed outside the opening 21 of the body 20 can be closely attached. The body surface layer of the desired detection position is used to enhance the adhesion of the detection module 40 to the surface layer of the body.

The second embodiment of the present flexible physiological detection structure includes a fabric 10, a body 20, an elastic member 30, and a detecting module 40, which is coupled to the inner layer of the fabric 10, and The combination is stitched, ultrasonic, hot Any one of a fusion method or an adhesive method, and the fabric 10 is any one of clothes, pants, gloves, underwear, vest, bra, and blouse (and the fabric 10 of the embodiment is not yet sewed). Take the big cloth of the above-mentioned underwear type as an example). The body 20 is provided with at least one opening 21, wherein the opening 21 can be lateral or straight (the embodiment is represented by a lateral opening 21) (as shown in FIG. 3). And the body 20 is any one of a cloth, a fabric, a film, and the like (the embodiment of the present invention is represented by a cloth), and the film may be a plastic film or a metal film. Carbon-coated diaphragms or other membranes of other materials.

Furthermore, the elastic member 30 is coupled to one surface of the body 20, wherein the bonding system may be any one of a stitching method, an ultrasonic method, a heat fusion method or an adhesive method, or the elastic member 30. The two ends of the body and the body 20 are respectively provided with corresponding joints (such as buttons, buckles, devil felts, etc.) (and the present embodiment is presented by stitching). The detecting module 40 is coupled to the elastic member 30, wherein the detecting module 40 and the elastic member 30 are respectively provided with corresponding latching portions 31 and 41 (such as a concave and convex member, a male The female member (etc.) (as shown in Fig. 4), or the detection module 40 is directly fixed to the elastic member 30 (such as the suture method, the ultrasonic method, the thermal fusion method or the adhesive method). One). The detection module 40 is exposed outside the opening 21 of the body 20 (in this embodiment, the detection module 40 is exposed between a lateral opening 21), and the detection module 40 is The contact surface of the detection module 40 is used to contact the surface layer of the body to detect the physiological signal of the surface layer of the body, thereby enabling the detection module 40 to be attached to the fabric by the elastic member 30. 10 applies a pressure to the surface of the body to expose the detection module exposed outside the opening 21 of the body 20. The 40 can be attached to the surface of the body at the desired detection position to enhance the adhesion of the detection module 40 to the surface of the body.

In the first embodiment and the second embodiment of the present invention, the opening 21 of the body 20 has a certain length when implemented (this embodiment can be implemented in two straight directions) The opening member 21 has a predetermined length 32 (as shown in FIGS. 1 and 3), and the detecting module 40 has a contact surface. The contact surface of the detecting module 40 is used to contact the surface layer of the body to detect the physiological signal of the surface layer of the body, so that the detecting module 40 can be reserved by the elastic member 30 located inside the body 20. To perform the sliding movement (as shown in FIGS. 2 and 5), the detection module 40 can have the effect of generating a change detection position between the openings 21 of the body 20.

The third embodiment of the present flexible physiological detection structure includes a fabric 10, a body 20, an elastic member 30, and a detecting module 40. The implementation structure and the first embodiment and the second implementation In the same manner, the main difference is that the reserved length 32 of the elastic member 30 in the first embodiment and the second embodiment is provided with at least one inelastic segment 33 (as shown in FIG. 7), and the present embodiment The example is represented by the two straight-shaped openings 21 (not limited to the embodiment, and can also be implemented in a laterally-shaped opening 21), and the non-elastic segments 33 can also be respectively disposed on the elastic member 30. The two ends of the detecting module 40 are elastically coupled to the intermediate position on the elastic member 30. In addition, the non-elastic segment 33 may be woven together with the elastic member 30, or the non-elastic 33 segment may be combined with the elastic member 30 by a combination manner, and the bonding system may be stitched, ultrasonically, thermally fused or Adhesive method, etc.. The non-elastic section 33 provided at both ends of the detecting module 40 of the elastic member 30 can cause the detecting module 40 to slip.

The fourth embodiment of the present flexible physiological detection structure includes a fabric 10, a body 20, an elastic member 30, and a detecting module 40. The implementation structure and the first embodiment and the second implementation The main difference is the same as the third embodiment. The main difference is that the elastic member 30 of the first embodiment, the second embodiment and the third embodiment has an extension 34, and the extension 34 extends to The seam of the fabric 10 can be divided into a single side seam (as shown in Fig. 8), a joint stitch (as shown in Fig. 9), or a straight loop 34 around the fabric. 10 laps (as shown in FIG. 10), wherein the fabric 10 is any one of clothing, pants, gloves, underwear, vest, bra, and blouse, and the embodiment is a vest fabric 10 For example, the fabric 10 of the vest can be worn on the human body (and the illustration of the creation of the present invention folds the fabric 10 of the vest out of the inner inside for presentation), and forms a contact with the surface layer of the human body to make a combination. The body 20 on the fabric 10 of the vest can be in close contact with the human body The specific position of the layer, such as the chest, the chest, etc., and the detection module 40 exposed outside the opening 21 of the body 20 can be close to the surface layer of the human body, and the fabric 10 is woven by an elastic material or inelastic. Material weave. When the elastic member 30 has the extending portion 34, the flatness of the detecting module 40 coupled to the elastic member 30 is exposed to the opening 21 of the body 20, and is transmitted through the elastic member 30 to be bound to the surface of the body. The effect is that the detection module 40 exposed outside the opening 21 of the body 20 can be attached to the skin of the desired detection position, so that the contact effect with the surface layer of the body can be improved.

Furthermore, in the first embodiment, the second embodiment, the third embodiment, and the fourth embodiment of the present flexible physiological detection structure, the opening of the body 20 is 21 is implemented (and the present embodiment is represented by a lateral opening 21), and the inner surface of the opening 21 of the body 20 is bonded to a layer 50 (as shown in Fig. 6 or Fig. 11). The bonding system adopts any one of a stitching method, an ultrasonic method, a thermal fusion method or an adhesive method, and the opening 50 of the sheet 50 is provided with a corresponding opening 51 corresponding to the opening 21 of the body 20 so as to be located on the elastic member 30. The detecting module 40 can be exposed to the outside through the corresponding opening 51 of the layer 50 and the opening 21 of the body 20, and the layer 50 is made of plastic and cloth (the hardness can be obtained by processing, such as acrylic yarn). The woven fabric), the diaphragm (which may be a plastic material diaphragm, a metal material diaphragm, a carbon material diaphragm, etc. or other materials) may be used to increase the hardness of the opening 21 of the body 20, so that When the detecting module 40 is slid at the opening 21 of the body 20, the elastic member 30 is not easily pulled out of the opening 21 of the body 20, so as to prevent the detecting module 40 from being detached from the original sliding track and being unusable. .

In addition, the opening 21 of the body 20 can also be combined with two layers (not shown) on the inner surface of the opening 21 of the body 20. The bonding system is stitched, ultrasonic, thermally fused or bonded. And the two layers are respectively located on the left and right sides of the opening 21 of the body 20 to form a slit (not shown), so that the opening 21 of the body 20 corresponds to the slit, giving way The detecting module 40 on the elastic member 30 can be exposed to the outside through the slits of the two layers and the opening 21 of the body 20, and the two layers are made of plastic and cloth (the hardness can be obtained through processing) Any of the fabrics woven with acrylic yarn, the diaphragm (which may be a plastic diaphragm, a metal diaphragm, a carbon diaphragm, or the like) or the like to increase the opening of the body 20. The hardness of 21 is such that when the detecting module 40 is slid at the opening 21 of the body 20, The elastic member 30 is easily pulled out of the opening 21 of the body 20 to prevent the detecting module 40 from being detached from the original sliding track and being unusable.

In the first embodiment, the second embodiment, the third embodiment, and the fourth embodiment of the present invention, the first implementation of the detection module 40 is implemented. The image system may be an electrode sheet 401 (shown in FIG. 1, FIG. 3, FIG. 7 or FIG. 8) for detecting a physiological signal of the body surface, and the electrode sheet 401 is composed of a plurality of non-conductive fiber yarns. The wire and the plurality of conductive fiber yarns are woven, or the electrode sheet 401 is woven from a plurality of conductive fiber yarns, so that the entire electrode sheet 401 has a conductive effect, and the above electrode The plurality of conductive fiber yarns of the sheet 401 can be woven into a conductive area, and the conductive area of the electrode sheet 401 can be closely attached to the skin of the body, thereby facilitating detection of physiological signals, wherein the physiological signal can be body temperature, Heartbeat, pulse, breath, etc.

In the first embodiment, the second embodiment, the third embodiment, and the fourth embodiment of the present invention, the second implementation of the detection module 40 is implemented. The aspect system can be provided with a tilt sensing chip and a microcontroller 402 (as shown in FIG. 12), and the microcontroller 402 is connected to the tilt sensing chip to sense the tilt sensing chip change through the microcontroller 402. The tilt sensing chip is a Three Axis Low-g Micromachined Accelerometer, and the three-axis acceleration sensor calculates the tilt angle and acceleration of the three-axis X, Y, and Z values, and transmits the micro-control. The device 402 can detect and transmit at a time, and the tilt angle can be selected to be greater than +/- 1.0 degrees or +/- 1.5 degrees or +/- 2.0 degrees to determine whether there is a phenomenon of dizziness or falling, and the microcontroller 402 can The number of detections is determined by the number of detections, for example, the average detection value is greater than +/- 1.0 degrees (or +/- 1.5 degrees, +/- 2.0 degrees) within 30 seconds. It is set to be abnormally inclined. Or a nine-axis attitude sensor (not shown) is used. The nine-axis attitude sensor includes a three-axis acceleration sensor, a three-axis magnetic field sensor, and a three-axis gyro sensor, and the magnetic field range is ±1.3/1.9/ 2.5/4.0/4.7/5.6/8.1gauss, acceleration range: ±2g/±4g/±8g, gyroscope range: ±250/500/2000dps, through the above range value to monitor whether the attitude is abnormal, when the range value is exceeded That is, it is considered to be abnormally inclined. When the tilt or attitude change exceeds the set value, the microcontroller 402 can immediately transmit the signal through the wireless signal transmitter (not shown).

In the fourth embodiment of the present flexible physiological detection structure, the fabric 10 is provided with a signal transmission contact 60 (as shown in FIG. 12), and the signal transmission contact 60 is coupled with at least one Detector. The measurement module 40 is connected to enable the change of the physiological signal or the body tilt angle detected by the detection module 40 to be transmitted to the signal transmission contact 60, and the signal transmission contact 60 can be configured with a signal. a transmitter (not shown), and the signal transmitter is provided with a wireless transmission module for wirelessly transmitting changes in physiological signals or body tilt angles to electronic devices (eg, smart phones, smart tablets, On laptops, desktops, medical devices, etc., or in the cloud, it is easy to understand the results of detection, enabling early preventive care.

Furthermore, the first embodiment, the second embodiment, the third embodiment, and the fourth embodiment of the elastic physiological detection structure can be implemented through a fabric 10, a body 20, and a first embodiment. The combination of the elastic member 30 and the detection module 40 is coupled to the inner layer of the fabric 10, and the body 20 is provided with at least one opening 21, and the elastic member 30 is coupled to the body. On one side of the 20, the detecting module 40 is coupled to the elastic member 30 and exposed outside the opening 21 of the body 20, thereby enabling the detecting module 40 to be attached to the fabric by the elastic member 30. Increase on 10 Applying pressure to the surface of the body so that the detection module 40 exposed outside the opening 21 of the body 20 can be attached to the surface of the body at the desired detection position to enhance the adhesion of the detection module 40 to the surface of the body. Attached, with improved stability of motion detection.

The opening 21 of the body 20 has a certain length, and the elastic member 30 has a reserved length 32, so that the detecting module 40 can be reserved by the reserved length 32 of the elastic member 30. The opening 21 of the body 20 is displaced, so that the detecting module 40 can move left and right at the opening 21 of the body 20 to have the effect of changing the detection position, and is convenient for detecting physiological signals of different positions of the body, and The non-coupling design provides stability of the detection module 40, and improves the phenomenon that the detection module 40 is red and swollen due to prolonged compression at the same position or the body is uncomfortable due to prolonged compression.

From the above detailed description, it will be apparent to those skilled in the art that the present invention can achieve the aforementioned objectives, and has been in compliance with the provisions of the Patent Law, and has filed a patent application.

However, the above is only the preferred embodiment of the present invention, and the scope of the creation of the present invention cannot be limited by this; therefore, the simple equivalent changes and modifications made by the scope of the patent application and the content of the creation specification are All should remain within the scope of this creation patent.

10‧‧‧ fabric

20‧‧‧ body

21‧‧‧ openings

30‧‧‧Flexible parts

32‧‧‧Reserved length

34‧‧‧Extension

40‧‧‧Detection module

401‧‧‧electrode

Claims (14)

An elastic physiological detecting structure comprises: a fabric; a body, the system is coupled to the inner layer of the fabric, and the body is provided with at least one opening; an elastic member, the elastic member is coupled to the body And a detection module, the detection module is coupled to the elastic member, and the detection module is exposed outside the opening of the body, so that the detection module can be The elastic member increases the pressure. The elastic physiological detecting structure according to claim 1, wherein the opening of the body is further lateral or straight, and the system is further a cloth, a fabric, a film, and the like. The physiological detection structure of claim 1 or 2, wherein the inner surface of the opening of the body is further combined with a layer, and the layer is provided with a corresponding opening corresponding to the opening of the body, and the layer is further Further, it is any one of plastic, cloth, and diaphragm. The physiological detection structure according to claim 1 or 2, wherein the inner surface of the opening of the body further combines two layers, and the two layers are respectively located on the left and right sides of the opening of the body to form The slit is such that the opening of the body corresponds to the slit, and the layer is further a plastic, a cloth, a film or the like. The elastic physiological detecting structure according to claim 1, wherein the fabric is further a garment, a trousers, a glove, an underwear, a vest, a corset, a flat garment, and the like, and the fabric is woven with an elastic material. Or use a non-elastic material weaver. The elastic physiological detecting structure of claim 1, wherein the opening of the body further has a certain length, and the elastic member further has a reserved length, so that the detecting module can be elasticized The reserved length of the piece is displaced at the opening of the body. The elastic physiological detecting structure of claim 6, wherein the elastic member has a reserved length further provided with at least one non-elastic segment. The elastic physiological detection structure of claim 1, wherein the elastic member further has an extension extending to the suture of the fabric. The elastic physiological detection structure of claim 1, wherein the elastic member and the body are coupled to each other at a position of a corresponding joint between the two ends of the elastic member and the body. The elastic physiological detecting structure according to claim 1, wherein the bonding system further adopts any one of a suture method, an ultrasonic method, a heat fusion method or an adhesive method. The elastic physiological detection structure of the first aspect of the invention, wherein the detecting module and the elastic member are combined with the corresponding locking portion respectively on the detecting module and the elastic member. By. The elastic physiological detection structure of claim 1, wherein the combination of the detection module and the elastic member further fixes the detection module directly to the elastic member. The elastic physiological detection structure of claim 1, wherein the detection module is further provided with an electrode piece for detecting a physiological signal of the body surface, and the electrode piece is further connected to a signal transmission contact. . The elastic physiological detection structure of claim 1, wherein the detection module is further provided with a tilt sensing chip and a microcontroller, and the microcontroller is connected to the tilt sensing chip for micro control To sense the change in the tilt-aware chip.