CN220938065U - Bioelectricity acquisition electrode fixing device and wearable equipment - Google Patents

Abstract

The utility model provides a bioelectricity acquisition electrode fixing device and wearable equipment, wherein the bioelectricity acquisition electrode fixing device comprises a wearable material layer, a flexible circuit board, a base and an electrode assembly; the flexible circuit board and the base are stacked, and the flexible circuit board, the base and the electrode assembly are fixed on the wearable material layer through conductive sewing threads; the flexible circuit board is provided with a conductive hole, and one surface of the flexible circuit board, which is close to the base, is provided with a conductive thimble electrically connected with the conductive hole; the base is provided with an interface module, and the conductive thimble penetrates out of the interface module; the conductive sewing thread passes through the conductive hole of the flexible circuit board to electrically connect the conductive hole with the electrode assembly. In the bioelectricity acquisition electrode fixing device, the flexible circuit board, the base and the wearable material layer are stably and electrically connected and fixed through the conductive sewing threads, so that the cost is saved, and meanwhile, the process difficulty is reduced.

Description

Bioelectricity acquisition electrode fixing device and wearable equipment

Technical Field

The utility model belongs to the technical field of wearable equipment, and particularly relates to a bioelectricity acquisition electrode fixing device and wearable equipment.

Background

The bioelectric signals which are common in clinic mainly comprise electrocardio, brain electricity, electromyogram, stomach electricity, retina electricity and the like, can be picked up and amplified by the electrodes and recorded into electrocardiograms, electroencephalograms, electromyograms, stomach electrograms, retina electrograms and the like, and provide clinical physiological monitoring and drug treatment. In the field of wearable technology, an electrode is often connected with a controller to form a bioelectric acquisition device, and the bioelectric acquisition device is fixed in a flexible wearable device, so how to ensure connectivity between the electrode and the controller is one of the main works of research and development. At present, a common means is to adhere and fix an electrode and a controller by using conductive adhesive or conductive foam, but the structure needs to be added with cured conductive adhesive in the production process, so that the production efficiency is reduced, and the structure is easy to cause the reduction of the bonding degree along with the increase of the washing times of flexible wearing equipment, so that the contact impedance is high, even the direct disconnection is caused, and signals cannot be normally acquired. Another common means is to connect the electrodes with the controller by using conductive metal buckles, but as the number of times of using buckles increases, the surface of the conductive metal buckles is severely worn, oxidation and contact are easy to occur, so that impedance increases and even circuit breaking are caused, the number of the conductive metal buckles needs to be matched with the number of the electrodes, and as the number of the electrodes increases, the number of the conductive metal buckles correspondingly increases, so that the volume of a product is increased, and the miniaturization and the weight reduction of the product are not facilitated.

Disclosure of utility model

The utility model aims to overcome the defects and shortcomings in the prior art and provide a bioelectricity acquisition electrode fixing device, wherein the flexible circuit board, the base and the wearable material layer are stably and electrically connected and fixed, so that the cost is saved and the process difficulty is reduced.

The utility model is realized by the following technical scheme:

A bioelectricity acquisition electrode fixing device comprises a wearable material layer, a flexible circuit board, a base and an electrode assembly; the flexible circuit board and the base are stacked, and the flexible circuit board, the base and the electrode assembly are fixed on the wearable material layer through conductive sewing threads; the flexible circuit board is provided with a conductive hole, and one surface of the flexible circuit board, which is close to the base, is provided with a conductive thimble electrically connected with the conductive hole; the base is provided with an interface module, and the conductive thimble penetrates out of the interface module; the conductive sewing thread passes through the conductive hole of the flexible circuit board to electrically connect the conductive hole with the electrode assembly.

In the bioelectricity acquisition electrode fixing device provided by the utility model, the flexible circuit board, the base and the electrode assembly are fixed on the wearable material layer through the conductive sewing thread, so that the fixed installation of the flexible circuit board and the base is realized, the conductive sewing thread has a fixed connection function, and also has the function of conducting the flexible circuit board, the electrode assembly and the fixed connection, so that the cost is saved, and the process difficulty is reduced; the interface module is used for being electrically connected with the controller, and the conductive thimble penetrates out of the circuit board to the base and is used for being connected with the controller.

Further, the electrode assembly includes an electrode and a conductive cloth electrically connected to the electrode; one end of the conductive sewing thread penetrates through the conductive hole to fix the flexible circuit board and the base on the wearable material layer, and the other end penetrates through the conductive cloth to fix the electrode assembly on the wearable material. The conductive sewing thread fixedly connects the conductive cloth with the flexible circuit board, and simultaneously enables the conductive cloth to be conducted with the flexible circuit board so as to conduct the electrode assembly with the flexible circuit board.

Furthermore, the electrode is made of conductive cloth, so that the conductive sewing thread can be conveniently penetrated into the electrode and sewn on the flexible circuit board.

Further, the electrode comprises a conductive cloth and a sponge layer, and the sponge layer is wrapped in the conductive cloth. The sponge layer is used for increasing the thickness of the electrode while not affecting conductivity and sewing technology, is more beneficial to contact between the electrode and a human body, and improves the quality of bioelectricity acquisition.

Further, a positioning hole is formed in the base at a position corresponding to the conductive hole, and the conductive sewing thread passes through the conductive hole and the positioning hole to fix the flexible circuit board and the base on the wearable material layer. The conductive sewing thread is positioned through the conductive hole and the positioning hole so as to ensure the sewing running line of the conductive sewing thread, and the conductive hole, the positioning hole and the wearable material layer are repeatedly wound in a shuttling way, so that the flexible circuit board and the base are fixed on the wearable material layer.

Further, the base is provided with a controller interface limiting mechanism. The controller interface limiting mechanism is used for limiting the controller interface so that the controller is connected with the interface module.

Further, the controller interface limiting mechanism comprises a limiting chute and a limiting hole. And limiting the movement direction of the controller during installation through the limiting sliding groove and the limiting hole so as to align the controller with the interface module.

Further, the limiting sliding groove comprises two side limiting strips protruding from the base, clamping portions extend out of the top ends of opposite sides of the two side limiting strips respectively, and the interface module is arranged close to one ends of the two side limiting strips. The side limit bars are connected with the controller in a matched mode through the clamping portions, the side faces of the controller are limited, and the controller moves to be connected with the interface module according to the extending direction of the side limit bars when the controller is installed.

Further, the controller interface limiting structure comprises at least two limiting holes, and at least two limiting holes are close to one ends, away from the interface module, of the two side limiting strips.

Further, the bioelectricity acquisition electrode fixing device further comprises a protective layer, wherein the protective layer covers the flexible circuit board, the base and the electrode assembly and is fixedly connected with the wearable material layer, and the electrode assembly is at least partially exposed from the protective layer. The protective layer is used for preventing the flexible circuit board from contacting with the skin and providing buffer protection to prevent the skin of a human body from being scratched by the conductive sewing thread and the flexible circuit board; the electrode assembly is at least partially exposed from the protective layer for contacting the skin of the human body to collect bioelectric signals of the human body.

The utility model also provides wearable equipment, which comprises a controller and the bioelectricity acquisition electrode fixing device; the controller is provided with a control interface, and the control interface is installed in a matched mode with the interface module and is electrically connected with the conductive thimble. In the wearable device, the flexible circuit board, the base and the electrode assembly of the bioelectricity acquisition electrode fixing device are fixed on the wearable material layer through the conductive sewing thread, and the controller is electrically connected with the flexible circuit board through the conductive thimble through the controller interface, so that the abrasion is small, and the service life is prolonged.

For a better understanding and implementation, the present utility model is described in detail below with reference to the drawings.

Drawings

Fig. 1 is a schematic structural view of a bioelectric collection electrode fixing device according to an embodiment.

Fig. 2 is a schematic structural view of a base of the bioelectric collection electrode fixing device according to an embodiment.

Fig. 3 is a schematic structural view of a flexible circuit board of a bioelectric collection electrode fixing device according to an embodiment.

Fig. 4 is a cross-sectional view of a flexible circuit board of a bioelectric collection electrode fixture of one embodiment.

Fig. 5 is a schematic diagram of stacking a flexible circuit board and a base of a bioelectrical collection electrode fixing apparatus according to an embodiment.

Fig. 6 is a cross-sectional view of a base of a bioelectric collection electrode fixture of an embodiment.

Fig. 7 is a schematic structural view of a controller of the bioelectric collection electrode fixing device according to an embodiment.

Fig. 8 is a bottom view of a controller of the bioelectrical collection electrode assembly of one embodiment.

Fig. 9 is a side view of a controller of a bioelectrical collection electrode assembly according to one embodiment.

Detailed Description

Embodiments of the present utility model will be described in further detail below with reference to the drawings and examples. It should be understood that the particular embodiments described herein are illustrative only and are not limiting of embodiments of the utility model. It should be further noted that, for convenience of description, only some, but not all of the structures related to the embodiments of the present utility model are shown in the drawings.

Furthermore, the terms first, second, third and the like in the description and in the claims, are used for descriptive purposes only and are not necessarily for describing relative importance or to indicate the number of features indicated or the order or timing of the description. The terms are interchangeable where appropriate. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature.

Similarly, the terms "fixed," "connected," and "connected" are used throughout the description and claims and should not be construed as limited to a direct connection. Thus, the expression "device a is connected to device B" should not be limited to devices or systems in which device a is directly connected to device B, meaning that there is a path between device a and device B, which may be a path that includes other devices or tools.

Example 1

Embodiment 1 provides a bioelectric collection electrode fixing device, fig. 1 is a schematic structural view of the bioelectric collection electrode fixing device of one embodiment, fig. 2 is a schematic structural view of a base of the bioelectric collection electrode fixing device of one embodiment, fig. 3 is a schematic structural view of a flexible circuit board of the bioelectric collection electrode fixing device of one embodiment, fig. 4 is a cross-sectional view of the flexible circuit board of the bioelectric collection electrode fixing device of one embodiment, and referring to fig. 1 to 4, the bioelectric collection electrode fixing device includes a wearable material layer 1, a flexible circuit board 2, a base 3 and an electrode assembly 4; the flexible circuit board 2 and the base 3 are arranged in a stacked manner, and the flexible circuit board 2, the base 3 and the electrode assembly 4 are fixed on the wearable material layer 1 through conductive sewing threads 5; the flexible circuit board 2 is provided with a conductive hole 21, and one surface of the flexible circuit board, which is close to the base 3, is provided with a conductive thimble 22 electrically connected with the conductive hole 21; the base 3 is provided with an interface module 6, and the conductive thimble 22 penetrates out of the interface module 6; the conductive sewing thread 5 passes through the conductive hole 21 of the flexible circuit board 2, electrically connecting the conductive hole 21 with the electrode assembly 4.

In the bioelectricity acquisition electrode fixing device provided in this embodiment 1, the flexible circuit board 2, the base 3 and the electrode assembly 4 are fixed on the wearable material layer 1 through the conductive sewing thread 5, so that the fixed installation of the flexible circuit board 2 and the base 3 is realized, and the conductive sewing thread 5 plays a role in fixedly connecting the flexible circuit board 2 with the electrode assembly 4 and in fixedly connecting the flexible circuit board 2 and the electrode assembly 4, so that the cost is saved, and the process difficulty is reduced; the interface module 6 is used for electrically connecting with the controller, and the conductive thimble 22 penetrates from the circuit board to the base 3 for connecting with the controller.

The wearable material 1 can be plastic, elastic cloth, inelastic cloth and the like, and can be applied to watches, clothes, glasses, ornaments and the like.

The conductive thimble 22 is used for being electrically connected with a control interface of the controller, a through hole 61 is arranged in the control interface in a penetrating way, and the conductive thimble 22 is arranged in the through hole 61 of the interface module 6 in a penetrating way in a telescopic way, so that the resistance when the conductive thimble 22 is connected with the control interface is reduced. The outside of the conductive thimble 22 is wrapped with a gold plating layer, which is beneficial to enhancing the oxidation resistance. The conductive thimble 22 is conducted with the conductive hole 21 on the flexible circuit board 2 through the printed wiring.

When the number of the electrode assemblies 4 is plural, the number of the conductive pins 22 and the number of the conductive holes 21 are the same as the number of the electrode assemblies 4.

Fig. 5 is a stacked schematic view of a flexible circuit board and a base of a bioelectrical collection electrode fixture of one embodiment, in one embodiment, referring to fig. 1-5, electrode assembly 4 includes an electrode 41 and a conductive cloth 42 electrically connected to electrode 41; one end of the conductive sewing thread 5 passes through the conductive hole 21 to fix the flexible circuit board 2 and the chassis 3 to the wearable material layer 1, and the other end passes through the conductive cloth 42 to fix the electrode assembly 4 to the wearable material. The conductive sewing thread 5 fixedly connects the conductive cloth 42 with the flexible circuit board 2, and simultaneously conducts the conductive cloth 42 with the flexible circuit board 2 to conduct the electrode assembly 4 with the flexible circuit board 2.

In one embodiment, the electrode 41 is an electrode 41 made of a conductive cloth 42, which is advantageous for connecting the conductive cloth 42 with the electrode 41 and for making the wearer feel comfortable when the electrode is arranged on a wearable material. Specifically, the electrode 41 and the conductive cloth 42 are made of the same conductive cloth 42 material, one end of the conductive cloth 42 is connected with the electrode 41, the other end of the conductive cloth 42 is connected with the conductive hole 21 and fixed by the conductive sewing thread 5, and the conductive sewing thread 5 is utilized to further enhance the electrical connection between the conductive cloth 42 and the conductive hole 21.

In one embodiment, the electrode 41 includes a conductive cloth 42 and a sponge layer (not shown) wrapped in the conductive cloth 42. The sponge layer is used for increasing the thickness of the electrode 41 while not affecting the conductivity and the sewing process, is more beneficial to the contact between the electrode 41 and a human body, and improves the quality of bioelectricity acquisition.

In one embodiment, as shown in fig. 1-3, a positioning hole 31 is formed in the base 3 corresponding to the position of the conductive hole 21, and the conductive sewing thread 5 passes through the conductive hole 21 and the positioning hole 31 to fix the flexible circuit board 2 and the base 3 on the wearable material layer 1. The conductive sewing thread 5 is positioned through the conductive hole 21 and the positioning hole 31 to ensure the sewing running of the conductive sewing thread 5, which is repeatedly shuttled and wound at the conductive hole 21, the positioning hole 31 and the wearable material layer 1, thereby fixing the flexible circuit board 2 and the chassis 3 to the wearable material layer 1.

Specifically, the conductive hole 21 is a long-strip slot provided with a conductive bonding pad, the positioning hole 31 is in a long-strip slot shape, the conductive sewing thread 5 is arranged in the conductive hole 21 and the positioning hole 31 in a penetrating manner, and by adjusting the widths of the conductive hole 21 and the positioning hole 31, automatic stitching can be realized, so that the production efficiency is improved. Since the conductive hole 21 is conducted with the electrode assembly 4 and the conductive pin 22 is conducted with the elongated slot provided with the conductive pad through the printed wiring, the conductivity between the conductive pin 22 and the electrode assembly 4 can be improved.

In one embodiment, as shown in fig. 1, the base 3 is provided with a controller interface limit mechanism 7. The controller interface limiting mechanism 7 is used for limiting the controller interface so that the controller is installed in place, is stably connected with the interface module 6 and is not easy to fall off.

Fig. 6 is a cross-sectional view of the base of an embodiment of the bioelectric collection electrode holder, and in one embodiment, as shown in fig. 1, 2 and 6, the controller interface limit mechanism 7 includes a limit chute 71 and a limit aperture 72. The movement direction of the controller during installation is limited by the limit chute 71 and the limit hole 72 so as to align with the interface module 6.

In one embodiment, as shown in fig. 1, 2 and 6, the limiting chute 71 includes two side limiting strips 711 protruding from the base 3, and opposite side top ends of the two side limiting strips 711 extend out of a clamping portion 712, and the interface module 6 is disposed adjacent to one end of the two side limiting strips 711. The side limit bars 711 are connected with the controller in a matching way through the clamping parts 712, limit the side surfaces of the controller, and enable the controller to move to be connected with the interface module 6 according to the extending direction of the side limit bars 711 during installation.

In one embodiment, as shown in fig. 1, 2 and 6, the controller interface limiting structure 7 includes at least two limiting holes 72, and the at least two limiting holes 72 are disposed adjacent to one end of the two side limiting bars 711 away from the interface module 6. The controller is provided with limit groove and spacing lug with limit 711 and spacing hole 72 complex, and when the installation controller, limit 711 is used for spacing the side of controller, and when the controller was installed in place under the restriction of limit 711, through the spacing lug cooperation installation that limit hole 72 and controller set up, make the stopper be fixed in current position, unable removal to make controller and interface module 6 stable connection.

In one embodiment, as shown in fig. 1, the bioelectric collection electrode fixing device further includes a protective layer 8, where the protective layer 8 covers the flexible circuit board 2, the base 3, and the electrode assembly 4, and is fixedly connected to the wearable material layer 1, and the electrode assembly 4 is at least partially exposed from the protective layer 8. The protective layer 8 is used for preventing the flexible circuit board 2 from contacting with the skin, and providing buffer protection to prevent the skin of a human body from being scratched by the conductive sewing thread 5 and the flexible circuit board 2; the electrode assembly 4 is at least partially exposed from the protective layer 8 for contact with the human skin to collect human bioelectric signals. The protective layer 8 may be provided on the wearable material 1 by sewing or printing, etc.

Example 2

Embodiment 2 provides a wearable device comprising a controller 9 and the bioelectrical collection electrode fixing apparatus of embodiment 1; the controller 9 is provided with a control interface which is matched with the interface module, and is electrically connected with the conductive thimble 22.

In the wearable device of this embodiment 2, the bioelectricity collection electrode fixing device flexible circuit board, the base and the electrode assembly are fixed on the wearable material layer through the conductive sewing thread, the controller 9 is electrically connected with the flexible circuit board through the conductive thimble 22 through the interface of the controller 9, the abrasion is small, and the service life is prolonged.

The wearable device may be one of a wristwatch, a glove, clothing, and smart glasses.

In the bioelectric collection electrode fixing device, a convex interface module is arranged on a base, fig. 7 is a schematic structural view of a controller of the bioelectric collection electrode fixing device according to an embodiment, fig. 8 is a bottom view of the controller of the bioelectric collection electrode fixing device according to an embodiment, and fig. 9 is a side view of the controller of the bioelectric collection electrode fixing device according to an embodiment. Referring to fig. 7-9, the end of the controller 9 is provided with a receiving groove 92, the control interface 91 is disposed in the receiving groove 92, and the groove is matched with the interface module, so that the control interface 91 is connected with the conductive thimble 22, and the electrode assembly and the controller 9 are conducted. Meanwhile, the controller 9 is provided with a matching limiting mechanism 93 matched with the controller interface limiting mechanism 7 of the bioelectricity acquisition electrode fixing device. In one embodiment, referring to fig. 2 and 6, the controller interface limiting mechanism 7 includes two side limit bars 711, the opposite side top ends of the two side limit bars 711 are provided with a clamping portion 712, the interface module is disposed at one end of the two side limit bars 711, and at least two limiting holes 72 are respectively disposed at one end of the two side limit bars 711 away from the interface module. Correspondingly, the controller 9 includes two side limit grooves 931 and two limit bumps 932, the two limit bumps 932 are disposed at the bottom of the controller and are respectively located at one ends of the two side limit grooves 931 away from the interface module, when the controller 9 is mounted on the base, the clamping portion 712 is clamped in the side limit groove 931, when the controller 9 moves to the position where the control interface is abutted with the conductive thimble 22 of the interface module, the limit bumps 932 are clamped in the limit holes 72, and the limit of the controller 9 is completed simultaneously by the clamping portion 712, the control interface and the limit holes 72, so that falling between the controller 9 and the base is prevented, and the control interface 91 of the controller 9 is stably connected with the interface module.

The present utility model is not limited to the above-described embodiments, but, if various modifications or variations of the present utility model are not departing from the spirit and scope of the present utility model, the present utility model is intended to include such modifications and variations as fall within the scope of the claims and the equivalents thereof.

Claims (11)

1. The utility model provides a bioelectricity collection electrode fixing device which characterized in that:

Comprises a wearable material layer, a flexible circuit board, a base and an electrode assembly;

the flexible circuit board, the base and the electrode assembly are fixed on the wearable material layer through conductive sewing threads;

The flexible circuit board is provided with a conductive hole, and one surface of the flexible circuit board, which is close to the base, is provided with a conductive thimble electrically connected with the conductive hole;

The base is provided with an interface module, and the conductive thimble penetrates out of the interface module;

the conductive sewing thread passes through the conductive hole of the flexible circuit board to electrically connect the conductive hole with the electrode assembly.

2. The bioelectric collection electrode fixing device according to claim 1, wherein:

The electrode assembly comprises an electrode and a conductive cloth electrically connected with the electrode; one end of the conductive sewing thread penetrates through the conductive hole to fix the flexible circuit board and the base on the wearable material layer, and the other end penetrates through the conductive cloth to fix the electrode assembly on the wearable material layer.

3. The bioelectric collection electrode fixing device according to claim 2, wherein:

the electrode is made of conductive cloth.

4. The bioelectric collection electrode fixing device according to claim 2, wherein:

The electrode comprises a conductive cloth and a sponge layer, and the sponge layer is wrapped in the conductive cloth.

5. The bioelectric collection electrode fixing device according to any one of claims 1 to 4, wherein:

And positioning holes are formed in positions, corresponding to the conductive holes, of the base, and the conductive sewing threads penetrate through the conductive holes and the positioning holes to fix the flexible circuit board and the base on the wearable material layer.

6. The bioelectric collection electrode fixing device according to any one of claims 1 to 4, wherein:

The base is provided with a controller interface limiting mechanism.

7. The bioelectric collection electrode fixing device according to claim 6, wherein:

The controller interface limiting mechanism comprises a limiting chute and a limiting hole.

8. The bioelectric collection electrode holder of claim 7, wherein:

The limiting sliding groove comprises two side limiting strips protruding from the base, clamping portions extend out of the top ends of opposite sides of the two side limiting strips respectively, and the interface module is arranged adjacent to one ends of the two side limiting strips.

9. The bioelectric collection electrode holder of claim 8, wherein:

The controller interface limiting structure comprises at least two limiting holes, and the at least two limiting holes are adjacent to one ends, away from the interface module, of the two side limiting strips.

10. The bioelectric collection electrode fixing device according to claim 1, wherein:

the electrode assembly is characterized by further comprising a protective layer, wherein the protective layer covers the flexible circuit board, the base and the electrode assembly and is fixedly connected with the wearable material layer, and the electrode assembly is at least partially exposed from the protective layer.

11. A wearable device, characterized by:

Comprising a controller and the bioelectrical collection electrode fixing apparatus according to any one of claims 1 to 10;

The controller is provided with a control interface, and the control interface is installed in a matched mode with the interface module and is electrically connected with the conductive thimble.