阅读说明：本技术 用于智能服装的信号处理装置、穿戴衣 (A signal processing device, dress clothing for intelligent clothing ) 是由 钟君 王丽荣 成贤锴 朱文亮 刘永峰 蔡黎明 周虹 于 2021-08-06 设计创作，主要内容包括：本发明提供用于智能服装的信号处理装置,包括：信号处理器；信号处理器设有若干信号触点；底座,包括安装座、基座；安装座、基座自服装的外层面料两侧相固定并夹持外层面料；安装座设有若干第一金属触点；第一金属触点与服装内的信号采集装置通过导线电性连接；信号处理器与安装座相卡接,并使得若干信号触点分别与若干第一金属触点接触导通。底座设计成相固定的安装座、基座的结构,便于固定于外层面料,无需在外层面料上开设相应的复杂装配结构。卡接固定便于信号处理器装配于服装表面；且信号处理器与底座固定牢固,不易产生晃动。安装座具有足够的区域设计多金属触点,配合服装内多个信号采集组件,实现多项生理参数的监测。(The invention provides a signal processing device for intelligent clothing, comprising: a signal processor; the signal processor is provided with a plurality of signal contacts; the base comprises a mounting seat and a base; the mounting seat and the base are fixed from two sides of the outer layer fabric of the garment and clamp the outer layer fabric; the mounting base is provided with a plurality of first metal contacts; the first metal contact is electrically connected with a signal acquisition device in the garment through a lead; the signal processor is clamped with the mounting base, and the signal contacts are respectively in contact conduction with the first metal contacts. The base is designed into a structure of the fixed mounting seat and the fixed base, so that the base is convenient to fix on the outer-layer fabric, and a corresponding complex assembly structure is not required to be arranged on the outer-layer fabric. The clamping fixation is convenient for the signal processor to be assembled on the surface of the garment; and the signal processor is firmly fixed with the base and is not easy to shake. The installation seat is provided with enough area design multi-metal contacts, and is matched with a plurality of signal acquisition assemblies in the garment to realize monitoring of a plurality of physiological parameters.)

1. Signal processing apparatus for smart apparel, comprising:

a signal processor (11) for receiving the human body bioelectric signal and converting it into a digital signal; the signal processor (11) is provided with a plurality of signal contacts (111);

a base (12) including a mounting seat (121) and a base (122); the mounting seat (121) and the base (122) are fixed from two sides of an outer layer fabric (41) of the garment and clamp the outer layer fabric (41); the mounting seat (121) is provided with a plurality of first metal contacts (1211); the first metal contact (1211) is electrically connected with a signal acquisition device in the garment through a lead (30);

the signal processor (11) is clamped with the mounting seat (121), and the signal contacts (111) are respectively in contact conduction with the first metal contacts (1211) to receive and process the human body bioelectricity signals sent by the signal acquisition device.

2. The signal processing device for the intelligent garment as claimed in claim 1, wherein first clamping grooves (112) are respectively formed in two sides of the signal processor (11), and the mounting seat (121) is provided with matched clamping protrusions (1212); the clamping protrusion (1212) is clamped into the first clamping groove (112) to realize clamping.

3. The signal processing device for intelligent clothing according to claim 1, wherein the front of the mounting seat (121) is provided with a cavity (1213), and the bottom of the signal processor (11) is provided with an elastic lock (113); when the signal processor (11) and the mounting seat (121) are clamped in place, the elastic locking piece (113) extends into the cavity (1213) to realize locking.

4. The signal processing device for the intelligent garment as claimed in any one of claims 1 to 3, wherein the front face of the mounting seat (121) is provided with a protruding part (1214); the projection (1214) comprises a wedge-shaped structure (12141) which is gradually narrowed along the clamping direction, and a mounting part (12142) which is arranged at the short end of the wedge-shaped structure (12141) and is in a platform structure; a second clamping groove (114) matched with the protruding part (1214) in shape is formed in the bottom of the signal processor (11); the first metal contact (1211) and the signal contact (111) are respectively arranged in the mounting part (12142) and the second card slot (114) region; the protrusion (1214) snaps into the second card slot (114) and presses the first metal contact (1211) against the mating signal contact (111).

5. Signal processing device for smart clothing as claimed in claim 4, characterized in that the angle between the upper and lower surfaces of the wedge-shaped structure (1214) is 4 ° -6 °.

6. The signal processing device for smart clothes according to any one of claims 1 to 3, further comprising an FPC board (13) disposed between the base (122) and the outer fabric (41); the FPC board (13) is provided with a plurality of second metal contacts (131); a plurality of second metal contacts (131) are respectively in contact conduction with a plurality of first metal contacts (1211); wherein the content of the first and second substances,

the FPC board (13) is electrically connected with a plurality of leads in the garment, so that the first metal contact (1211) is electrically connected with the leads.

7. The signal processing device for intelligent clothes according to claim 6, wherein a plurality of bonding pads are arranged on the back surface of the FPC board (13); the base (122) is provided with a plurality of cavities (1221) for containing conductive paint; wherein the content of the first and second substances,

the bonding pad, the conducting wire and the containing cavity (1221) are sequentially corresponding in position, and the conductive paint clamped by the bonding pad and the containing cavity (1221) is cured to be fixedly connected with the conducting wire.

8. The signal processing device for intelligent clothing according to claim 7, wherein a side wall of the cavity (1221) near the side end of the base (122) is provided with a notch (12211) for overflowing.

9. The signal processing device for smart clothing according to any one of claims 1 to 3, wherein the base (122) comprises a first base (122a), a second base (122 b); the first base (122a) and the second base (122b) are respectively fixed from two sides of an inner layer fabric (42) of the garment and clamp the inner layer fabric (42); the mounting seat (121) is fixed to the first base (122 a).

10. A wearable garment, comprising:

a body-wearable garment (40);

a plurality of signal acquisition components arranged on the garment (40) and a signal processing device for smart garments according to any one of claims 1 to 9; the signal acquisition assembly is electrically connected with the base (12) through a conducting wire so as to transmit the acquired human body bioelectricity signals to the signal processor (11) through the base (12).

Technical Field

The invention relates to the technical field of bioelectricity signal detection, in particular to a signal processing device for an intelligent garment and the intelligent garment.

Background

The intelligent garment is a research hotspot in recent years, and integrates a textile sensor into the garment by combining with the advanced technologies of the related fields of electronic information technology, sensor technology, textile science, material science and the like, so as to realize the monitoring of various physiological parameters of a human body. The method is mainly applied to the fields of human body health care, health management, disease prevention, sports training, fashion of scientific and technical clothing and the like.

At present, a signal processor on the intelligent clothes usually adopts buttons as mounting structures, the buttons are large in size and not suitable for connection of multiple contacts, and the signal processor is not convenient to mount and dismount.

Disclosure of Invention

In order to achieve the above object, the present invention is achieved by the following technical solutions.

The invention provides a signal processing device for intelligent clothing, comprising:

the signal processor is used for receiving the human body bioelectricity signal and converting the human body bioelectricity signal into a digital signal; the signal processor is provided with a plurality of signal contacts;

the base comprises a mounting seat and a base; the mounting seat and the base are fixed from two sides of the outer fabric of the garment and clamp the outer fabric; the mounting seat is provided with a plurality of first metal contacts; the first metal contact is electrically connected with a signal acquisition device in the garment through a lead;

the signal processor is clamped with the mounting seat, and makes a plurality of the signal contacts respectively contact and conduct with the plurality of the first metal contacts so as to receive and process the human body bioelectricity signals sent by the signal acquisition device.

Preferably, two sides of the signal processor are respectively provided with a first clamping groove, and the mounting seat is provided with matched clamping protrusions; the clamping protrusion is clamped into the first clamping groove to realize clamping.

Preferably, the front surface of the mounting seat is provided with a concave cavity, and the bottom of the signal processor is provided with an elastic locking piece; when the signal processor and the mounting seat are clamped in place, the elastic locking piece extends into the concave cavity to realize locking.

Preferably, the front surface of the mounting seat is provided with a convex part; the bulge comprises a wedge-shaped structure gradually narrowed along the clamping direction and an installation part which is arranged at the short end of the wedge-shaped structure and is of a platform structure; the bottom of the signal processor is provided with a second clamping groove matched with the shape of the protruding part; the first metal contact and the signal contact are respectively arranged in the mounting part and the second clamping groove area; the protruding portion is clamped into the second clamping groove, so that the first metal contact is pressed against the matched signal contact.

Preferably, the included angle of the upper surface and the lower surface of the wedge-shaped structure is 4-6 degrees.

Preferably, the fabric further comprises an FPC board arranged between the base and the outer layer fabric; the FPC board is provided with a plurality of second metal contacts; the plurality of second metal contacts are respectively in contact conduction with the plurality of first metal contacts; wherein the content of the first and second substances,

the FPC board is electrically connected with a plurality of conducting wires in the garment, so that the first metal contact is electrically connected with the conducting wires.

Preferably, the back surface of the FPC board is provided with a plurality of bonding pads; the base is provided with a plurality of cavities for containing conductive paint; wherein the content of the first and second substances,

the bonding pad, the conducting wire and the containing cavity are sequentially corresponding in position, and the bonding pad and the conducting paint clamped by the containing cavity are solidified to be fixedly connected with the conducting wire.

Preferably, a notch is formed in one side wall of the accommodating cavity close to the side end of the base and used for overflowing.

Preferably, the base comprises a first base and a second base; the first base and the second base are respectively fixed from two sides of an inner layer fabric of the garment and clamp the inner layer fabric; the mounting seat is fixed to the first base.

A second object of the present invention is to provide a wearable garment, comprising:

a body-wearable garment;

the signal acquisition components are arranged on the garment, and the signal processing device for the intelligent garment is arranged on the garment; the signal acquisition assembly is electrically connected with the base through a wire so as to transmit the acquired human body bioelectricity signals to the signal processor through the base.

Compared with the prior art, the invention has the beneficial effects that:

the invention provides a signal processing device for intelligent clothes, wherein a base is designed into a structure of a fixed mounting seat and a fixed base, so that the base is conveniently fixed on an outer-layer fabric, the assembly is convenient, a corresponding complex assembly structure is not required to be arranged on the outer-layer fabric, and the influence of the installation of the base on the strength of the fabric of the clothes is reduced. The signal processor is installed by clamping with the installation seat. On one hand, the signal processor is convenient to be assembled on the surface of the garment; on the other hand, the signal processor and the base are firmly fixed and are not easy to shake. In addition, the mounting seat has enough area for the design of many metal contacts to the monitoring of multinomial physiological parameter is realized to a plurality of signal acquisition subassemblies in the cooperation clothing.

In a preferred scheme, the mounting seat is provided with a convex part for mounting the first metal contact; the wedge-shaped structure of the bulge is matched with the profile of a second clamping groove of the signal processor, which is provided with a signal contact, and the bulge is clamped into the second clamping groove to enable the first metal contact to gradually compress the signal contact, so that the tightness of the connection of the two contact areas is improved.

In a preferred scheme, the base passes through FPC board and wire electric connection, need not the welding, need not the high temperature condition, applicable in the connection of metal conductor or elasticity nonmetal wire, and the many wires of being convenient for are stably gathered. Furthermore, the base is provided with a containing cavity, and a notch is formed in one side wall of the containing cavity close to the side end of the base, so that the excessive conductive paint overflows out of the base in the base assembling process, and the conductive paint is prevented from being accumulated in an assembling gap between the FPC board and the base to influence the electric connection between the FPC board and a lead.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood and to be implemented according to the content of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings. The detailed description of the present invention is given in detail by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

FIG. 1 is a schematic diagram of an exploded structure of a device body according to an embodiment of the present invention;

FIG. 2 is an exploded view of the assembly structure of the device body and the garment fabric layer according to another embodiment of the present invention;

FIG. 3 is an exploded view of the lead and first base assembly of the present invention;

FIG. 4 is a schematic perspective view of a signal processor according to the present invention;

FIG. 5 is an exploded view of a signal processor according to the present invention;

FIG. 6 is a schematic perspective view of the mounting base of the present invention;

FIG. 7 is a schematic perspective view of a device body according to an embodiment of the present invention;

FIG. 8 is a schematic diagram of the connection relationship between the signal acquisition assembly, the signal processing device and the wires according to the present invention;

FIG. 9 is a front view of the inner surface of a garment in accordance with an embodiment of the invention.

In the figure:

100. a wearing clothes body;

10. a device body; 11. a signal processor; 111. a signal contact; 112. a first card slot; 113. an elastic locking member; 114. a second card slot; 1141. a second mounting groove; 115. an indicator light window; 116. an anti-slip portion; 117. an opening; 118. a USB interface; 1101. a first case; 11011. buckling grooves; 1102. a second box body; 11021. a buckling part; 12. a base; 121. a mounting seat; 1211. a first metal contact; 1212. clamping the bulges; 1213. a concave cavity; 1214. a boss portion; 12141. a wedge-shaped structure; 12142. an installation part; 121421, a first mounting groove; 1215. a sidewall structure; 1216. a base plate; 1217. a first fixing hole; 1218. positioning the projection; 122. a base; 1221. a cavity; 12211. a notch; 1222. a second fixing hole; 1223. positioning holes; 122a, a first base; 122b, a second base; 13. an FPC board; 131. a second metal contact; 132. a second abdication gap;

20. an electrocardio-electrode;

30. a wire;

40. a garment; 41. an outer layer fabric; 411. a first abdication gap; 42. inner layer fabric;

50. a temperature sensor;

60. a respiration sensor.

Detailed Description

The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, which will enable those skilled in the art to practice the present invention with reference to the accompanying specification. In the drawings, the shape and size may be exaggerated for clarity, and the same reference numerals will be used throughout the drawings to designate the same or similar components. In the following description, terms such as center, thickness, height, length, front, back, rear, left, right, top, bottom, upper, lower, and the like are used based on the orientation or positional relationship shown in the drawings. In particular, "height" corresponds to the dimension from top to bottom, "width" corresponds to the dimension from left to right, and "depth" corresponds to the dimension from front to back. These relative terms are for convenience of description and are not generally intended to require a particular orientation. Terms concerning attachments, coupling and the like (e.g., "connected" and "attached") refer to a relationship wherein structures are secured or attached, either directly or indirectly, to one another through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise.

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that any combination of the embodiments or technical features described below can be used to form a new embodiment without conflict.

Example 1

The invention provides a signal processing device for intelligent clothes, as shown in fig. 1 and 4, comprising a device body 10, wherein the device body 10 comprises:

a signal processor 11 for receiving the human body bioelectric signal and converting it into a digital signal; the signal processor 11 is provided with a plurality of signal contacts 111;

a base 12 including a mounting seat 121 and a base 122; the mounting seat 121 and the base 122 are fixed from two sides of the outer layer fabric 41 of the garment 40 and clamp the outer layer fabric 41; the mounting seat 121 is provided with a plurality of first metal contacts 1211; the first metal contact 1211 is electrically connected with a signal acquisition device in the garment 40 through a lead 30;

the signal processor 11 is clamped with the mounting seat 121, and makes the plurality of signal contacts 111 respectively contact and conduct with the plurality of first metal contacts 1211 to receive and process the human body bioelectricity signals sent by the signal acquisition device.

Specifically, the mounting seat 121 and the base 122 are respectively mounted on two sides of the outer layer fabric 41, the mounting seat 121 and the base 122 can be fixed by fasteners, and the outer layer fabric 41 is provided with abdicating holes for assembling the abdicating fasteners. The base 12 is designed into the structures of the fixed mounting seat 121 and the fixed base 122, so that the base 12 is conveniently fixed on the outer fabric 41, the assembly is convenient, the corresponding complex assembly structure does not need to be arranged on the outer fabric 41, and the influence of the installation of the base 12 on the strength of the clothing fabric is reduced.

The signal processor 11 is mounted by its engagement with the mounting seat 121. On the one hand, the signal processor is convenient to be assembled on the surface of the garment 40; on the other hand, the signal processor 11 and the base 12 are firmly fixed and are not easy to shake. In addition, the mounting base 121 has sufficient area for multiple metal contact designs to cooperate with multiple signal acquisition components on the garment 40 to enable monitoring of multiple physiological parameters.

In an embodiment, the signal processor 11 further includes a main control module, a storage module, a bluetooth module, an AD module, and a power module. When the signal processor 11 and the base 12 are assembled in place, the signal contacts 111 are respectively in contact with the first metal contacts 1211 for conduction, the first metal contacts 1211 are electrically connected with the signal acquisition device on the garment 40 through the conducting wire 30, and the human body bioelectricity signals acquired by the signal acquisition device are transmitted to the AD module through the first metal contacts 1211 and the signal contacts 111 which are in conduction in sequence. Specifically, the AD module is electrically connected to the signal acquisition device on the garment 40 through the wire 30, and is configured to receive the human body bioelectrical signal acquired by the signal acquisition device on the garment 40, perform analog-to-digital conversion on the human body bioelectrical signal, and convert the human body bioelectrical signal into a digital signal. The main control module is electrically connected with the AD module, the storage module, the Bluetooth module and the power module respectively. The main control module is used for receiving the digital signals processed by the AD module and converting the digital signals into a data form required by a user through data analysis and operation. The storage module is used for storing data formed after the processing of the main control module. The Bluetooth module is connected with the remote intelligent terminal device through a wireless signal and used for sending data processed by the main control module to the remote intelligent terminal device. The power module is used for supplying power to other modules.

Further, the signal processor 11 further includes a nine-axis acceleration sensor or a three-axis acceleration sensor for acquiring different status information of the user at rest, walking, running, so as to analyze the human body bioelectrical signal according to different statuses.

In an embodiment, as shown in fig. 1, two sides of the signal processor 11 are respectively provided with a first clamping groove 112, and the mounting base 121 is provided with a matching clamping protrusion 1212; the clamping protrusion 1212 is clamped into the first clamping groove 112 to realize clamping. The first engaging groove 112 and the engaging protrusion 1212 are simple in structure and convenient to process, and the engaging assembly structure occupies a small space, thereby facilitating the miniaturization design of the device body 10.

In an embodiment, the signal processor 11 is a box structure, and a cavity for accommodating the main control module, the storage module, the bluetooth module, the AD module, the power module, the nine-axis acceleration sensor, or the three-axis acceleration sensor is disposed inside the box structure. The signal processor 11 has a simple structure, is small and portable, and has a large capacity. Furthermore, the outer surfaces of both sides of the signal processor 11 are concave to form the first card slot 112, so that the processing is simple and convenient. Further, the first card slot 112 is disposed near the bottom of the signal processor 11 to reduce the distance between the card-connecting protrusion 1212 and the bottom surface of the mounting seat 121, which is beneficial to the miniaturization design of the mounting seat 121.

Further, two sides of the mounting seat 121 extend toward the signal processor 11 to form two sidewall structures 1215, and the clamping protrusion 1212 is disposed on the sidewall structures 1215. Specifically, the mounting block 121 includes a bottom plate 1216, and both sides of the bottom plate 1216 extend toward the signal processor 11 to form two sidewall structures 1215. After the clamping protrusion 1212 is clamped into the corresponding first clamping groove 112, the inner surface of the sidewall 1215 abuts against the outer surface of the signal processor 11, so as to stabilize the clamping between the two.

Further, the first card slot 112 extends along the length direction of the signal processor 11, so as to increase the clamping area of the first card slot 112 and the clamping protrusion 1212, and increase the clamping firmness.

In one embodiment, the first metal contact 1211 is a metal pogo pin having a certain elasticity. Before the first metal contact 1211 is contacted and conducted with the signal contact 111, the first metal contact 1211 protrudes out of the front surface of the mounting seat 121, the first metal contact 1211 and the signal contact 111 are mutually pressed to realize contact and conduction, and when the first metal contact 1211 and the signal contact 111 are pressed to be mutually pressed, the first metal contact 1211 retracts, the exposed surface of the first metal contact 1211 is flush with the front surface of the mounting seat 121, so that the metal contact area of the mounting seat 121 and the signal processing area of the signal processor 11 are in surface-to-surface contact, the assembly gap is reduced, and the waterproofness is improved, so that the contact area is prevented from being short-circuited. It should be understood that the front surface of the mounting seat 121 represents a surface of the mounting seat 121 facing the signal processor 11, and the back surface of the mounting seat 121 represents a surface of the mounting seat 121 facing the outer layer fabric 41.

In one embodiment, as shown in fig. 1 and 4, the front surface of the mounting seat 121 is provided with a cavity 1213, and the bottom of the signal processor 11 is provided with an elastic locking piece 113; when the signal processor 11 and the mounting seat 121 are clamped in place, the elastic locking piece 113 extends into the cavity 1213 to achieve locking. The first card slot 112 is clamped with the clamping protrusion 1212 to limit the movement of the signal processor 11 away from or close to the base 12. The mutual friction force between the first card slot 112 and the clamping protrusion 1212 can limit the movement of the clamping protrusion 1212 separating from the first card slot 112 to a certain degree; in order to prevent the locking protrusion 1212 from being disengaged from the first locking groove 112 when the device body 10 is subjected to a large external force, the elastic locking member 113 extends into the cavity 1213 to limit the movement of the signal processor 11 along the extending direction of the first locking groove 112, so as to ensure that the signal processor 11 is firmly installed. In addition, when the signal processor 11 and the mounting seat 121 are in place, the elastic locking piece 113 emits mechanical sound when bouncing into the cavity 1213, which plays a role in prompting the installation in place, and the user can remove the assembly application force.

In one embodiment, as shown in fig. 1 and 4, the front surface of the mounting seat 121 is provided with a protruding portion 1214; the projection 1214 includes a wedge 12141 tapering in the direction of snap-fit, a mounting portion 12142 disposed at the lower end of the wedge 12141 and having a plateau configuration; the bottom of the signal processor 11 is provided with a second card slot 114 matched with the shape of the convex part 1214; the first metal contact 1211 and the signal contact 111 are respectively arranged in the mounting part 12142 and the second card slot 114 region; the protrusion 1214 is snapped into the second card slot 114 and presses the first metal contact 1211 against the mating signal contact 111. Specifically, the second card slot 114 matches the contour of the protrusion 1214, and the area of the second card slot 114 corresponding to the wedge-shaped structure 12141 narrows in the card-fitting direction. The mounting portion 12142 has a plurality of first mounting grooves 121421, and a first mounting groove 121421 is used to fix a first metal contact 1211, wherein the first metal contact 1211 protrudes from a surface of the first mounting groove 121421 facing the signal processor 11. The second card slot 114 is provided with a plurality of second mounting grooves 1141, and one of the second mounting grooves 1141 fixes one of the signal contacts 111. The wedge 12141 is designed to be gradually narrowed along the clamping direction, so that during the process of clamping the protrusion 1214 from the open end of the second card slot 114, the wedge 12141 is gradually pressed against the inner surface of the second card slot 114, and further the first metal contact 1211 and the signal contact 111 are gradually pressed against each other to achieve electrical conduction. Namely, through the design of the wedge-shaped structure 12141, the signal contact area of the signal processor 11 is tightly connected with the metal contact area of the base 12, so that the contact areas are not easy to be dislocated and loosened along with the movement of a user, and the wearable device is suitable for wearable devices.

Further, the angle between the upper and lower surfaces of wedge 12141 is 4 ° -6 °, such that protrusion 1214 engages the inner surface of second card slot 114 while facilitating engagement of protrusion 1214 with second card slot 114.

In one embodiment, as shown in fig. 2 and 3, the flexible printed circuit board further includes an FPC board 13 disposed between the base 122 and the outer fabric 41; the FPC board 13 is provided with a plurality of second metal contacts 131; a plurality of second metal contacts 131 are respectively in contact with a plurality of first metal contacts 1211; wherein the content of the first and second substances,

the FPC board 13 is electrically connected to a plurality of conductive wires in the garment 40, so that the first metal contacts 1211 are electrically connected to the conductive wires. The FPC board 13 is used for electrically connecting the wires in the garment 40 with the mounting seat 121, and the FPC board 13 is small in size, has good flexibility, can deform along with the bending of the garment and is not easy to break. Specifically, the outer layer 41 has a first relief notch 411 for allowing the first metal contact 1211 on the mounting seat 121 to contact and conduct with the second metal contact 131 on the FPC board 13.

Further, a plurality of bonding pads (not shown in the figure) are arranged on the back surface of the FPC board 13; the base 122 is provided with a plurality of cavities 1221 for containing conductive paint; wherein the content of the first and second substances,

the pad, the lead and the cavity 1221 are sequentially corresponding in position, and the pad and the conductive paint clamped by the cavity 1221 are cured to be fixedly connected with the lead. Specifically, when the mounting seat 121 and the base 122 are fixed from the outer side and the inner side of the outer layer fabric 41, respectively, the mounting seat 121 and the base 122 apply mechanical force to two surfaces of the FPC board 13, so that the FPC board is pressed against the base 122; the pad and the cavity 1221 are clamped together to form a space for containing conductive paint. The conductive wires 30 are pressed into the conductive paint by the bonding pads of the FPC board 13, and the conductive paint is cured to fix the conductive wires 30 and electrically connect the conductive wires 30 to the FPC board 13. The scheme that the FPC board 13 is matched with the conductive paint is adopted to fix the conducting wire 30, a welding scheme is replaced, high-temperature treatment is not needed, safety is achieved, and the processing difficulty is reduced. The fixing firmness of the lead 30 is improved by the mechanical force formed by fixing the conductive paint curing combination mounting seat 121 and the base 122; in addition, the wire 30 may be a metal wire or a flexible non-metal wire, and is not limited to the scheme of using a metal wire in the welding process. In addition, the FPC board 13 is small in size, the fixed connection of the plurality of wires 30 can be achieved according to the requirement of the clothes for signal acquisition, the wiring integration level is high, and the flexible circuit board is suitable for various flexible wearable devices.

Further, the conductive paint is conductive silver paint, the conductive silver paint starts to be cured after about 10 minutes at room temperature, and the conductive silver paint can be completely cured after standing for 22-26 hours.

In an embodiment, a sidewall of the cavity 1221 near the side end of the base 122 is provided with a notch 12211 for overflowing. When the mounting seat 121 and the base 122 are fixed together and press the FPC board 13 on the base 122, the conductive paint in the cavity 1221 overflows when the FPC board 13 is pressed, the notch 12211 is formed to form a conductive paint overflow port in the cavity 1221, so that the conductive paint overflows to the outside of the base 122, the conductive paint overflows to the inner region of the FPC board 13 to cause short circuit of electrical connection, and the plurality of wires 30 are stably and reliably gathered and then fixed on the back of the FPC board 13.

In one embodiment, as shown in fig. 1 and 6, the mounting seat 121 is provided with a plurality of first fixing holes 1217, the base 122 is provided with a plurality of second fixing holes 1222, and the fixing is achieved by fasteners passing through the first fixing holes 1217, the second fixing holes 1222 or the second fixing holes 1222, the first fixing holes 1217 in sequence; the FPC board 13 is provided with a plurality of second yield notches 132 for fixing the yield mounting seat 121 and the base 122 by fasteners. Further, in order to avoid the performance of the signal processor 11 being affected by the impact of the fastening member on the outer surface of the signal processor 11 during installation, the first fixing hole 1217 is a blind hole, the second fixing hole 1222 is a through hole, and the fastening member sequentially passes through the second fixing hole 1222 and the first fixing hole 1217 to be fixed.

Further, in order to reduce the assembly difficulty of the mounting seat 121 and the base 122, the mounting seat 121 is provided with a plurality of positioning protrusions 1218, and the base 122 is provided with a plurality of matching positioning holes 1223. When the mounting seat 121 and the base 122 are assembled, the positioning protrusions 1218 are aligned with the matching positioning holes 1223 and extend into the positioning holes, and then the fasteners pass through the second fixing holes 1222 and the first fixing holes 1217 to fix the mounting seat.

In one embodiment, as shown in fig. 2, the base 122 includes a first base 122a, a second base 122 b; the first base 122a and the second base 122b are respectively fixed from two sides of the inner fabric 42 of the garment 40 and clamp the inner fabric 42; the mounting seat 121 is fixed to the first base 122 a. Specifically, the garment 40 has at least two layers of fabric in order to accommodate the lead 30, signal acquisition device. Further, in order to save the cost of the garment and improve the comfort of the garment when it is applied to the skin, the garment 40 has two layers of fabric, namely an outer layer fabric 41 and an inner layer fabric 42. In order to facilitate the connection of the fastener of the mounting seat 121 and the base 122 and reduce the sliding of the inner layer fabric 42 relative to the base 122, the base 122 and the inner layer fabric 42 are fixed by arranging the first base 122a and the second base 122b, the first base 122a and the second base 122b are simple to assemble, and the fixing can be realized by matching the fastener with the corresponding fixing holes on the second base 122b, the first base 122a and the mounting seat 121. The inner layer fabric 42 only needs to be provided with holes through which the abdicating fasteners pass, and the processing procedure of the inner layer fabric 42 is simplified.

In one embodiment, the first base 122a and the second base 122b are identical in structure. In another embodiment, in order to reduce the manufacturing cost, the first base 122a and the second base 122b have different structures, the first base 122a has a plurality of cavities 1221 for accommodating conductive paint, and a side of the cavity 1221 near the side end of the first base 122a has a notch for flash. The second base 122b is a flat plate structure.

In one embodiment, the number of the contacts 111 of the signal processor 11 and the mounting base 121 is nine, and the contacts are arranged in an array; the first metal contact 1211 on the mounting base 121 corresponds to a path of signal acquisition information on the garment 40, and the first metal contact 1211 is in contact with the corresponding signal contact 111 and transmits the path of signal acquisition information to the signal processor 11. The signal processor 11 and the mounting seat 121 have simple structures, are convenient for arranging corresponding contact structures, and can increase the number of contacts of the device body 10 so as to be matched with the processing of a plurality of human body bioelectricity signals. Specifically, in an embodiment, as shown in fig. 8 and 9, the signal acquisition device provided on the garment 40 includes five electrocardiograph electrodes 20 for detecting electrocardiographic signals, a temperature sensor 50 for detecting the current body temperature, and a respiration sensor 60 for detecting respiration strain, wherein the respiration sensor 60 is in a band shape and is arranged between the two side fabrics; wherein, the two electrocardio-electrodes 20 arranged close to the chest are also used for detecting the impedance of the chest; the other three electrocardio-electrodes 20 are respectively arranged close to the left lower rib, the right lower abdomen and the left lower abdomen of the human body. The number of the leads 30 is nine, the number of the signal contacts 111 on the signal processor 11 is nine, and the number of the first metal contacts 1211 on the mounting seat 121 is nine, so that the device body 10 receives and processes the electrocardiosignals collected by the five electrocardioelectrodes 20, the temperature electric signals collected by the temperature sensor 50, the respiratory strain electric signals collected by the respiratory sensor 60 and the thoracic impedance electric signals collected by the two electrocardioelectrodes 20 close to the chest, and the monitoring of three-lead electrocardio, one-lead respiration and one-lead body temperature is realized; wherein the thoracic impedance multiplexes two electrodes in the three lead electrodes.

Further, nine contacts are arranged in a 3 × 3 array. That is, the nine signal contacts 111 and the nine first metal contacts 1211 are arranged in a 3 × 3 array, and the arrangement is compact, which is favorable for the miniaturization design of the device body 10. Further, the number of contacts may also be larger to access more channels of signals.

In an embodiment, a signal indicator lamp (not shown) is disposed in the signal processor 11, and the box body of the signal processor 11 is provided with an indicator lamp window 115, so that the signal indicator lamp can be viewed through the indicator lamp window 115, and the current working state of the signal processor 11 can be indicated through the signal indicator lamp. The current working state of the signal processor 11 includes a normal running state and an abnormal running state; the normal operation state comprises a Bluetooth connection state or a Bluetooth disconnection state; the abnormal operation state is a signal reading abnormal state, and comprises an electrocardio reading abnormal state, a body temperature reading abnormal state, a breath reading abnormal state or a data storage abnormal state. When the three-axis acceleration sensor or the nine-axis acceleration sensor is disposed in the signal processor 11, the abnormal operation state further includes an abnormal state read by the three-axis acceleration sensor or the nine-axis acceleration sensor.

In an embodiment, the signal processor 11 is provided with an inductive switch (not shown) for turning on or off the signal processor 11 according to the human body induction result, instead of a conventional mechanical switch, so as to simplify the structural design of the signal processor 11, facilitate the miniaturization design of the signal processor 11, and improve the waterproof performance.

In one embodiment, as shown in fig. 1, the signal processor 11 has an anti-slip portion 116 on the outer surface thereof for increasing the friction force between the signal processor 11 and the user contact portion, so as to facilitate the user to assemble and disassemble the signal processor 11 and the mounting seat 121. In addition, the anti-slip part 116 also assists the user to find the force application part during loading and unloading, so that the loading and unloading are convenient.

In one embodiment, as shown in fig. 5, the casing of the signal processor 11 is provided with an opening 117, and the opening 117 is provided with a USB interface 118 for data transmission or charging through a data line.

In an embodiment, as shown in fig. 5, the signal processor 11 is a box structure, and includes a first box 1101 and a second box 1102, where the first box 1101 and the second box 1102 are clamped together to form a cavity, and the cavity is used to accommodate a main control module, a memory module, a bluetooth module, an AD module, a power module, a nine-axis acceleration sensor or a three-axis acceleration sensor, so as to facilitate the assembly, disassembly, and replacement of each module.

Further, the first box 1101 and the second box 1102 are quickly assembled through the fastening slots and the fastening parts. Specifically, two sides of the first case 1101 are provided with a plurality of fastening slots 11011, two sides of the second case 1102 are provided with a plurality of fastening portions 11021, and the fastening slots 11011 are fastened with the fastening portions 11021, so as to realize the quick assembly and disassembly of the two cases.

In one embodiment, the device body 10 is rectangular or square, and the signal processor 11 and the base 12 are correspondingly rectangular to facilitate the engagement therebetween.

Example 2

The present invention provides a wearable garment, as shown in fig. 1 to 9, including a wearable garment body 100, the wearable garment body 100 including: a body-wearable garment 40;

a plurality of signal acquisition components arranged on the garment 40 and the signal processing device for the intelligent garment; the signal acquisition assembly is electrically connected with the base 12 through a conducting wire so as to transmit the acquired human body bioelectricity signals to the signal processor 11 through the base 12. The device body 10 has a simple and small structure and is easy to assemble, and a multi-contact structure can be arranged to meet the information transmission of a plurality of signal acquisition components of the garment 40.

The foregoing is merely a preferred embodiment of the invention and is not intended to limit the invention in any manner; those skilled in the art can readily practice the invention as shown and described in the drawings and detailed description herein; however, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the scope of the invention as defined by the appended claims; meanwhile, any changes, modifications, and evolutions of the equivalent changes of the above embodiments according to the actual techniques of the present invention are still within the protection scope of the technical solution of the present invention.