CN116725268A

CN116725268A - Device base and intelligent clothing using same

Info

Publication number: CN116725268A
Application number: CN202210200953.7A
Authority: CN
Inventors: 范文松; 郑凯元; 杜志威; 廖珮雯; 姚明辉; 何宗祐
Original assignee: AMPAK TECHNOLOGY Inc
Current assignee: AMPAK TECHNOLOGY Inc
Priority date: 2022-03-03
Filing date: 2022-03-03
Publication date: 2023-09-12

Abstract

The invention relates to a device base and intelligent clothing using the same, wherein the device base comprises an upper shell and a lower shell, a circuit substrate is arranged between the upper shell and the lower shell, a metal contact piece on the top surface of the circuit substrate penetrates out of the upper shell to form a plurality of metal contact points, a flat cable interface on the bottom surface of the circuit substrate penetrates out of the lower shell, a flat cable groove is formed on the bottom surface of the lower shell towards each flat cable interface and used for guiding a transmission wire rod to be inserted into the flat cable interface along the flat cable grooves, the device base is combined on the clothing body by using a soft cushion sheet and is matched with a waterproof protection layer to avoid damage to the circuit components and the transmission wire rod when the electronic device is arranged on the device base, and the motion state of the device base can be monitored.

Description

Device base and intelligent clothing using same

Technical Field

The invention relates to a device base and intelligent clothing using the same, wherein the device base is a base capable of loading an electronic device for sensing or operation, is arranged on the intelligent clothing, and can be assembled on the device base during movement, so that the movement state can be monitored.

Background

In the busy environment of modern life, people face various huge pressures, and the problems of physiological and psychological health are indirectly caused, so that the concept of exercise and fitness becomes an important pipeline for relieving the pressure.

In order to achieve more effective exercise, a great number of professional athletes can use electronic exercise equipment in a matching manner during exercise, and the physiological state during exercise is recorded, so that modern scientific exercise is provided, the exercise efficiency is improved, and the physical condition of the athletes is further known.

For convenience, many industries have developed products incorporating sensing devices into clothing in recent years, in which wires are suspended directly from the clothing, but this can prevent the wearer from moving and comfort, in addition to being inconvenient to wear. Some products use rivet buckles to directly mount and buckle the sensing device on cloth and then carry out stay wire and fixation, however, the method is very difficult to process and mass production, and once the sensing device on the whole garment cannot be continuously used and must be scrapped due to damage of one part caused by pulling, the whole garment is very environmentally-friendly.

In addition, since this type of product is used in a lot more than during exercise, cleaning after exercise is necessary. If the sensing device and the wires thereof are directly fastened on the cloth, even if some of the sensing device and the wires thereof are subjected to waterproof treatment, the sensing device is still easy to damage or destroy in the cleaning process. The price of the intelligent clothing cannot be reduced due to the high manufacturing cost of the sensing device. This can lead to significant purchase conflict for the user due to the inability to last long and expensive service life, and can also become difficult to popularize for such products. Therefore, there is a need for a more environmentally friendly and economical design that allows smart apparel to better meet the needs of users.

Disclosure of Invention

The invention aims to provide a device base and intelligent clothing using the same, which are simple in structure and convenient to operate, wherein the device base is a base capable of loading an electronic device for sensing or operation, is arranged on the intelligent clothing, and can be assembled on the device base during movement, so that movement state monitoring can be performed.

In order to achieve the above object, the present invention discloses a device base electrically connected to an electronic device having a plurality of metal external contacts on a lower surface, wherein the device base comprises:

the electronic device is fixed in a range surrounded by the positioning side wall through the first positioning structure, the position of the first through hole corresponds to the position of a metal external contact point of the electronic device, and a concave positioning part is arranged at the periphery of the bottom surface of the upper shell;

the circuit substrate is provided with a plurality of metal contact pieces in a penetrating way, the top surface of the circuit substrate is attached below the upper shell, the metal contact pieces penetrate into the first through holes to form a plurality of metal contact points, the metal contact points are contacted with the metal external contact points, and a plurality of flat cable interfaces are arranged on the bottom surface of the circuit substrate; and

the circuit board comprises an upper shell, a lower shell, a plurality of first flat cable connectors and a plurality of second through holes, wherein the periphery of the top surface of the upper shell is provided with at least one first convex positioning part, the first convex positioning parts are positioned in the concave positioning parts so as to enable the upper shell to be combined with the lower shell, the circuit board is wrapped between the upper shell and the lower shell, the surface of the lower shell is provided with a plurality of second through holes corresponding to the positions of the flat cable connectors so as to enable the flat cable connectors of the circuit board to penetrate out of the second through holes, and the bottom surface of the lower shell is inwards concave from the edge of the bottom surface of the lower shell to form a first flat cable groove so as to enable a connecting joint at any end of a transmission wire to be inserted into the flat cable connectors in the second through holes along the first flat cable groove.

The upper shell or the lower shell is externally extended and surrounded by a soft gasket, a second flat cable groove is concavely formed on the bottom surface of the soft gasket towards the first flat cable groove, and the inclination of the second flat cable groove is the same as that of the first flat cable groove, so that the second flat cable groove and the first flat cable groove extend out of a continuously extending plane.

The electronic device is a sensing device, a stimulation device, a processing operation device or a combination thereof.

The transmission wire is a flexible elastic belt body, and a plurality of wavy or zigzag metal wires are distributed in the flexible elastic belt body, wherein the metal wires are connected to the adapter.

The adapter at one end of the transmission wire is connected with the flat cable interface, and the adapter at the other end of the transmission wire is connected with the flat cable interface of the base of another device, the flat cable interface of a battery device or the flat cable interface of an electrode patch.

The soft pad comprises a second convex positioning part and a combined hole, wherein the second convex positioning part and the first convex positioning part are combined in the concave positioning part, and the lower shell is tightly adhered in the combined hole, so that the periphery of the lower shell extends outwards to form the soft pad.

Wherein, the periphery of the upper shell extends outwards and is provided with a soft gasket in a surrounding way.

The utility model also discloses an intelligent dress of application device base, its characterized in that contains:

at least one device mount as described above;

the device comprises a surface fabric layer, a soft cushion piece, a circuit board and a circuit board, wherein the surface fabric layer is provided with at least one opening, the device base passes through the opening, the soft cushion piece is attached to the inner surface of the surface fabric layer, the upper shell is exposed out of the surface fabric layer, and a flat cable interface of the circuit board faces the inner side of the surface fabric layer; and

at least one transmission wire, a joint at either end of the transmission wire is inserted into the flat cable interface in the second through hole along the second flat cable groove and the first flat cable groove, the transmission wire is extended and laid from the inner surface of the surface layer towards any direction, and the inner surface of the surface layer is combined with a waterproof protection layer to cover the bottom surface of the lower shell and the extension range of the transmission wire upwards.

Wherein the battery device further comprises at least one battery device with a flat cable interface or/and at least one electrode patch with a flat cable interface, and the transmission wire extends from the inner surface of the surface layer to be connected to the flat cable interface of the other device base, the flat cable interface of the battery device or the flat cable interface of the electrode patch.

Wherein, a waterproof surface layer is further laid on the upper surface of the transmission wire, and the waterproof protection layer is fixedly attached to the inner surface of the surface layer in an adhesive or stitching mode.

Therefore, the technical scheme of the invention provides the base on which the electronic device with the sensing function, the stimulation function or the operation function is arranged, the base is combined on the clothes, and the bases on the clothes can be electrically connected in series through the special structure of the waterproof and transmission wires. Therefore, when there is a movement requirement, the electronic device is only required to be placed on the base, and signals can be transmitted to the electronic devices on other bases so as to monitor and calculate the movement state. When the electronic device is required to be cleaned, the electronic device can be pulled out for cleaning so as to avoid damage or destruction of the expensive electronic device, and the base and the transmission wire rod are subjected to waterproof treatment, so that the electronic device can resist cleaning for a certain number of times, and the clothing and the base are low in manufacturing cost, even if damaged due to cleaning, a consumer can buy a piece of replacement for use as a consumable, so that the electronic device is an optimal solution.

Drawings

Fig. 1A is a side plan view of a first embodiment of a base of the device of the present invention in an exploded configuration.

Fig. 1B is a side view in elevation of a first embodiment of a base exploded construction of a base of the device of the present invention.

FIG. 1C is a schematic sectional view showing a first embodiment of a base assembly of the device of the present invention.

Fig. 1D is a schematic perspective view showing a first embodiment of a base assembly of the device of the present invention.

Fig. 2 is a schematic diagram of a transmission wire structure of a base of the apparatus of the present invention.

Fig. 3A is a side plan view of a base exploded construction of a second embodiment of the base of the device of the present invention.

Fig. 3B is a side view in elevation of a second embodiment of a base exploded construction of a base of the device of the present invention.

FIG. 3C is a schematic sectional view of a second embodiment of a base assembly of the device of the present invention.

Fig. 3D is a schematic perspective view of a base assembly of a second embodiment of the base of the device of the present invention.

Fig. 4A is a side plan view of an exploded construction of a third embodiment of a base for a device of the present invention.

Fig. 4B is a side view in elevation of a third embodiment of a base exploded construction of a base of the device of the present invention.

Fig. 4C is a schematic sectional view of a third embodiment of a base assembly of the device of the present invention.

Fig. 4D is a schematic perspective view of a third embodiment of a base assembly of the device of the present invention.

FIG. 5A is a schematic cross-sectional view of a combination of a base and a garment body of the apparatus of the present invention.

FIG. 5B is a schematic view of the interior surface of the smart garment of the present invention.

Fig. 5C is a schematic view of the exterior surface of the intelligent garment of the present invention when installed in an electronic device.

Detailed Description

Other aspects, features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments, which is to be read in connection with the accompanying drawings.

As used herein, the articles "a," "an," and "any" refer to grammars of one or more (i.e., at least one) articles. For example, "a component" means one component or more than one component.

As used herein, the term "disposed" describing a combination of structures generally refers to a plurality of structures that are not easily separated or dropped after combination, and may be fixedly connected, detachably connected, integrally connected, mechanically connected, electrically connected, or directly physically connected, or indirectly connected through an intermediate medium, for example: using threads, tenons, fasteners, nails, adhesives or any combination of high frequency. As used herein, "opening" refers broadly to forming an aperture at a location by drilling, integrally forming, molding, 3D printing, and the like.

As used herein, the terms "protruding," "recessed," "threading," "forming," or "extending" describing a relationship of a combination of structures generally refer to one or more structures being joined together as one body or corresponding structures on the same body due to different locations, shapes, and functions.

As used herein, the terms "inside" and "inside" describing a structural location refer to a location near the center of the structural body, or where not exposed in use; the term "inwardly" refers to toward a central location near the structural body, or toward a location that is not exposed in use; the terms "outboard" and "external" refer to a position away from the center of the structural body, or where exposed above is used; the term "outwardly" refers to a position that is either toward a center away from the structural body or toward an exposed position in use.

As used herein, the term "upper" describing the location of a structure refers to any surface location of the structure and is not colloquially referred to as "above" or "over" having directionality. The terms "above" and "below" used to describe a structural position refer to the orientation of the structural position as conventionally used.

Device base of embodiment one:

the device base of the first embodiment of the invention can be used for being arranged on clothes to form the intelligent clothes of the second embodiment, and the device base can be combined with an electronic device to provide operation control for measuring electrocardio or myoelectric signals, stimulating muscles or other monitoring or measuring when a user moves. The electronic device may be a sensing device, a stimulating device, a processing device or a combination thereof, and is packaged as an integrated device according to the requirements of the designer and manufacturer.

In a first embodiment, the electronic device may be an encapsulated combination device (EMS-IMU) of a muscle electrostimulator (Electrical Muscle Stimulation, EMS) and an inertial sensing unit (Inertial Measurement Unit, IMU), providing muscle electrostimulation and sensing the motion of the limb. In a second embodiment, the electronic device may be an Electromyography (EMG) and inertial sensing unit package assembly (EMG-IMU) while providing Electromyography and limb motion sensing. In the third embodiment, the electronic device may be an arithmetic control device. The device base can be adjusted according to the size of the electronic device, the positions and the number of the electrical contact points, and the connection requirements of the electronic device and other devices, but the overall design concept is the same, so the following description is incorporated. Only the first description of the device will show the three aspects of the reference numerals, and the reference numerals of the first embodiment will be used as representative in the following. The different parts are denoted by reference numerals in different aspects and are described separately.

Referring to the first embodiment of fig. 1A-1D, the second embodiment of fig. 3A-3D, and the third embodiment of fig. 4A-4D, since the electronic devices 1,4,6 are packaged as one unit, a plurality of metal external contacts 12,42,62 connected to the external communication are disposed on the lower surface 13,43,63 of the electronic device, and a plurality of second positioning structures 11,41,61 (and/or 61') are disposed on the side of the electronic device. The number and location of the metal contacts 12 depends on the terminals connected to the internal circuit design of the electronic device 1. The device bases 2,5,7 of the first embodiment of the present invention are electrically connected to the electronic devices 1,4,6, respectively. The device base 2 can transmit or receive signals generated by the electronic device 1 to the electronic device 1.

The device base 2,5,7 comprises: an upper housing 21,51,71, a circuit substrate 22,52,72, and a lower housing 23,53,73. The device chassis 2,5,7 further comprises a cushion 24,54,74. The upper housing 21,51,71 includes a plurality of first perforations 211,511,711, a positioning sidewall 212,512,712, a first positioning structure 213,513,713, and a concave positioning portion 214,514,714. The circuit substrate 22,52,72 has a top surface 221,521,721 and a bottom surface 222,522,722, and includes a flat cable interface 2221,5221,7221 and metal contacts 223,523,723. The lower housing 23,53,73 includes a first male positioning portion 231,531,731, a second through hole 232,532,732, and a first flat cable groove 233,533,733. The soft spacer 24,54,74 includes a second male retainer 241,541,741, a combination opening 242,542,742, and a second flat cable groove 243,543,743. The flat cable interface 2221,5221,7221 interfaces with the adapter connector 31, 31', 31 ".

The surface of the upper housing 21 is provided with a plurality of first through holes 211, and the number of the first through holes 211 is at least equal to the number of the metal external contacts 12 of the electronic device 1, so that each metal external contact 12 of the electronic device 1 can correspond to one first through hole 211. At least one positioning sidewall 212 is formed at the edge of the upper housing 21 by extending upwards, at least one first positioning structure 213 is disposed around the positioning sidewall 212, and the electronic device 1 is disposed within a range surrounded by the positioning sidewall 212, and is fastened with the second positioning structure 11 of the electronic device 1 through the first positioning structure 213, so as to fix the electronic device 1 on the surface of the upper housing 21 (the positioning structure 11,213 is a corresponding rotating fastening structure, and thus can be fastened and fixed by rotating).

The circuit substrate 22 is provided with a plurality of metal contacts 223 (e.g. conductive copper pillars) in a penetrating manner, and the top surface 221 of the circuit substrate 22 is attached below the upper housing 21, so that at least one annular concave positioning portion 214 is formed between the circuit substrate 22 and the side wall of the bottom periphery of the upper housing 21. The metal contact 223 of the circuit substrate 22 penetrates through the first through hole 211 of the upper housing 21 to form a plurality of metal contacts for making contact with the metal external contacts 12 of the electronic device 1 for electrical connection, and the bottom surface 222 of the circuit substrate 22 protrudes with a plurality of flat cable interfaces 2221 including, but not limited to, a flexible flat cable connector (flexible printed circuit connector).

At least one first convex positioning portion 231 is disposed at the top periphery of the lower housing 23, and the first convex positioning portion 231 is combined with and positioned in the concave positioning portion 214 of the upper housing 21, so as to cover the circuit substrate 22 between the upper housing 21 and the lower housing 23. One or more second through holes 232 corresponding to the positions of the flat cable ports 2221 are formed on the surface of the lower housing 23, so that the flat cable ports 2221 of the circuit substrate 22 pass through the second through holes 232, and the bottom surface of the lower housing 23 is concaved inward from the edge to the second through holes 232 to form a first flat cable groove 233, so that a connection terminal 31 at either end of a transmission wire is inserted into the flat cable ports 2221 in the second through holes 232 along the first flat cable groove. The lower housing may further include a fool-proof structure 534 to allow the upper housing to be properly coupled to the lower housing.

The periphery of the upper housing 21 or the lower housing 23 may further extend outwards to surround a soft pad 24, such that a combination opening 242 is formed in the center of the soft pad 24 to expose the bottom surface of the lower housing 23 and the flat cable interface 2221 in the second through hole 232, and the soft pad 24 may be used as a combination component of the device base 2 and the smart garment, for example, to adhere the soft pad 24 to the smart garment. The bottom surface of the cushion sheet 24 is concave toward the first flat cable groove 233 to form a second flat cable groove 243, and the slope of the second flat cable groove 243 is the same as that of the first flat cable groove 233, so that the second flat cable groove 243 and the first flat cable groove 233 extend out of a continuous plane, so that the adapter 31 is smoothly inserted into the flat cable port 2221 in the second through hole 232 along the first flat cable groove 233 and the second flat cable groove 243, and the adapter 31 is disposed in the first flat cable groove 233, so that the subsequent smart clothes manufacturing process is not affected by the protrusion, and the transmission wire is not easily damaged.

As shown in fig. 2, the transmission wire 3 is a flexible elastic belt body 33 with a plurality of wavy or zigzag metal wires 32 disposed therein, and the metal wires 32 are connected to the adaptor 31, and the adaptor 31 of the embodiment of the invention uses a flexible printed circuit board (Flexible Printed Circuit Board, FPCB) for connecting and inserting the flat cable interface 2221 so as to transmit the sensing signal or the control signal generated by the electronic device 1 to the flat cable interface 2221 of another device base 2, the flat cable interface 2221 of a battery device or the flat cable interface 2221 of an electrode patch connected to the adaptor 31 at the other end of the transmission wire 3 through the transmission wire 3.

The arrangement and design of the positioning sidewall and the positioning structure can be adjusted according to the shape, size, weight or wiring of the electronic device, so that the positioning structure corresponding to the lower housing and the soft gasket can be slightly adjusted. In addition, the number and direction of the flat cable interfaces can be adjusted according to the connection requirement of the electronic device and the intelligent clothing, so that the positions and directions of the first flat cable grooves of the lower shell and the second flat cable grooves of the soft gaskets can be correspondingly adjusted, but the main concept of the device base is not affected.

For example, in the first embodiment of fig. 1A to 1D/the second embodiment of fig. 3A to 3D, the upper housing 21/51 is provided with four positioning sidewalls 212/512, and the four first positioning structures 213/513 are used to rotate the four second positioning structures 11/41 of the snap-fit electronic device 1/4, so that the electronic device 1/4 is fixed within the range defined by the four positioning sidewalls 212/512. In order to facilitate the connection of the electronic device 1/4 and other electronic devices to each other, a set of flat cable interfaces 2221/5221 and first and second flat cable grooves 233/533 and 243/543 may be provided in four perpendicular directions, respectively. At least one annular second convex positioning portion 241/541 is disposed at the top periphery of the soft pad 24/54, and the first convex positioning portion 231/531 and the second convex positioning portion 241/541 can be plugged into and positioned in the concave positioning portion 214/514 of the upper housing 21/51 together, and the lower housing 23/53 is tightly adhered to the combining hole 242/542, so that the lower housing 23/53 is combined with the upper housing 21/51, and the periphery of the lower housing 23/53 further extends outwards to surround the soft pad 24/54.

For example, in the third embodiment of fig. 4A to 4D, the edge of the upper housing 71 extends upward to form a circumferential positioning sidewall 712 to form a placement bottom groove, at least one first positioning structure 713 is formed around the positioning sidewall 712, and the first positioning structure 713 may be an opening or a groove for corresponding to the movable positioning structure 61 or the fixed positioning structure 61' of the electronic device 6, where the movable positioning structure 61 may be a button hook structure. At least one annular first protruding positioning portion 731 is disposed at the top periphery of the lower housing 73, and a third positioning structure 7311 (e.g. a hole-shaped third positioning structure 7311 or a groove-shaped third positioning structure 7311 ') may be further protruding above the first protruding positioning portion 731, so that when the lower housing 73 is combined with the upper housing 71, the first protruding positioning portion 731 is inserted into the concave positioning portion 714, and the third positioning structure 7311 is exposed out of the hole-shaped first positioning structure 713, so that after the electronic device 6 is placed in the area surrounded by the positioning sidewall 712, the movable positioning structure 61 of the electronic device 6 can be inserted into the hole 73111 of the third positioning structure 7311 exposed in the concave positioning portion 714, and the fixed positioning structure 61' can be locked into the groove-shaped third positioning structure 7311', so that the electronic device 6 can be firmly placed in the placement groove. The soft spacer 74 is formed by extending outwardly from the positioning side wall 712 of the upper housing 71. In order to facilitate the connection of the electronic device 6 and other electronic devices to each other, a plurality of sets of flat cable interfaces 7221 and a plurality of corresponding first flat cable grooves 733 and second flat cable grooves 743 may be disposed on opposite sides of the circuit substrate 72.

The smart apparel of embodiment two:

as shown in fig. 5A and 5B, a second embodiment of the present invention provides an intelligent garment using the device base of the first embodiment, the intelligent garment including: the device base of embodiment one, the clothing body and the at least one transmission wire of embodiment one, wherein the clothing body comprises a surface layer 81 and a waterproof layer 82. When the device base 5 is combined with a decoration body 8, an opening 811 is first dug into the surface layer 81, then the device base 5 is penetrated out of the opening 811, the cushion sheet 54 of the device base 5 is adhered (bonded by using a hot pressing mode) to be fixed on the inner surface of the surface layer 81, the upper shell 51 is exposed out of the surface layer 81, and the flat cable interface 5221 of the circuit substrate 52 faces the inner side of the surface layer 81.

After the one-way joint 31' at either end of the transmission wire 3 is inserted into the flat cable connector in the second through hole along the second flat cable groove and the first flat cable groove, the other end of the transmission wire 3 is extended and laid out in any direction inside the surface layer 81 according to the transmission requirement. In order to further protect the circuit components of the circuit substrate 52 and the transmission wires 3, a waterproof protective layer 82 is bonded (sewn or thermocompression bonded) to the inner surface of the surface layer 81 to cover the bottom surface of the lower housing 53 and the extension of the transmission wires 3. In order to increase the waterproof performance, a waterproof surface layer may be further laid on the inner surface of the surface layer 81, and the waterproof surface layer may be adhered to the waterproof protective layer 82 correspondingly to completely cover the transmission wire 3; or, a waterproof layer may be further laid on the upper surface of the transmission wire 3, and the waterproof layer 82 is adhered or sewn to the inner surface of the surface layer 81.

As shown in fig. 5B, the device bases 2,5,7 of different types of electronic devices, the transmission wires 3, at least one battery device having a flat cable interface, or/and at least one electrode patch 83 having a flat cable interface are wired on the clothing body 8, and the transmission wires extending from the inner surface of the cloth layer to be connected to the flat cable interface of another device base, the flat cable interface of the battery device, or the flat cable interface of the electrode patch are observable from the inside of the clothing body 8. The electronic device may be the device base 2 of the EMS-IMU combination device, the device base 5 of the EMG-IMU combination device and/or the device base 7 of the operation control device, or the device base of the electronic device with a battery, and the user may match the device according to the requirement. The clothing body 8 can be directly cleaned, and is economical to be used as a consumable.

As shown in fig. 5C, when the exercise is to be performed, the electronic device 1,4,6 can be mounted on the device base 2,5,7, and the electronic device 1,4 is used for sensing and transmitting the sensing signal to the device base 7 via the device base 2,5, and is received by the electronic device 6 linked to the device base 7 for operation and control, for example, controlling the electronic device 1 to supply power to the electrode patch 83 for performing muscle stimulation through the electrode patch 83. Therefore, the intelligent clothes according to the arranged electronic device not only can receive electrocardio signals, myoelectricity signals and limb inertia signals to know the exercise condition, but also can give muscle stimulation according to the exercise condition, and the training result is improved.

The present invention has been described in terms of the above embodiments, but it should be understood that the invention is not limited to the above embodiments, and that the technical features and embodiments of the present invention can be understood by those skilled in the art, and that the invention is not limited to the above embodiments.

Claims

1. An apparatus base electrically connected to an electronic apparatus having a plurality of metal external contacts on a lower surface, the apparatus base comprising:

2. The device chassis of claim 1, wherein the upper or lower housing has a flexible gasket extending outwardly around a periphery thereof, wherein the bottom surface of the flexible gasket is recessed toward the first flat cable groove to form a second flat cable groove having a slope equal to that of the first flat cable groove, such that the second flat cable groove and the first flat cable groove extend out of a continuous plane.

3. The device mount of claim 1, wherein the electronic device is a sensing device, a stimulation device, a processing computing device, or a combination thereof.

4. The device base of claim 1, wherein the transmission wire is a flexible elastic belt body, and a plurality of wavy or zigzag metal wires are arranged in the flexible elastic belt body, wherein the metal wires are connected to the adapter.

5. The device mount of claim 1, wherein the adapter at one end of the transmission wire is connected to the flat cable interface and the adapter at the other end of the transmission wire is connected to a flat cable interface of another device mount, a flat cable interface of a battery device, or a flat cable interface of an electrode patch.

6. The device mount of claim 2, wherein the soft pad includes a second protruding locating portion and forms a combination hole, the second protruding locating portion and the first protruding locating portion are combined in the concave locating portion, and the lower housing is tightly fitted in the combination hole, so that the periphery of the lower housing extends outwards the soft pad.

7. The device mount of claim 2, wherein the upper housing has a soft gasket extending around the periphery thereof.

8. An intelligent garment employing a device base, comprising:

at least one device mount according to claim 2;

9. The smart garment of claim 8, further comprising at least one battery device having a flat cable interface or/and at least one electrode patch having a flat cable interface, wherein the transmission wire extends from the inner surface of the surfacing layer to connect to the flat cable interface of another device base, the flat cable interface of the battery device or the flat cable interface of the electrode patch.

10. The intelligent clothing using the base of the device as claimed in claim 8, wherein a waterproof layer is further laid on the upper surface of the transmission wire, and the waterproof layer is fixedly attached to the inner surface of the surface layer by bonding or sewing.