CN206453922U - Micro-current cloth and clothes, bed necessaries, mat and external member containing the cloth - Google Patents

Abstract

The utility model is related to a kind of micro-current cloth, and the micro-current cloth includes cloth body that can be conductive, is arranged at least one micro-current power supply on cloth body.The utility model on cloth matrix by setting micro-current power supply, when cloth is human contact, micro-current power supply and human body formation loop, form micro-current, in the presence of micro-current, pre- counteracting bedsores is played a part of in the blood circulation increase contacted with micro-current cloth, the related acupuncture point that harmonizes the body can also be played, plays a part of health care；Further, the utility model by the both positive and negative polarity of micro-current power supply by drawing conductive bar, realize being uniformly distributed for the potential on cloth body, and then the micro-current realized in the human body of covering is uniformly distributed, so as to reach uniform stimulation body blood circulation and acupuncture point, the effect of bedsore is prevented comprehensively.

Description

Micro-current cloth, and clothes, bedding, cushion and kit containing the same

Technical Field

The utility model belongs to the fabric design field, concretely relates to little electric current cloth especially relates to a cloth that can produce little electric current, the cloth can be fixed as required or design on close clothing, bedding or mat, increases the blood circulation of the person of dress skin of contact with it, prevents decubital formation.

Background

Bedsore, also known as pressure ulcer and pressure sore, is caused by tissue ulceration and necrosis due to continuous ischemia, anoxia and malnutrition caused by long-term local tissue compression. Skin pressure sores are a common problem in rehabilitation and care. According to the literature, about 6 million people die from pressure sore union symptom every year.

In order to prevent the bedsore of the patient, the patient needs to be nursed by turning over, massaging and the like regularly, the blood circulation of the corresponding part is increased, and the workload is large and inconvenient.

The micro-current cloth is required to be developed in the field, and can form micro-current when being in contact with the skin, so that the blood circulation is increased, and the bedsore is effectively prevented.

SUMMERY OF THE UTILITY MODEL

To prior art's not enough, one of the purposes of the utility model is to provide an utilize little electric current's cloth, little electric current cloth can increase human blood circulation, prevention bedsore at the human skin evenly distributed little electric current that covers.

The utility model discloses a utility model purpose realizes through following technical scheme:

the micro-current cloth comprises a cloth body and at least one micro-current power supply arranged on the cloth body.

The micro-current power supply arranged on the cloth body can be internally arranged or externally connected.

Preferably, the micro-current power supply comprises any 1 or at least 2 combinations of paper batteries, lithium batteries and external power supplies; the micro-current power supply voltage is not higher than 36V, such as 1.5V, 3V, 3.7V, 4.5V, 6V, 7.4V, 12V, 24V, 36V and the like, and preferably the micro-current power supply voltage is not higher than 12V, such as 1.5V, 3V, 3.7V, 4.5V, 6V, 7.4V, 12V and the like; and the micro-current formed is less than or equal to 10mA, preferably less than or equal to 5 mA.

The output voltage of the external power supply (similar to the charging plug of various chargers) is not higher than 36V, such as 1.5V, 3V, 4.5V, 6V, 12V, 24V, 36V, and the like, and the output voltage of the preferred external power supply is not higher than 12V, such as 1.5V, 3V, 4.5V, 6V, 12V, and the like; and the micro-current formed is less than or equal to 10mA, preferably less than or equal to 5 mA.

The micro-current cloth can be a combination of at least 2 micro-current power supplies, for example, an external power supply is arranged on the premise that a paper battery or a lithium battery is arranged, and the micro-current cloth can be directly plugged for use on the premise that an external power supply socket is arranged.

Preferably, the micro-current power supply is a micro-current power supply having a switch.

Preferably, the micro-current power source is a paper battery.

It will be clear to those skilled in the art that the positive and negative electrodes of the microcurrent power supply should form an open circuit to avoid discharging current when the microcurrent power supply is not needed, for example, when the microcurrent power supply is a paper battery, the positive and/or negative electrode of the paper battery is provided with a detachable isolating layer for isolating the positive and/or negative electrode of the paper battery from the cloth body when the microcurrent power supply is not needed.

Preferably, when the micro-current power supply is an internal power supply, the cloth is provided with a detachable protective sleeve for fixing, replacing or detaching the micro-current power supply when needed.

Preferably, the removable sheath comprises a self-adhesive cloth.

Preferably, the cloth body is further provided with a positive conductive strip and/or a negative conductive strip; one end of the positive conductive bar is connected with the positive electrode of the micro-current power supply, and the other end of the positive conductive bar is suspended; one end of the negative conductive bar is connected with the negative electrode of the micro-current power supply, and the other end of the negative conductive bar is suspended.

The utility model discloses in, anodal busbar and negative pole busbar can be understood as anodal extension line and negative pole extension line, and the busbar is selected from the very little conductor of resistance, and resistance is far less than the battery internal resistance, and can neglect almost, be equal to the battery just, the negative pole, and the effect played is on the cloth body with little current power's electric potential evenly distributed.

Preferably, the positive conductive strips and the negative conductive strips are arranged at intervals.

Preferably, the spacing distance between the positive conductive strips and the negative conductive strips is the same.

Preferably, the positive conductive strips are sequentially arranged around the periphery of a first set point in sequence; the negative conductive strips are sequentially arranged around a second set point around the periphery of the second set point; and the positive conductive strips and the negative conductive strips are arranged side by side so as to enable the positive and negative strips to be arranged at intervals.

Preferably, each of the positive conductive strip and the negative conductive strip is independently selected from any 1 of a square spiral line, a circular spiral line, a triangular spiral line or a diamond spiral line.

Preferably, at least 2 micro-current power supplies are arranged on the cloth body, each micro-current power supply is optionally connected with a positive conductive strip and/or a negative conductive strip, and the positive conductive strips and the negative conductive strips are arranged at intervals.

Preferably, the adjacent positive conductive strips and the adjacent negative conductive strips are distributed in a centrosymmetric manner or in an axisymmetric manner.

Preferably, at least 2 micro-current power supplies are arranged on the cloth body, each micro-current power supply is optionally connected with a positive conductive strip and/or a negative conductive strip, the suspension ends of the positive conductive strips and the negative conductive strips are arranged at intervals, and the included angles between the suspension ends of the adjacent positive conductive strips and the suspension ends of the negative conductive strips and the line connecting the circle centers of the cloth body are not less than 60 degrees.

Preferably, the anode of the micro-current power supply is arranged at the center of the cloth body, and the cathode of the micro-current power supply is connected with the cathode conductive bar and is distributed on the edge of the cloth body in a circular ring shape; or,

the negative pole of the micro-current power supply is arranged at the center of the cloth body, and the positive pole of the micro-current power supply is connected with the positive conductive strip and distributed on the edge of the cloth body in a circular shape.

Preferably, the shape of anodal busbar and negative pole busbar is the comb shape, and the broach of anodal busbar is placed in the broach clearance of negative pole busbar.

Preferably, the distance between the positive electrode of the micro-current battery, the distance between the negative electrode of the micro-current battery, the distance between the positive electrode conductive strip and the distance between the negative electrode conductive strip and the edge of the cloth are respectively and independently selected from 0.5-5 cm.

Preferably, the cloth body contains flexible conductive fibers.

Preferably, the flexible conductive fibers are selected from any 1 or a combination of at least 2 of silver fibers, graphene composite fibers or carbon fibers.

Further preferably, the cloth body is formed by blending graphene composite fibers and carbon fibers.

Preferably, each of the positive conductive strip and the negative conductive strip is independently selected from any 1 or at least 2 combinations of conductive fibers, conductive metal wires, conductive metal sheets, conductive metal strips or conductive paste.

Preferably, the conductive fiber is any 1 or a combination of at least 2 of carbon fiber, graphene fiber and graphene composite fiber.

When the conductive fibers are biomass graphene oxide composite fibers or the biomass graphene is compounded in the cloth body, the micro-current cloth has a far infrared function.

Preferably, the positive conductive strip and the negative conductive strip are printed or brushed independently by conductive paste.

The preparation method of the micro-current cloth of the utility model typically but not limitatively comprises the following steps:

(1) preparing a material of a cloth body sheet layer;

(2) cutting the cloth body material obtained in the step (1) according to a set shape to obtain a cloth body;

(3) and (3) attaching a micro-current power supply or the positive electrode and the negative electrode of the micro-current power supply to the cloth body to obtain the micro-current cloth.

The micro-current cloth prepared at this time does not have a positive conductive strip and a negative conductive strip.

Optionally, step (3') is performed before step (3) to form the positive conductive strip and/or the negative conductive strip on the cloth body. After step (3'), the resulting microcurrent cloth has a positive conducting strip and/or a negative conducting strip.

One of the preparation methods of the material of the cloth body sheet layer can be as follows: and mixing the graphene with the fiber master batch, and performing electrostatic spinning to obtain the graphene fiber.

Or,

the second preparation method of the material of the sheet layer of the cloth body comprises the following steps: the method comprises the steps of mixing graphene and fiber master batches, carrying out melt spinning to obtain graphene composite fibers, and then blending the graphene composite fibers with fibers which are not compounded with graphene and can be obtained in any of the prior art.

Or,

the third preparation method of the material of the cloth body sheet layer comprises the following steps: the method comprises the steps of mixing graphene with a cellulose spinning solution, spinning to obtain graphene composite fibers, and then blending the graphene composite fibers with fibers which are not compounded with graphene and can be obtained in any of the prior art.

The fabric body is obtained by spinning fibers, and the fibers can also be made into non-woven fabrics.

The method for attaching the micro-current power supply or the anode and the cathode of the micro-current power supply to the cloth body is to attach the micro-current power supply or the anode and the cathode of the micro-current power supply through a binder or other fixing methods in the prior art. When little current power supply is paper battery or lithium cell, its volume ratio is less, can be directly with the power laminating on the cloth body. When the micro-current power supply is an external power supply, the micro-current power supply can be directly attached to only the anode and the cathode of the power supply, and an external power supply is inserted in the using process.

Preferably, the conductive paste is conductive silver paste.

The second purpose of the utility model is to provide a garment, which comprises the micro-current cloth.

Preferably, the garment is a close-fitting garment, preferably any 1 of a close-fitting sling, vest, tights, trousers or pajamas.

The third purpose of the utility model is to provide a bedding, which comprises any 1 or at least 2 combinations of quilt, mattress, bed sheet, pillow case or quilt cover, wherein the bedding is close to one side of human body and contains micro-current cloth as mentioned above.

As will be understood by those skilled in the art, the bedding of the present invention may be any 1 kind of quilt, mattress, sheet, pillow case or quilt cover, and may also be any 2 or more kinds of combinations of matched quilt, mattress, sheet, pillow case or quilt cover; when the bedding is any 2 or more than 2 combinations of quilts, bed sheets, pillows, pillow cases or quilt covers, 2 or more than 2 single beddings can share one micro-current power supply, or each single beddings is respectively provided with one micro-current power supply.

The fourth purpose of the utility model is to provide a cushion, the surface of the cushion contains the micro-current cloth as mentioned above.

The fifth of the objects of the utility model provides a kit, the kit includes the third of purpose bedding or the fourth of purpose the mat to and the clothing of wearing next to the shin can electrically conduct, the clothing contacts with bedding or mat in the external member use.

Compared with the prior art, the utility model discloses following beneficial effect has:

the utility model discloses a set up little current power on the cloth base member, when the cloth contacted with the human body, little current power and human body formed the return circuit, formed little current, under the effect of little current, the blood circulation who contacts with little current cloth increased, played the effect of preventing bedsore, can also play the relevant acupuncture point of massage health, played the effect of health care;

further, the utility model discloses a draw forth the busbar with little current source's positive negative pole, realized the evenly distributed of electric potential on the cloth body, and then realized the evenly distributed at the human little current that covers to reach even amazing health blood circulation and acupuncture point, prevent decubital effect comprehensively.

Drawings

FIG. 1 shows a schematic diagram of an embodiment with a microcurrent power supply;

FIG. 2 is a cross-sectional view of the internal structure of circle B1 of FIG. 1;

FIG. 3 shows a schematic structural view of an embodiment with a removable sheath;

FIG. 4 is a cross-sectional view of the internal structure of circle B2 of FIG. 3;

fig. 5 is a schematic structural diagram of positive conductive strip 300 and negative conductive strip 400 in embodiment 1, which are circular spirals;

fig. 6 is a schematic structural diagram of positive conductive strip 300 and negative conductive strip 400 in the embodiment 1, which are square spirals;

fig. 7 is a schematic structural diagram of the positive electrode conductive strip 300 and the negative electrode conductive strip 400 in embodiment 2, which are long strips;

fig. 8 is a schematic structural diagram of the positive conductive strip 300 and the negative conductive strip 400 in the embodiment 2 with arc shapes;

fig. 9 is a schematic structural diagram of the positive conductive strip 300 and the negative conductive strip 400 in a wavy shape in embodiment 2;

FIG. 10 is a schematic view showing the structure of a wig cap according to example 3;

FIG. 11 is a schematic view showing the structure of the wig cap of example 4;

FIG. 12 is a schematic view showing the structure of the wig cap of example 5.

The protective sleeve comprises a cloth body 100, a micro-current battery 200, a positive conductive strip 300, a negative conductive strip 400 and a detachable sheath 500.

Detailed Description

To facilitate understanding of the present invention, the present invention has the following embodiments. It should be understood by those skilled in the art that the described embodiments are merely provided to assist in understanding the present invention and should not be construed as specifically limiting the present invention.

The utility model provides a little current cloth, little current cloth sets up at least one little current power supply 200 on cloth body 100 including cloth body 100 that can electrically conduct. (fig. 1 is a schematic structural view showing an embodiment having a micro-current power supply, fig. 1 is a schematic front view, and fig. 2 is a cross-sectional view showing an internal structure of a circle B1 in fig. 1).

The micro-current power supply 200 has a positive electrode and a negative electrode, and the positive electrode and the negative electrode of the micro-current power supply 200 can be arranged on the same side of the cloth body 100, such as on the side of the cloth body 100 away from the skin, or on the side of the cloth body 100 close to the skin; or, the positive electrode and the negative electrode of the micro-current power supply 200 are disposed on different sides of the cloth body 100, for example, the positive electrode of the micro-current power supply 200 is disposed on one side of the cloth body 100 close to the skin, and the negative electrode is disposed on one side of the cloth body 100 far from the skin, or the positive electrode of the micro-current power supply 200 is disposed on one side of the cloth body 100 far from the skin, and the negative electrode is disposed on one side of the cloth body close to the skin.

Preferably, the micro current power supply 200 includes any 1 or at least 2 combinations of paper batteries, lithium batteries, and external power sources.

Preferably, the micro-current power supply is a micro-current power supply having a switch.

Preferably, the micro-current power supply 100 is a paper battery.

The paper battery is a battery using paper as a carrier, or a battery made by making each part of the battery into a paper form, and can be folded. When selecting the paper battery as little current power, it can be crooked together with the cloth body, and does not influence the current transport when using. Any paper battery available to those skilled in the art may be used in the present invention.

It should be understood by those skilled in the art that when the micro-current power supply 200 is not required to generate micro-current, the positive and negative electrodes of the micro-current power supply 200 should form an open circuit to avoid discharging current, for example, when the micro-current power supply 200 is a paper battery, the positive and negative electrodes of the paper battery are provided with isolating layers to isolate the positive and/or negative electrodes of the paper battery from the cloth body 100.

Preferably, when the micro-current power supply 200 is a paper battery, the positive electrode and the negative electrode of the paper battery are provided with detachable isolation layers for isolating the positive electrode and/or the negative electrode of the paper battery from the cloth body when micro-current generation is not required.

It will be understood by those skilled in the art that when a micro-current is to be generated, the removable isolation layer is removed, and the micro-current power supply 200 can be connected to form a loop to generate the micro-current.

Preferably, when the micro-current power supply 200 is a built-in power supply, the cloth is provided with a detachable protective sleeve 500 for fixing, replacing or detaching the micro-current power supply 200 when necessary.

Preferably, the removable sheath 500 comprises a self-adhesive cloth.

(FIG. 3 shows a schematic structural view of an embodiment with a detachable sheath, and FIG. 4 is a sectional view of the internal structure of circle B2 in FIG. 3).

As a specific embodiment, the cloth body 100 is further provided with a positive conductive strip 300 and/or a negative conductive strip 400; one end of the positive conductive bar 300 is connected with the positive electrode of the micro-current power supply 200, and the other end is suspended; one end of the negative conductive strip 400 is connected to the negative electrode of the micro-current power supply 200, and the other end is suspended.

It should also be clear to those skilled in the art that any raw material used in the micro-current cloth of the present invention should meet the national requirements.

Preferably, the positive conductive strips 300 and the negative conductive strips 400 are arranged at intervals.

It should be clear to those skilled in the art that the current of the micro-current cloth of the present invention should not be too large and should be within the safe current of the human body, preferably within 10 mA. The size of the micro-current can be adjusted by adjusting the resistance of the cloth body and/or the voltage of the micro-current power supply by a person skilled in the art, specifically by an equation of I ═ U/R, where I is the current size, U is the voltage size, and R is the resistance size.

The materials of the positive conductive strip 300 and the negative conductive strip 400 of the micro-current power supply are selected from conductors which are far smaller than other resistors in a current loop formed by a cloth body, human skin and the like, so that the potentials on the positive conductive strip 300 and the negative conductive strip 400 are basically the same, the positive conductive strip can be equivalent to a power extension line of the micro-current power supply 200, and the negative conductive strip can be equivalent to a negative extension line of the micro-current power supply 200.

It should be understood by those skilled in the art that the cloth can be configured in different structures to be suitable for the final products, such as trousers, jackets, pillows, quilts, cushions, etc., all the drawings of the present invention are schematic structural diagrams, wherein the exposed areas of the differences of the shapes are not shown, those skilled in the art can modify the conductive strips on the cloth body into any arrangement suitable for the shapes according to actual situations, and it is necessary to ensure that the positive conductive strips 300 and the negative conductive strips 400 are not cut off.

The utility model also provides a garment, the garment contains little current cloth as before.

Preferably, the garment is a close-fitting garment, preferably any 1 of a close-fitting sling, vest, tights, trousers or pajamas.

The utility model also provides a bedding, including 1 arbitrary or 2 at least combinations in quilt, bed sheet, bed pillow, pillowcase or the quilt cover, the bedding contains as before little current cloth in being close to human one side.

The utility model also provides a mat, the surface of mat contains as before little current cloth.

The utility model also provides a kit, the kit includes as before the bedding or as before the mat to and the clothing of wearing next to the shin can electrically conduct, the clothing contacts with bedding or mat in the kit use.

The utility model provides a have the utility model in clothes, bedding, cushion and the external member of little electric current cloth, the fixed mode of little electric current cloth is also undefined.

Optionally, in the garment, the bedding, the seat cushion or the set, the cloth is detachably arranged on the garment, or is fixedly arranged on the garment, the bedding, the seat cushion or the set in an integrated manner.

The micro-current cloth can be fixed on clothes, bedding, a cushion or a suite in a detachable mode through the self-adhesive cloth, and even a user can fix the micro-current cloth at any position according to the body condition of the user.

The utility model provides a have the utility model in the clothes, bedding, cushion or the external member of little electric current cloth, the quantity of little electric current cloth is not specifically injectd, can only set up 1 according to the demand, 2 or 3, 4 and so on.

Example 1

A micro-current cloth comprises a cloth body 100, a micro-current power supply 200 arranged on the cloth body 100, a positive conductive strip 300 connected with the positive electrode of the micro-current power supply 200 and a negative conductive strip 400 connected with the negative electrode of the micro-current power supply 200; the positive conductive strips 300 are sequentially arranged around the first set point around the periphery of the first set point; the negative conductive strips 400 are sequentially arranged around a second set point around the periphery of the second set point; and the positive conductive strip 300 and the negative conductive strip 400 are arranged side by side so that the positive and negative electrodes are arranged at intervals.

In embodiment 1, the positive conductive strip 300 and the negative conductive strip 400 may be two circular spirals arranged side by side (as shown in fig. 5), or two square spirals arranged side by side (as shown in fig. 6), or two triangular spirals or diamonds arranged side by side. It should be understood by those skilled in the art that the specific shape of the spiral line is not limited to the illustration of the present invention, and any arrangement that can realize the interval arrangement of the positive and negative electrodes can be used in the present invention, and the rotation directions of the spiral lines of the positive conductive bar 300 and the negative conductive bar 400 can be the same or different, i.e. the positive conductive bar 300 and the negative conductive bar 400 can be the same spiral or the reverse spiral.

In embodiment 1, the positive and negative spacing distances of the positive conductive strip 300 and the negative conductive strip 400 are the same.

In embodiment 1, the first set point and the second set point may be the same or different.

In embodiment 1, the positive electrode of the micro-current power supply 200 can be connected to any end of the positive conductive strip 300, and the negative electrode of the micro-current power supply 200 can be connected to any end of the negative conductive strip 400.

It should be understood by those skilled in the art that fig. 5 and 6 are only schematic structural diagrams, and the specific shapes of the spiral lines of the positive conductive strip 300 and the negative conductive strip 400 may not be regular circles, squares, triangles or crescent shapes, and may be any shapes suitable for the shape of the cloth.

Example 2

A micro-current cloth comprises a cloth body 100, a first micro-current power supply 201 and a second micro-current power supply 202 which are arranged on the cloth body 100, a first positive conductive strip 301 connected with the positive electrode of the first micro-current power supply 201, a first negative conductive strip 401 connected with the negative electrode of the first micro-current power supply 201, a second positive conductive strip 302 connected with the positive electrode of the second micro-current power supply 202, and a second negative conductive strip 402 connected with the negative electrode of the second micro-current power supply 202; the conductive strips are arranged at intervals, such as a first positive conductive strip 301, a first negative conductive strip 401, a second positive conductive strip 302 and a second negative conductive strip 402 from left to right.

In embodiment 2, the shapes of first positive conductive strip 301, first negative conductive strip 401, second positive conductive strip 302, and second negative conductive strip 402 are not particularly limited, and may be a long strip (as shown in fig. 7), an arc (as shown in fig. 8), or a wave (as shown in fig. 9).

In embodiment 2, the adjacent positive conductive strips and the adjacent negative conductive strips are distributed in an axisymmetric or point-symmetric manner.

In embodiment 2, only one micro-current power supply may be provided, and at least 2 conductive strips are led out from the positive electrode and the negative electrode, respectively, and the conductive strips need positive and negative intervals.

In embodiment 1, the positive and negative spacing distances of the positive conductive strip 300 and the negative conductive strip 400 are the same.

It should be understood by those skilled in the art that fig. 7, 8 and 9 are only schematic structural diagrams, and the specific shapes of the positive conductive strip 300 and the negative conductive strip 400 may not be regular strips, arcs or waves, and may be any shapes suitable for the shape of cloth.

Example 3

A micro-current cloth comprises a cloth body 100, a first micro-current power supply 201 and a second micro-current power supply 202 which are arranged on the cloth body 100, a first positive conductive strip 301 connected with the positive electrode of the first micro-current power supply 201, a first negative conductive strip 401 connected with the negative electrode of the first micro-current power supply 201, a second positive conductive strip 302 connected with the positive electrode of the second micro-current power supply 202, and a second negative conductive strip 402 connected with the negative electrode of the second micro-current power supply 202; the suspension ends of the conductive strips are arranged at positive and negative intervals, and the included angles between the suspension ends of the conductive strips and the connecting line of the circle center of the cloth body are all larger than or equal to 60 degrees, such as 65 degrees, 70 degrees, 75 degrees, 80 degrees, 85 degrees, 90 degrees, 98 degrees, 110 degrees, 130 degrees, 150 degrees, 180 degrees and the like (as shown in fig. 10).

Example 4

A micro-current cloth comprises a cloth body 100 and a micro-current power supply 200 arranged on the cloth body 100, wherein the anode of the micro-current power supply 200 is arranged at the center of the cloth body 100, the cathode of the micro-current power supply 200 is connected with a cathode conductor 400 through a wire 403, the cathode conductor 400 is in a circular ring shape (as shown in figure 11) along the edge of the cloth body 100, the wire 403 is insulated from the cloth body 100, and an insulating layer can be arranged on the outer layer of the wire 403.

In embodiment 4, the positive electrode and the negative electrode can be exchanged with each other, that is, the negative electrode of the micro-current power supply 200 is disposed at the center of the cloth body 100, and the positive electrode of the micro-current power supply 200 is connected to the lead 403 and is in a circular shape along the edge of the cloth body 100.

Example 5

A micro-current cloth comprises a cloth body 100, a micro-current power supply 200 arranged on the cloth body 100, a positive conductive strip 300 connected with the positive electrode of the micro-current power supply 200 and a negative conductive strip 400 connected with the negative electrode of the micro-current power supply 200; the positive conductive strip 300 and the negative conductive strip 400 are both comb-shaped, and the comb teeth of the positive conductive strip 300 are placed in the comb tooth gaps of the negative conductive strip 400.

In the micro-current cloth of the present invention, the distance between the positive electrode of the micro-current battery, the negative electrode of the micro-current battery, the positive conductive strip and the negative conductive strip, and the edge of the cloth is independently selected from 0.5 to 5cm, such as 0.6cm, 0.7cm, 0.8cm, 1.1cm, 1.6cm, 1.9cm, 2.3cm, 2.8cm, 3.5cm, 4,3cm, 4.8cm, etc.

In the micro-current cloth of the utility model, the cloth body contains flexible conductive fibers; the flexible conductive fiber is preferably selected from any 1 or a combination of at least 2 of silver fiber, graphene composite fiber or carbon fiber. As one of the preferred embodiment, the utility model discloses the cloth body is formed by graphite alkene composite fiber and carbon fiber blending.

In the micro-current cloth of the present invention, the positive electrode conductive strip and the negative electrode conductive strip are independently selected from any 1 or at least 2 combinations of conductive fibers, conductive metal wires, conductive metal sheets, conductive metal strips, or conductive paste; the conductive fiber is preferably any 1 or a combination of at least 2 of carbon fiber, graphene fiber and graphene composite fiber; the positive conductive strip and the negative conductive strip are respectively and independently formed by printing or brushing conductive paste; the conductive paste is preferably conductive silver paste. The metal elements of the conductive metal wires, the conductive metal sheets and the conductive metal strips are preferably conductive metals such as metallic silver or copper.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (33)

1. The micro-current cloth is characterized by comprising a conductive cloth body and at least one micro-current power supply arranged on the cloth body.

2. The micro-current fabric according to claim 1, wherein the micro-current power source comprises any 1 or at least 2 combinations of paper batteries, lithium batteries, and external power sources.

3. The micro-current fabric according to claim 1, wherein the micro-current power supply is a micro-current power supply having a switch.

4. The micro-current fabric of claim 1, wherein the micro-current power source is a paper battery.

5. The micro-current cloth according to claim 1, wherein when the micro-current power source is a paper battery, the positive electrode and/or the negative electrode of the paper battery is provided with a detachable isolating layer for isolating the positive electrode and/or the negative electrode of the paper battery from the cloth body.

6. The micro-current cloth according to claim 1, wherein when the micro-current power supply is a built-in power supply, the cloth is provided with a detachable protective cover for fixing, replacing or detaching the micro-current power supply when necessary.

7. The micro-current fabric of claim 6, wherein the removable sheath comprises a self-adhesive cloth.

8. The micro-current cloth of claim 1, wherein the cloth body is further provided with a positive conductive strip and/or a negative conductive strip; one end of the positive conductive bar is connected with the positive electrode of the micro-current power supply, and the other end of the positive conductive bar is suspended; one end of the negative conductive bar is connected with the negative electrode of the micro-current power supply, and the other end of the negative conductive bar is suspended.

9. The micro-current cloth of claim 8, wherein the positive conductive strips and the negative conductive strips are arranged at positive and negative intervals.

10. The micro-current cloth of claim 9, wherein the positive conductive strips are spaced apart from the negative conductive strips by the same distance.

11. The micro-current cloth of claim 8, wherein the positive conductive strips are sequentially arranged around a first set point around the periphery of the first set point; the negative conductive strips are sequentially arranged around a second set point around the periphery of the second set point; and the positive conductive strips and the negative conductive strips are arranged side by side so as to enable the positive and negative strips to be arranged at intervals.

12. The micro-current cloth of claim 11, wherein the positive conductive strip and the negative conductive strip are each independently selected from any 1 of a square spiral, a circular spiral, a triangular spiral, or a diamond spiral.

13. The micro-current cloth according to claim 1, wherein at least 2 micro-current power supplies are arranged on the cloth body, each micro-current power supply is optionally connected with a positive conductive strip and/or a negative conductive strip, and the positive conductive strips and the negative conductive strips are arranged at intervals.

14. The micro-current cloth according to claim 13, wherein the adjacent positive conductive strips and the adjacent negative conductive strips are distributed in a central symmetry or an axial symmetry.

15. The micro-current cloth according to claim 1, wherein at least 2 micro-current power supplies are arranged on the cloth body, each micro-current power supply is optionally connected with a positive conductive strip and/or a negative conductive strip, the suspension ends of the positive conductive strips and the negative conductive strips are arranged at intervals, and the included angles between the connection lines of the suspension ends of the adjacent positive conductive strips and the suspension ends of the negative conductive strips and the circle center of the cloth body are not less than 60 °.

16. The micro-current cloth according to claim 1, wherein the anode of the micro-current power supply is disposed at the center of the cloth body, and the cathode of the micro-current power supply is connected to the cathode conductive strip and is annularly distributed at the edge of the cloth body.

17. The micro-current cloth according to claim 1, wherein the cathode of the micro-current power supply is disposed at the center of the cloth body, and the anode of the micro-current power supply is connected to the anode conductive strip and is annularly distributed at the edge of the cloth body.

18. The micro-current cloth of claim 8, wherein the positive conductive bar and the negative conductive bar are both comb-shaped, and the comb teeth of the positive conductive bar are placed in the comb teeth gaps of the negative conductive bar.

19. The micro-current cloth of claim 1, wherein the distance between the positive electrode of the micro-current battery, the distance between the negative electrode of the micro-current battery, the distance between the positive conductive bar and the distance between the negative conductive bar and the edge of the cloth are respectively and independently selected from 0.5-5 cm.

20. The micro-current cloth of claim 1, wherein the cloth body contains flexible conductive fibers, or the surface of the cloth body is coated with a conductive layer.

21. The micro-current cloth of claim 20, wherein the flexible conductive fibers are selected from any 1 or a combination of at least 2 of silver fibers, graphene composite fibers, or carbon fibers.

22. The micro-current cloth of claim 1, wherein the cloth body is blended from graphene composite fibers and carbon fibers.

23. The micro-current cloth of claim 8, wherein the positive conductive strip and the negative conductive strip are each independently selected from any 1 or at least 2 combinations of conductive fibers, conductive metal wires, conductive metal sheets, conductive metal strips, or conductive pastes.

24. The micro-current fabric according to claim 23, wherein the conductive fibers are any 1 or a combination of at least 2 of carbon fibers, graphene fibers, and graphene composite fibers.

25. The micro-current cloth according to claim 8, wherein the positive conductive strips and the negative conductive strips are printed or brushed independently from each other by conductive paste.

26. The micro-current fabric of claim 25, wherein the conductive paste is a conductive silver paste.

27. The micro-current cloth of claim 1, wherein the cloth is any 1 of circular, semicircular or crescent-shaped.

28. A garment comprising the microcurrent fabric of any one of claims 1 to 27.

29. The garment of claim 28, wherein the garment is a body-fitting garment, preferably any 1 of a body-fitting sling, vest, tights, pants, or pajamas.

30. A bedding article, comprising any 1 or at least 2 combinations of quilts, bed sheets, pillows, pillow cases and quilt covers, characterized in that the side of the bedding article close to human body contains the micro-current cloth material of any one of claims 1 to 27.

31. A mat characterized in that the surface of the mat contains the micro-current cloth according to any one of claims 1 to 27.

32. A kit comprising the bedding article of claim 30 and an intimate wear garment capable of conducting electricity, said garment being in contact with the bedding article during use of the kit.

33. A kit comprising the pad of claim 31 and a body-mountable electrically conductive garment in contact with the pad during use of the kit.