CN205674626U - Intelligent temperature control Graphene yarn fabric - Google Patents

Abstract

The open a kind of intelligent temperature control Graphene yarn fabric of the utility model, the problem being unsuitable for providing heat for clothes mainly for existing heating, propose a kind of intelligent temperature control Graphene yarn fabric, including the first insulating barrier setting gradually, conductive layer, the second insulating barrier, thermometric layer, fixed bed and cover layer；The conductive warp yarn of conductive layer and conductive warp yarns are conductive graphene fiber；Conductive graphene fiber includes strand and strand conductive coating；Strand includes the conductive graphene monofilament of two or more than two, and conductive graphene monofilament includes monofilament long fibre and monofilament conductive coating；If thermometric layer is the dry temperature sensor that array is arranged；Fixed bed includes stationary warp and fixing weft yarn；Temperature sensor lead as warp thread or weft yarns in fixed bed.First insulating barrier, conductive layer, the second insulating barrier, thermometric layer, fixed bed are together with cover bonding.The utility model heating is uniformly, conductive capability is strong, soft pliable is folded, comfortableness is good.

Description

Intelligent temperature control graphene textile

Technical Field

The utility model relates to an electrical heating fabric, specific intelligence accuse temperature graphite alkene fabric that says so.

Background

Winter in northern China is very cold, and in cold winter, warm-keeping clothes are necessary articles for people. In the traditional thermal clothes, thermal materials such as cotton, down and the like are filled in the clothes. The thermal garment reduces air flow inside and outside the garment, i.e., reduces heat loss from the body, thereby enabling the body to resist cold. However, if the temperature drops to a certain degree, the temperature of the human body cannot be sufficiently ensured by the thermal clothes. Later, electric heating article appeared, and people added the resistance wire in the clothing, produced the heat through the resistance wire to, guarantee that the temperature in the clothing keeps in certain temperature range, however, the resistance wire sets up in the clothing, can greatly reduced the travelling comfort of clothing, in addition, set up behind the resistance wire in the clothing, the clothing also can not be random folding, and it is very inconvenient to use.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides an intelligence control by temperature change graphite alkene fabric that the travelling comfort is high, soft easily folding.

In order to achieve the above object, the utility model discloses intelligence control by temperature change graphite alkene fabric, its characterized in that: the temperature-measuring device comprises a first insulating layer, a conducting layer, a second insulating layer, a temperature-measuring layer, a fixing layer and a covering layer which are sequentially arranged; wherein,

the conductive layer comprises conductive warp yarns and conductive weft yarns; the conductive warp yarns and the conductive weft yarns are conductive graphene fibers; the conductive graphene fiber comprises a strand and a strand conductive coating wrapped on the outer surface of the strand; the folded yarn comprises two or more than two conductive graphene monofilaments, and each conductive graphene monofilament comprises a monofilament long fiber and a monofilament conductive coating wrapped on the outer surface of the monofilament long fiber; the monofilament conductive coating and the plied yarn conductive coating respectively comprise a plurality of sheets of layered graphene, a plurality of granular conductive carbon blacks embedded among the sheets of the graphene, and acrylic resin used for bonding the graphene and the conductive carbon blacks;

the temperature measuring layer is a plurality of temperature sensors arranged in an array;

the fixing layer comprises fixing warp yarns and fixing weft yarns; the fixed warp comprises temperature sensor wires and insulating fibers which are alternately arranged, and the fixed weft is made of the insulating fibers; or the fixed warp yarns are insulating fibers, and the fixed weft yarns are temperature sensor conducting wires and insulating fibers which are alternately arranged;

the first insulating layer, the conducting layer, the second insulating layer, the temperature measuring layer, the fixing layer and the covering layer are bonded together.

Furthermore, the warp yarns or the weft yarns of the conductive layers further comprise a plurality of electrode wires, and the electrode wires and the conductive graphene fibers are arranged alternately.

Further, the temperature sensor is electrically connected with a controller, and the controller, the power supply and the conducting layer are connected in series to form a closed loop.

Further, the opposite sides of the conductive layer are connected with wires, or the electrode wires of the conductive layer are connected with wires.

Furthermore, the temperature sensor wires in the same row or the same column are arranged in sequence, and a minimum of 15 insulating fibers are arranged between every two adjacent temperature sensor wires.

Further, the cover layer comprises cover warp yarns and cover weft yarns, and the cover warp yarns and the cover weft yarns are insulating fibers.

Further, the warp yarns and the weft yarns of the first insulating layer, the second insulating layer, the fixing layer and the covering layer are all profiled fibers.

Furthermore, the first insulating layer, the conducting layer, the second insulating layer, the temperature measuring layer, the fixing layer and the covering layer are penetrated through by water guide fibers, the water guide fibers are C-shaped fibers, and the water guide fibers are insulating fibers.

Further, still include humidity transducer, humidity transducer is the array setting, humidity transducer coats and is stamped the skin-friendly layer.

Further, the skin-friendly layer is woven by pure cotton fibers.

The utility model discloses the conducting layer of intelligence control by temperature change graphite alkene fabric adopts graphite alkene fibre to weave, and is softer comfortable than current fabric soft comfortable with resistance wire heat production, can fold repeatedly and do not take place to damage long service life. Additionally, the utility model discloses a monofilament conductive coating and strand conductive coating all adopt flake graphite alkene as the skeleton, fill conductive carbon black granule between flake graphite alkene skeleton to, can form and use flake graphite alkene as conductive skeleton, use conductive carbon black granule as the conductive node's conductive skeleton, thereby, its electric conductivity is stronger than the electric conductivity of prior art's resistance wire greatly, and consequently, its ability that produces heat is stronger than current resistance wire far away. In addition, because its electric conductivity is stronger than the electric conductivity of current resistance wire, consequently, the utility model discloses compare with current resistance wire, still have energy-conserving effect.

Drawings

Fig. 1 is the layered structure of the intelligent temperature control graphene textile fabric of the present invention.

Detailed Description

The invention is further described with reference to the accompanying drawings.

Example 1

As shown in fig. 1, the intelligent temperature-controlled graphene textile fabric of the present embodiment includes a first insulating layer 6, a conductive layer 5, a second insulating layer 4, a temperature-measuring layer, a fixing layer 2, and a covering layer 1, which are sequentially disposed; wherein,

the conductive layer 5 comprises conductive warp yarns and conductive weft yarns; the conductive warp yarns and the conductive weft yarns are conductive graphene fibers; the conductive graphene fiber comprises a strand and a strand conductive coating wrapped on the outer surface of the strand; the folded yarn comprises two or more than two conductive graphene monofilaments, and each conductive graphene monofilament comprises a monofilament long fiber and a monofilament conductive coating wrapped on the outer surface of the monofilament long fiber; the monofilament conductive coating and the plied yarn conductive coating respectively comprise a plurality of sheets of layered graphene, a plurality of granular conductive carbon blacks embedded among the sheets of the graphene, and acrylic resin used for bonding the graphene and the conductive carbon blacks;

the temperature measuring layer is a plurality of temperature sensors 3 arranged in an array;

the fixed layer 2 comprises fixed warp yarns and fixed weft yarns; the fixed warp comprises temperature sensor 3 conducting wires and insulating fibers which are alternately arranged, and the fixed weft is made of the insulating fibers; or the fixed warp yarns are insulating fibers, and the fixed weft yarns are temperature sensor 3 conducting wires and insulating fibers which are alternately arranged;

the first insulating layer 6, the conducting layer 5, the second insulating layer 4, the temperature measuring layer, the fixing layer 2 and the covering layer 1 are bonded together. The opposite sides of the conductive layer 5 are connected to wires. The cover layer 1 includes cover warp yarns and cover weft yarns, both of which are insulating fibers.

The conducting layer 5 of this embodiment intelligence control by temperature change graphite alkene fabric adopts the graphite alkene fibre to weave, and is softer comfortable than current fabric soft comfortable with resistance wire production heat, can fold repeatedly and do not take place to damage long service life. Additionally, the utility model discloses a monofilament conductive coating and strand conductive coating all adopt flake graphite alkene as the skeleton, fill conductive carbon black granule between flake graphite alkene skeleton to, can form and use flake graphite alkene as conductive skeleton, use conductive carbon black granule as the conductive node's conductive skeleton, thereby, its electric conductivity is stronger than the electric conductivity of prior art's resistance wire greatly, and consequently, its ability that produces heat is stronger than current resistance wire far away. In addition, because its conducting power is stronger than the conducting power of current resistance wire, consequently, the intelligence control by temperature change graphite alkene textile of this embodiment still has energy-conserving effect with current resistance wire.

Because the intelligent temperature control graphene textile fabric of the embodiment is conductive and generates heat for the whole fabric, when the intelligent temperature control graphene textile fabric is electrified, the heat generation of the fabric is uniform, and the intelligent temperature control graphene textile fabric does not generate heat locally like resistance wire.

Example 2

On the basis of the above embodiment, the warp or weft of the conductive layer 5 further includes a plurality of electrode wires, and the electrode wires and the conductive graphene fibers are alternately arranged. The electrode wire of the conductive layer 5 is connected with a lead.

This embodiment adds the electrode line in the warp or the woof of conducting layer 5, when the intelligence accuse temperature graphite alkene fabric of this embodiment of needs produced heat, is connected the positive negative pole of electrode line and power, just can make conducting layer 5 produce heat, connects conveniently.

Example 3

On the basis of the above embodiment, the temperature sensor 3 is electrically connected to a controller, and the controller, a power supply and the conductive layer 5 are connected in series to form a closed loop.

The voltage or the current of the intelligent temperature control graphene textile fabric of the embodiment utilizes the controller to control the conducting layer 5, so that the heat emitted by the conducting layer 5 can be controlled, and the current temperature can be measured by the temperature sensor 3, so that the basis for controlling the conducting layer 5 to generate heat can be provided for the controller.

Example 4

On the basis of the above embodiment, the temperature sensor 3 wires in the same row or the same column are arranged in sequence, and the minimum interval between two adjacent temperature sensor 3 wires is 15 insulating fibers.

Arrange the 3 wires of temperature sensor in same line or same row in order, what the signal that finds that which wire conduction is derived that which sensor measured that can be accurate, the temperature situation of each position of the intelligent accuse temperature graphite alkene fabric of this embodiment that can be accurate. In addition, when current flows through the wire, a magnetic field is generated, and the magnetic field influences the flow of the current in the wire. Therefore, adjacent wires are arranged at intervals, and mutual influence between the adjacent wires is weakened.

Example 5

On the basis of the above embodiment, the warp and weft yarns of the first insulating layer 6, the second insulating layer 4, the fixing layer 2 and the cover layer 1 are all profiled fibers. The first insulating layer 6, the conducting layer 5, the second insulating layer 4, the temperature measuring layer, the fixing layer 2 and the covering layer 1 penetrate through water guide fibers, the water guide fibers are C-shaped fibers, and the water guide fibers are insulating fibers.

The fibre of this embodiment with each layer all adopts the dysmorphism fibre to adopt C shape fibre to run through each layer, can derive the sweat on human surface, thereby can improve the comfort level of fabric. Under the action of the surface tension of sweat, when the C-shaped fibers lead out the sweat and pass through the conductive layer 5, the sweat cannot contact the conductive layer 5, and the problem of wetting the conductive layer 5 cannot occur.

Example 6

On the basis of the embodiment, the humidity sensor is further included and arranged in an array mode, and the humidity sensor is covered with the skin-friendly layer. The skin-friendly layer is woven by pure cotton fibers.

This embodiment sets up humidity transducer, can judge whether human surface perspires through the humidity on surface fabric top layer to for the regulation of temperature provides another index, set up the close skin layer that pure cotton fiber was made into on humidity transducer, comfort level when can improving human dress.

The above is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope defined by the claims.

Claims (10)

1. The utility model provides an intelligence control by temperature change graphite alkene fabric which characterized in that: the temperature-measuring device comprises a first insulating layer, a conducting layer, a second insulating layer, a temperature-measuring layer, a fixing layer and a covering layer which are sequentially arranged; wherein,

the conductive layer comprises conductive warp yarns and conductive weft yarns; the conductive warp yarns and the conductive weft yarns are conductive graphene fibers; the conductive graphene fiber comprises a strand and a strand conductive coating wrapped on the outer surface of the strand; the folded yarn comprises two or more than two conductive graphene monofilaments, and each conductive graphene monofilament comprises a monofilament long fiber and a monofilament conductive coating wrapped on the outer surface of the monofilament long fiber; the monofilament conductive coating and the plied yarn conductive coating respectively comprise a plurality of sheets of layered graphene, a plurality of granular conductive carbon blacks embedded among the sheets of the graphene, and acrylic resin used for bonding the graphene and the conductive carbon blacks;

the temperature measuring layer is a plurality of temperature sensors arranged in an array;

the fixing layer comprises fixing warp yarns and fixing weft yarns; the fixed warp comprises temperature sensor wires and insulating fibers which are alternately arranged, and the fixed weft is made of the insulating fibers; or the fixed warp yarns are insulating fibers, and the fixed weft yarns are temperature sensor conducting wires and insulating fibers which are alternately arranged;

the first insulating layer, the conducting layer, the second insulating layer, the temperature measuring layer, the fixing layer and the covering layer are bonded together.

2. The intelligent temperature-controlled graphene textile fabric according to claim 1, wherein: the warp yarns or the weft yarns of the conducting layers further comprise a plurality of electrode wires, and the electrode wires and the conducting graphene fibers are arranged alternately.

3. The intelligent temperature-controlled graphene textile fabric of claim 1 or 2, wherein: the temperature sensor is electrically connected with the controller, and the controller, the power supply and the conducting layer are connected in series to form a closed loop.

4. The intelligent temperature-controlled graphene textile fabric according to claim 3, wherein: and the two opposite sides of the conducting layer are connected with a lead, or the electrode wire of the conducting layer is connected with the lead.

5. The intelligent temperature-controlled graphene textile fabric according to claim 1, wherein: the temperature sensor leads in the same row or the same column are arranged in sequence, and at least 15 insulating fibers are arranged between every two adjacent temperature sensor leads at intervals.

6. The intelligent temperature-controlled graphene textile fabric according to claim 1, wherein: the cover layer includes cover warp yarns and cover weft yarns, both of which are insulating fibers.

7. The intelligent temperature-controlled graphene textile fabric according to claim 1, wherein: the warp yarns and the weft yarns of the first insulating layer, the second insulating layer, the fixing layer and the covering layer are all profiled fibers.

8. The intelligent temperature-controlled graphene textile fabric according to claim 7, wherein: the first insulating layer, the conducting layer, the second insulating layer, the temperature measuring layer, the fixing layer and the covering layer penetrate through water guide fibers, the water guide fibers are C-shaped fibers, and the water guide fibers are insulating fibers.

9. The intelligent temperature-controlled graphene textile fabric according to claim 1, wherein: still include humidity transducer, humidity transducer is the array setting, humidity transducer coats and is stamped close skin layer.

10. The intelligent temperature-controlled graphene textile fabric according to claim 9, wherein: the skin-friendly layer is woven by pure cotton fibers.