CN105615237A - Marcel waver - Google Patents

Abstract

The invention discloses a marcel waver. The marcel waver comprises a bracket, a graphene layer, a heat conduction layer and an electric power storage device, wherein the bracket comprises a first mounting part and a second mounting part; the graphene layer and the heat conduction layer are arranged at the first mounting part; the graphene layer is covered with the heat conduction layer; the electric power storage device is arranged at the second mounting part and electrically connected with the graphene layer. The marcel waver adopts graphene as a heating material and is not required to be driven by alternating current of a mains supply or circuits such as a battery boost circuit and the like for heating, so that energy is saved, the marcel waver is safe and convenient to use and applicable to outdoor use, and a human body feels comfortable.

Description

Marcel waver

Technical field

The present invention relates to Hair Equipment field, particularly relate to a kind of marcel waver.

Background technology

Marcel waver generally includes heater of hair straightener, curler, comb etc., is used for stretching hair, scalding volume head or other moulding effect. Such as, heater of hair straightener can be passed through two clamping plate of high-temperature heating, and clamping hair also makes hair slide between two clamping plate, and high-temperature heating can make hair qualitative in addition, so that hair fixing becomes straight hair. In existing marcel waver, the alternating current of 110V or 220V is mostly adopted to drive it to generate heat, adopt ceramic material as heater, traditional material exothermic material is generally point-like heating and wire heating, if electric furnace heating wire, carbon fiber exothermic part are linear heating element, generating heat uneven, during use, comfort level is bad. Owing to needing to adopt the alternating current of 110V or 220V, therefore, when using marcel waver generally marcel waver is plugged in mains supply, and in the process using marcel waver, marcel waver and human contact, it is easy to accidents caused; Additionally, due to the marcel waver of prior art needs to adopt the alternating current of 110V or 220V, because there being power line to connect during use, it is impossible at will walk about; When outdoor, for instance when tourism, countryside shooting etc. are without commercial power supply, it is impossible to use marcel waver to carry out hair caring, it is difficult to realize the demand for experience of user, or make troubles to shooting work.

Summary of the invention

The technical problem to be solved is in that, it is provided that a kind of marcel waver, and described marcel waver drives heating without mains electricity, saves the energy, easy to use, safe, comfortable, and is suitable for outdoor application.

In order to solve above-mentioned technical problem, the present invention by the following technical solutions:

Adopt Graphene as exothermic material, just can generate heat in more than 3V power drives, so, adopt common lithium battery, it is not necessary to through circuit conversion, such as booster circuit, just can directly drive heating, save the ability of loss during circuit conversion, and the accident that high-voltage electric leakage hurts sb.'s feelings can be avoided. Easy to use, the pullling without be overwhelmed by power line when indoor use, it is also possible to use when outdoor is without commercial power supply.

Graphene exothermic material is the exothermic material of a kind of plane, and heating uniformly, during use, has the advantage making people's body-sensing comfortable.

The present invention provides a kind of marcel waver, described marcel waver includes support, graphene layer, heat-conducting layer and electrical storage device, described support includes the first installation portion and the second installation portion, described graphene layer and described heat-conducting layer are arranged at described first installation portion, described heat-conducting layer is covered on described graphene layer, described electrical storage device is arranged at described second installation portion, and described graphene layer is electrically connected with described electrical storage device.

Wherein, described marcel waver also includes heat-insulation layer, and described heat-insulation layer is arranged at described first installation portion, and is positioned at the surface away from described heat-conducting layer of described graphene layer.

Wherein, described marcel waver also includes temperature sensor, and described temperature sensor is arranged between described graphene layer and described heat-conducting layer.

Wherein, described marcel waver also includes power interface, described electrical storage device includes electric power management circuit and accumulator, described power interface receives from outside alternating current or unidirectional current, and flow to described electric power management circuit, described electric power management circuit charges for described accumulator after described alternating current or unidirectional current carry out the process such as rectifying and voltage-stabilizing.

Wherein, described marcel waver also includes control panel and control circuit, described second installation portion is in the shell structure with cavity, described control circuit is arranged in the cavity of described second installation portion, and be connected with described electrical storage device, described control panel is embedded in the outer surface of the housing of described second installation portion, and described control panel is connected with described control circuit.

Wherein, the inputting interface of described control panel is the structure touching display screen in conjunction with physical button, or physical button is in conjunction with the structure of LCD or LED.

Wherein, described control circuit includes CPU and heat driven circuit, described CPU receives the call for heat of described control panel, read the current temperature value of described temperature sensor, and current temperature value and target temperature value are compared, if current temperature value is lower than target temperature value, described CPU opens described heat driven circuit, so that described accumulator provides electric energy to be heated for described graphene layer; If current temperature value equals to or higher than target temperature value, described CPU then closes described heat driven circuit.

Wherein, described heat-conducting layer being provided with multiple comb, the material of described comb is Heat Conduction Material.

Wherein, described comb and described heat-conducting layer are non-removable integral structure.

Wherein, one end away from described heat-conducting layer of described comb is in sphere.

Wherein, each described comb being provided with a tooth set, described tooth set is placed on one end away from described heat-conducting layer of described comb, and the shape of described tooth set is consistent with the shape away from one end of described heat-conducting layer of described comb.

Wherein, described marcel waver also includes tooth set, described tooth set includes tooth set main body and multiple shape sub-set consistent with the shape of described comb, the corresponding comb of each described sub-set, each described sub-set is fixed in described tooth set main body, described sub-set is placed on described comb, and described tooth set main body covers described heat-conducting layer.

Wherein, described sub-set becomes non-removable integral structure with described tooth set main body.

Wherein, described first installation portion is in the shell structure with cavity, and described heat-insulation layer is sheathed on the outer surface of described first installation portion, and described graphene layer is sheathed on the outer surface of described heat-insulation layer, and described heat-conducting layer is sheathed on the outer surface of described graphene layer.

Wherein, the two ends of described first installation portion are respectively arranged with auxiliary heat-insulation layer, and described auxiliary heat-insulation layer is by the closed at both ends of described first installation portion.

Wherein, train wheel bridge and lower plate, one end of described train wheel bridge and one end of described lower plate that described marcel waver includes relatively and arranges are connected by a junction, and described train wheel bridge and described lower plate can be rotated by described connecting portion and close to each other, first installation portion of described marcel waver includes the first sub-installation portion and the second sub-installation portion, and described first sub-installation position is in one end away from described connecting portion of described train wheel bridge, and the second sub-installation position is in one end away from connecting portion of described lower plate, described graphene layer includes the first graphene layer and the second graphene layer, described heat-conducting layer includes the first heat-conducting layer and the second heat-conducting layer, described heat-insulation layer includes the first heat-insulation layer and the second heat-insulation layer, described first heat-insulation layer, described first graphene layer and described first heat-conducting layer are cascadingly set on described first sub-installation portion, described second heat-insulation layer, described second graphene layer and described second heat-conducting layer are cascadingly set on described second sub-installation portion, when described train wheel bridge and described lower plate rotate and close to each other time, make described first heat-conducting layer and described second heat-conducting layer laminating.

Wherein, described first installation portion of described support has relative first surface and second surface, described graphene layer includes the first graphene layer and the second graphene layer, described heat-conducting layer includes the first heat-conducting layer and the second heat-conducting layer, described heat-insulation layer includes the first heat-insulation layer and the second heat-insulation layer, be cascading on described first surface described first heat-insulation layer, described first graphene layer and described first heat-conducting layer, described second heat-insulation layer that described second surface is cascading, described second graphene layer and described second heat-conducting layer.

Compared with prior art, technical scheme at least has the advantages that the marcel waver of the present invention includes support, graphene layer, heat-conducting layer and electrical storage device, and described graphene layer is electrically connected with described electrical storage device. Owing to the marcel waver of the present invention have employed graphene layer exothermic material, only need the power supply of more than 3V that graphene layer heating can be driven to reach the temperature value needed for hair caring, during as adopted lithium battery power supply, do not need additional boost circuit to consume the energy, saved the energy; Owing to have employed Graphene exothermic material, it adopts plane glow mode, has the uniform feature of heating, and during use, body-sensing is comfortable. In addition, owing to only needing the power supply of more than 3V that graphene layer can be driven to generate heat, therefore, in use procedure very safe, further, electric power is provided owing to the marcel waver of the present invention is also provided with accumulator, therefore, the pullling without be overwhelmed by power line when indoor use, it is also possible to use when outdoor is without commercial power supply.

Accompanying drawing explanation

In order to be illustrated more clearly that the embodiment of the present invention or technical scheme of the prior art, the accompanying drawing used required in embodiment or description of the prior art will be briefly described below, apparently, accompanying drawing in the following describes is only some embodiments of the present invention, for those of ordinary skill in the art, under the premise not paying creative work, it is also possible to obtain other accompanying drawing according to these accompanying drawings.

Fig. 1 a is the structural representation of marcel waver in first embodiment of the invention;

Fig. 1 b is the structural representation of first embodiment of the invention medium-height trestle;

Fig. 1 c is the electrical block diagram of marcel waver in first embodiment of the invention;

Fig. 2 is the structural representation of marcel waver in second embodiment of the invention;

Fig. 3 is the structural representation of marcel waver in third embodiment of the invention;

Fig. 4 is the structural representation of marcel waver in fourth embodiment of the invention;

Fig. 5 a is the structural representation of marcel waver in fifth embodiment of the invention;

Fig. 5 b be fifth embodiment of the invention another embodiment in the structural representation of marcel waver;

Fig. 6 is the structural representation of marcel waver in sixth embodiment of the invention;

Fig. 7 is the structural representation of marcel waver in seventh embodiment of the invention.

Detailed description of the invention

Below in conjunction with the accompanying drawing in the embodiment of the present invention, the technical scheme in the embodiment of the present invention is clearly and completely described, it is clear that described embodiment is only a part of embodiment of the present invention, rather than whole embodiments. Based on the embodiment in the present invention, the every other embodiment that those of ordinary skill in the art obtain under not making creative work premise, broadly fall into the scope of protection of the invention.

It is the structural representation of marcel waver in first embodiment of the invention referring to Fig. 1 a and Fig. 1 b, Fig. 1 a; Fig. 1 b is the structural representation of first embodiment of the invention medium-height trestle. Marcel waver in first embodiment of the invention includes support 100, graphene layer 200, heat-conducting layer 300 and electrical storage device 400. Described graphene layer 200, as the heater of described marcel waver, provides heat for described heat-conducting layer 300, and described heat-conducting layer 300 for providing heat and chucking power for hair caring process, in order to hair is heated sizing in hair caring process. Described support 100 includes the first installation portion 110 and the second installation portion 120, described graphene layer 200 and described heat-conducting layer 300 are arranged at described first installation portion 110, described heat-conducting layer 300 is covered on described graphene layer 200, described electrical storage device 400 is arranged at described second installation portion 120, and described graphene layer 200 is electrically connected with described electrical storage device 400.

Specifically, the joining place of described first installation portion 110 and described second installation portion 120 has the first side wall 111, namely one end of described first installation portion 110 has described the first side wall 111, the other end relative with described the first side wall 111 of described first installation portion 110 has the second sidewall 112, and the bottom surface 113 of described the first side wall 111, described second sidewall 112 and described first installation portion 110 is interconnected to form an accommodation space 114. Described graphene layer 200 and described heat-conducting layer 300 are arranged in described accommodation space 114, and namely described graphene layer 200 and described heat-conducting layer 300 are contained in described first installation portion 110. Described graphene layer 200 can be arranged on the bottom surface 113 of described first installation portion 110, fits with described bottom surface 113, and described graphene layer 200 can also keep certain distance with described bottom surface 113, can adopt therebetween and have elastic implant.

In the another embodiment of the present embodiment, described marcel waver can also include heat-insulation layer 500, described heat-insulation layer 500 is arranged at described first installation portion 110, and it is positioned at the surface away from described heat-conducting layer 300 of described graphene layer 200, to reduce the waste of heat produced by described graphene layer 200, described heat-conducting layer 300 is made to make full use of heat produced by described graphene layer 200. Described heat-insulation layer 500, described graphene layer 200 and described heat-conducting layer 300 are cascadingly set in described accommodation space 114, and namely described heat-insulation layer 500, graphene layer 200 and described heat-conducting layer 300 are contained in described first installation portion 110. Described heat-insulation layer 500 can be arranged on the bottom surface 113 of described first installation portion 110, and fit with described bottom surface 113, described heat-insulation layer 500 can also keep certain distance with described bottom surface 113, and is individually fixed at two ends on described the first side wall 111 and the second sidewall 112.

Further, marcel waver described in the present embodiment also includes the first auxiliary heat-insulation layer 510 and the second auxiliary heat-insulation layer 520, described first auxiliary heat-insulation layer 510 is arranged between described the first side wall 111 and described graphene layer 200, and described second auxiliary heat-insulation layer 520 is arranged between described second sidewall 112 and described graphene layer 200. First auxiliary heat-insulation layer 510 and the second auxiliary heat-insulation layer 520 reduce scattering and disappearing of the heat of described graphene layer 200 further, so that described heat-conducting layer 300 utilizes the heat of described graphene layer 200 more fully.

Described heat-conducting layer 300 can be metal, alloy, tourmaline ceramic or polymer composite etc., for instance ferrum, aluminium alloy or synthetic plastic etc.

In the present embodiment (first embodiment), described marcel waver also includes temperature sensor 600, described temperature sensor 600 is arranged between described graphene layer 200 and described heat-conducting layer 300, the operating temperature current for sensing described marcel waver, is beneficial to control the temperature that hair caring process adopts.

See also Fig. 1 a, Fig. 1 b and Fig. 1 c, Fig. 1 a is the structural representation of marcel waver in first embodiment of the invention; Fig. 1 b is the structural representation of first embodiment of the invention medium-height trestle; Fig. 1 c is the electrical block diagram of marcel waver in first embodiment of the invention. Described marcel waver also includes power interface 700, described electrical storage device 400 includes electric power management circuit 410 and accumulator 420, described power interface 700 receives from outside alternating current or unidirectional current, and flow to described electric power management circuit 410, after described alternating current or unidirectional current are carried out voltage stabilizing by described electric power management circuit 410, charge for described accumulator 420, in order to provide power supply for whole described marcel waver, provide power supply including for described graphene layer 200.

In the present embodiment, described second installation portion 120 is the tubular shell with cavity 121, described power interface 700 is arranged at one end away from described first installation portion 110 of described second installation portion 120, described electrical storage device 400 is arranged in described cavity 121, and is electrically connected with described power interface 700.

Described marcel waver also includes control panel 800 and control circuit 900, and described control circuit 900 is arranged at the cavity 121 of described second installation portion 120, and is connected with described electrical storage device 400. Described control panel 800 is embedded in the sidewall of the tubular shell of described second installation portion 120, or described control panel 800 is arranged at the outer surface of tubular shell of described second installation portion 120, and described control panel 800 is electrically connected with described control circuit 900. The inputting interface of described control panel 800 can be the structure touching display screen in conjunction with physical button, or physical button is in conjunction with the structure of LCD or LED.

Specifically, referring to Fig. 1 c, described control circuit 900 includes CPU 910 and heat driven circuit 920. Described CPU 910 receives the call for heat of described control panel 800, read the current temperature value of described temperature sensor 600, and current temperature value and target temperature value are compared, if current temperature value is lower than target temperature value, then described CPU 910 opens described heat driven circuit 920, so that described accumulator 420 provides electric energy for described graphene layer 200, described graphene layer 200 is made to generate heat and heat up; If current temperature value equals to or higher than target temperature value, described CPU 910 then closes described heat driven circuit 920, stops providing electric energy for described graphene layer 200 so that it is no longer heat up. So that the working temperature constant of described marcel waver is target temperature, to obtain the preference temperature needed for hair caring process. In hair caring process, being wound on described first installation portion 110 with the form looped by hair, described graphene layer 200 transfers heat to described heat-conducting layer 300, hair is heated by described heat-conducting layer 300, so that curly headed, now, described marcel waver is curler.

Further, the described heat-conducting layer 300 of marcel waver described in the present embodiment (first embodiment) being provided with multiple comb 330, the material of described comb 330 is the Heat Conduction Materials such as metal, alloy, tourmaline ceramic or polymer composite. Described comb is in the structure being similar to triangle, and wherein a limit connects with described heat-conducting layer 300, and the diagonal angle corresponding to this limit is then away from described heat-conducting layer 300, and described diagonal angle can be fillet. Additionally, the shape of described comb 330 can be fine strip shape. Described comb 330 can be detachably be arranged on described heat-conducting layer 300. In other embodiment, described comb 330 can be non-removable integral structure with described heat-conducting layer. Hair can be held between described comb 330, in the process of hair caring, described hair is placed between warmed-up comb 330, in the process of mobile described marcel waver, hair slips between described comb 330, and the hair slipped over is played heating and the effect of clamping by adjacent two comb 330, so that hair is straightened, now, described marcel waver is heater of hair straightener. Such as, arranging target temperature is certain value within the scope of 80��230 DEG C, provides electric energy with electrical storage device 400 for graphene layer 200, heat is passed to the heat-conducting layer 300 fitted tightly with it by graphene layer 200, making heat-conducting layer 300 heat up, so that comb 330 heats up, high temperature can make hair fixing. Comb 330 has heat conductivility, and the bottom of comb 330 and heat-conducting layer 300 compact siro spinning technology, temperature is higher, when hair slips between adjacent two comb 330, majority is positioned at bottom, and the top of comb 330 is from heat-conducting layer 300 farther out, temperature is relatively low, the top often contacted with human skin, is not easily burned during the contact of such human skin. The spacing of comb 330 is less, when combing hair, naturally hair can be clamped, thus hair is stretched.

When described graphene layer 200 not being heated, described heat-conducting layer 300 and comb 330 are also unheated, and now, described marcel waver can serve as comb and use.

Furthermore, it is possible to be that to arrange target temperature be a value within the scope of 40��80 DEG C to described marcel waver by described control panel 800, after heating, combing hair or massage head, have the effect at massaging skin and acupuncture point.

In the present embodiment, described marcel waver includes support, graphene layer, heat-conducting layer and electrical storage device, and described graphene layer is electrically connected with described electrical storage device. Owing to the marcel waver of the present invention have employed graphene layer exothermic material, only need the power supply of more than 3V that graphene layer heating can be driven to reach the temperature value needed for hair caring, during as adopted lithium battery power supply, do not need additional boost circuit to consume the energy, saved the energy; Owing to have employed Graphene exothermic material, it adopts plane glow mode, has the uniform feature of heating, and during use, body-sensing is comfortable. Additionally, due to only need the power supply of more than 3V that graphene layer can be driven to generate heat, therefore, in use procedure very safe, and, owing to the marcel waver of the present invention is also provided with accumulator, the power supply that can provide more than 3V is heated, and therefore, it can use when outdoor is without commercial power supply.

Referring to Fig. 2, Fig. 2 is the structural representation of marcel waver in second embodiment of the invention. The structure of the marcel waver in the present embodiment (the second embodiment) is essentially identical with the structure of the marcel waver described in first embodiment, it is different in that: the marcel waver described in the present embodiment also includes tooth set 331, and described tooth set 331 includes tooth set main body 3311 and multiple shape sub-set 3312 consistent with the shape of described comb 330. The part that in figure, broken box surrounds represents tooth set main body 3311. The corresponding comb 330 of each described sub-set 3312, each described sub-set 3312 is fixed in described tooth set main body 3311, described sub-set is placed on described comb 330, is coated with described comb 330, and described tooth set main body 3311 covers the surface of described heat-conducting layer 300. The material of described tooth set can be high molecular synthetic material etc., such as synthetic plastic. Described tooth set 331 can disassemble from described heat-conducting layer 300 and described comb 330, and user can select band tooth set carry out hair caring or carry out hair caring without tooth set.

In the present embodiment, owing to described marcel waver also includes tooth set 331, described tooth set 331 covers the surface of described heat-conducting layer 300 and described comb 330, so that in the process using marcel waver, human body will not directly contact the Heat Conduction Material of high temperature, it is prevented that scalds.

Referring to Fig. 3, Fig. 3 is the structural representation of marcel waver in third embodiment of the invention. The structure of marcel waver described in the present embodiment (the 3rd embodiment) is essentially identical with the structure of the marcel waver in the second embodiment, it is different in that: the present embodiment is provided with on each comb of marcel waver a tooth set 331, described tooth set 331 is placed on one end away from described heat-conducting layer 300 of described comb 330, and the shape of described tooth set 331 is consistent with the shape away from one end of described heat-conducting layer 300 of described comb 330. Namely described tooth overlaps 331 tip portion being coated with described comb 330, makes the comb 330 that employing Heat Conduction Material is made remain to keep high temperature, to ensure fixed effect.

Marcel waver in the present embodiment is owing to being provided with a tooth set 331 on each comb, and 331 one end away from described heat-conducting layer 300 being placed on described comb 330 of described tooth set, namely described tooth overlaps 331 tip portion being coated with described comb 330, thus preventing described marcel waver from making comb 330 remain to keep high temperature while scalding human body, it is ensured that heat-shaping effect.

Referring to Fig. 4, Fig. 4 is the structural representation of marcel waver in fourth embodiment of the invention. The structure of marcel waver described in the present embodiment (the 4th embodiment) is essentially identical with the structure of the marcel waver in the 3rd embodiment, is different in that: one end away from described heat-conducting layer 300 of all or part of comb 330 of the marcel waver described in the present embodiment is in sphere. Fig. 4 illustrates that one end away from described heat-conducting layer 300 of a part of comb 330 is in sphere. Owing to described spheroid is curved surface, so not easily injured when encountering human body; Additionally, when described marcel waver is used for massaging head, make human body feel more comfortable.

Referring to Fig. 5 a, Fig. 5 a is the structural representation of marcel waver in fifth embodiment of the invention. The structure of marcel waver described in the present embodiment (the 5th embodiment) is essentially identical with the structure of the marcel waver in the 4th embodiment, it is different in that: described first installation portion 110 is in the shell structure with cavity, described heat-insulation layer 500 is sheathed on the outer surface of described first installation portion 110, described graphene layer 200 is sheathed on the outer surface of described heat-insulation layer 500, and described heat-conducting layer 300 is sheathed on the outer surface of described graphene layer 200. Specifically, described first installation portion 110 can be cylindrical shape, oval column or the shell structure such as rectangular-shaped. Such as, when described first installation portion 110 is in cylindrical shape, at the surface configuration one layer of heat preservation layer 500 of described first installation portion 110, then described heat-insulation layer 500 is cylindrically. The outer surface of described heat-insulation layer 500 cylindrically is coated with by graphene layer 200, and the outer surface of described graphene layer 200 is coated with by described heat-conducting layer 300, so that heat-conducting layer 300 is also cylindrically. So, it is possible to increase the contact area of described heat-conducting layer and hair, so that when described marcel waver is as curler curly hair better effects if.

Referring to Fig. 5 b, Fig. 5 b is the structural representation of marcel waver in fifth embodiment of the invention another embodiment. In another embodiment of the present embodiment, the surface of the heat-conducting layer 300 of described cylindrical shape is additionally provided with comb 330, and one end away from described heat-conducting layer 300 of all or part of described comb 330 is in sphere. . Hair can be held between described comb 330, in the process of hair caring, described hair is placed between warmed-up comb 330, in the process of mobile described marcel waver, hair slips between described comb 330, and the hair slipped over is played heating and the effect of clamping by adjacent two comb 330, so that hair is straightened, now, described marcel waver is heater of hair straightener. Simultaneously as described spheroid is curved surface, so not easily injured when encountering human body; Additionally, when described marcel waver is used for massaging head, make human body feel more comfortable. In the present embodiment, described comb 330 can also is that triangular shaped or subtriangular shape, and the width of one end of the close heat-conducting layer 300 of described comb 330 is more than one end away from heat-conducting layer 300 of described comb 330.

Described first installation portion 110 is provided with auxiliary heat-insulation layer, described auxiliary heat-insulation layer includes the first auxiliary heat-insulation layer 510 and the second auxiliary heat-insulation layer 520, described first auxiliary heat-insulation layer 510 and the second auxiliary heat-insulation layer 520 are by the closed at both ends of described cylinder, thus reducing the thermal loss of described graphene layer 200 further.

Referring to Fig. 6, Fig. 6 is the structural representation of marcel waver in sixth embodiment of the invention. The structure of marcel waver described in the present embodiment (sixth embodiment) is essentially identical with the structure of the marcel waver in first embodiment, it is different in that: marcel waver described in the present embodiment includes the train wheel bridge 1 arranged and lower plate 2 relatively, one end of described train wheel bridge 1 and one end of lower plate 2 are connected by connecting portion 3, and train wheel bridge 1 and lower plate 2 can be rotated by described connecting portion 3 and close to each other; First installation portion of described marcel waver includes the first sub-installation portion 1101 and the second sub-installation portion 1102, described first sub-installation portion 1101 is positioned at one end away from connecting portion 3 of described train wheel bridge 1, second sub-installation portion 1102 is positioned at described lower plate 2 one end away from connecting portion 3, when train wheel bridge 1 and lower plate 2 rotate by described connecting portion 3 and be close to each other, the first sub-installation portion 1101 and the second sub-installation portion 1102 are facing each other; Described graphene layer 200 includes the first graphene layer 210 and the second graphene layer 220, described heat-conducting layer 300 includes the first heat-conducting layer 310 and the second heat-conducting layer 320, described heat-insulation layer 500 includes the first heat-insulation layer 530 and the second heat-insulation layer 540, and described first heat-insulation layer 530, described first graphene layer 210 and described first heat-conducting layer 310 are cascadingly set on described first sub-installation portion 1101; Described second heat-insulation layer 540, described second graphene layer 220 and described second heat-conducting layer 320 are cascadingly set on described second sub-installation portion 1102; When train wheel bridge 1 and lower plate 2 rotate by described connecting portion 3 and be close to each other, the first heat-conducting layer 310 on described first sub-installation portion 1101 and the second heat-conducting layer 320 on described second sub-installation portion 1102 are facing each other and can close to each other or mutually fit tightly. In hair caring process, hair is placed between described first heat-conducting layer 310 and described second heat-conducting layer 320, again that the outside of described first sub-installation portion 1101 and the second sub-installation portion 110 is afterburning, the first heat-conducting layer 310 and the second heat-conducting layer 320 is made mutually to fit tightly, make hair from traverse between the first heat-conducting layer 310 and the second heat-conducting layer 320, so that hair is straightened simultaneously.

Dotted line in Fig. 6 represents the first installation portion and the demarcation line of the second installation portion, in the present embodiment, described second installation portion includes the first sub-portion 1201 and the second sub-portion 1202, first sub-portion 1201 is positioned at one end of the close connecting portion 3 of train wheel bridge 1, and the second sub-portion 1202 is positioned at one end of the close connecting portion 3 of lower plate 2. Described first sub-portion 1201 and the second sub-portion 1202 are respectively provided with an inner chamber, and power interface 700 is arranged at the end in the first sub-portion 1201, and electrical storage device 400 is arranged at the inner chamber in described first sub-portion 1201. Control circuit 900 is arranged at the inner chamber in the second sub-portion 1202, and control panel 800 is arranged at the outer surface in the second sub-portion 1202.

In the present embodiment, described marcel waver is included train wheel bridge 1 and lower plate 2, one end of described train wheel bridge 1 and one end of lower plate 2 and is connected by connecting portion 3, and train wheel bridge 1 and lower plate 2 can be rotated by described connecting portion 3 and close to each other; First installation portion 110 includes the first sub-installation portion 1101 and the second sub-installation portion 1102, described graphene layer 200 includes the first graphene layer 210 and the second graphene layer 220, described heat-conducting layer 300 includes the first heat-conducting layer 310 and the second heat-conducting layer 320, and described heat-insulation layer 500 includes the first heat-insulation layer 530 and the second heat-insulation layer 540; When train wheel bridge 1 and lower plate 2 rotate by described connecting portion 3 and are close to each other, the first heat-conducting layer 310 on described first sub-installation portion 1101 and the second heat-conducting layer 320 on described second sub-installation portion 1102 can be close to each other or bonded to each other, the chucking power of the hair being positioned between the first heat-conducting layer 310 and the second heat-conducting layer 320 is bigger, so that the better effects if that hair is straightened.

In the present embodiment, preferably, lower plate 2 can save the second graphene layer 220 etc. in second sub-installation portion 1102, train wheel bridge 1 has the function of heat temperature raising, and lower plate 2 does not have heat temperature raising function, in use, by hair clamping being stretched, there is same hair-straightening effect.

Referring to Fig. 7, Fig. 7 is the structural representation of marcel waver in seventh embodiment of the invention. the structure of marcel waver described in the present embodiment (the 7th embodiment) is essentially identical with the structure of marcel waver described in the 3rd embodiment and Fig. 3, it is different in that: in the present embodiment, first installation portion 110 of support 100 has the first surface 1103 arranged and second surface 1104 relatively, described graphene layer includes the first graphene layer 200 and the second graphene layer 200 ', described heat-conducting layer includes the first heat-conducting layer 300 and the second heat-conducting layer 300 ', described heat-insulation layer includes the first heat-insulation layer 500 and the second heat-insulation layer 500 ', be cascading on described first surface 1103 described first heat-insulation layer 500, described first graphene layer 200 and described first heat-conducting layer 300, be cascading on described second surface 1104 described second heat-insulation layer 500 ', described second graphene layer 200 ' and described second heat-conducting layer 300 '. described first installation portion 110 can be cylindrically, oval column, rectangular-shaped etc. in the present embodiment, described first heat-conducting layer 300 of described marcel waver is also provided with the first comb 330, described second heat-conducting layer 300 ' is provided with the second comb 330 ', it is also possible on described first comb 330 and described second comb 330 ', be respectively provided with the first tooth set 331 and the second tooth set 331 '.

In the process of hair caring, described hair is placed between warmed-up first comb 330 and/or the second comb 330 ' on described first surface 1103 or described second surface 1104, in the process of mobile described marcel waver, hair slips between described first comb 330 and/or between the second comb 330 ', heating and the effect of clamping is played between adjacent two described first comb 330 or between the second comb 330 ' to the hair slipped over, so that hair is straightened, now, described marcel waver is heater of hair straightener.

In hair caring process, hair is wound in the form looped on the described first surface 1103 of described first installation portion 110 or the first comb 330 of described second surface 1104 and/or the second comb 330 ', described first graphene layer 200 and the second graphene layer 200 ' transfer heat to described first heat-conducting layer 300 and described second heat-conducting layer 300 ' respectively, hair is heated by the first heat-conducting layer 300, described second heat-conducting layer 300 ' first comb 330 and/or the second comb 330 ', so that curly headed, now, described marcel waver is curler.

In the description of this specification, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means in conjunction with this embodiment or example describe are contained at least one embodiment or the example of the present invention. In this manual, the schematic representation of above-mentioned term is not necessarily referring to identical embodiment or example. And, the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiments or example.

Embodiments described above, is not intended that the restriction to this technical scheme protection domain. The amendment made within any spirit at above-mentioned embodiment and principle, equivalent replacement and improvement etc., should be included within the protection domain of this technical scheme.

Claims (17)

1. a marcel waver, it is characterized in that, including support, graphene layer, heat-conducting layer and electrical storage device, described support includes the first installation portion and the second installation portion, described graphene layer and described heat-conducting layer are arranged at described first installation portion, described heat-conducting layer covers described graphene layer, and described electrical storage device is arranged at described second installation portion, and described graphene layer is electrically connected with described electrical storage device.

2. marcel waver as claimed in claim 1, it is characterised in that described marcel waver also includes heat-insulation layer, and described heat-insulation layer is arranged at described first installation portion, and is positioned at the surface away from described heat-conducting layer of described graphene layer.

3. marcel waver as claimed in claim 2, it is characterised in that described marcel waver also includes temperature sensor, and described temperature sensor is arranged between described graphene layer and described heat-conducting layer.

4. marcel waver as claimed in claim 3, it is characterized in that, described marcel waver also includes power interface, described electrical storage device includes electric power management circuit and accumulator, described power interface receives from outside alternating current or unidirectional current, and flowing to described electric power management circuit, described alternating current or unidirectional current are processed and after voltage stabilizing by described electric power management circuit, charge for described accumulator.

5. marcel waver as claimed in claim 4, it is characterized in that, described marcel waver also includes control panel and control circuit, described second installation portion is in the shell structure with cavity, described control circuit is arranged in the cavity of described second installation portion, and be connected with described electrical storage device, described control panel is embedded in the outer surface of described second installation portion, and described control panel is connected with described control circuit.

6. marcel waver as claimed in claim 5, it is characterised in that the inputting interface of described control panel is for touching display screen in conjunction with physical button, or physical button is in conjunction with LCD or LED.

7. marcel waver as claimed in claim 5, it is characterized in that, described control circuit includes CPU and heat driven circuit, described CPU receives the call for heat of described control panel, read the current temperature value of described temperature sensor, and current temperature value and target temperature value are compared, if current temperature value is lower than target temperature value, described CPU opens described heat driven circuit, so that described accumulator provides electric energy to be heated for described graphene layer; If current temperature value equals to or higher than target temperature value, described CPU then closes described heat driven circuit.

8. the marcel waver as described in any one of claim 1 to 7, it is characterised in that be provided with multiple comb on described heat-conducting layer, the material of described comb is Heat Conduction Material.

9. marcel waver as claimed in claim 8, it is characterised in that described comb and described heat-conducting layer are non-removable integral structure.

10. marcel waver as claimed in claim 8, it is characterised in that one end away from described heat-conducting layer of described comb is in sphere.

11. marcel waver as claimed in claim 8, it is characterized in that, being provided with a tooth set on each described comb, described tooth set is placed on one end away from described heat-conducting layer of described comb, and the shape of described tooth set is consistent with the shape away from one end of described heat-conducting layer of described comb.

12. marcel waver as claimed in claim 8, it is characterized in that, described marcel waver also includes tooth set, described tooth set includes tooth set main body and multiple shape sub-set consistent with the shape of described comb, the corresponding comb of each described sub-set, each described sub-set is fixed in described tooth set main body, and described sub-set is placed on described comb, and described tooth set main body covers described heat-conducting layer IQ.

13. marcel waver as claimed in claim 12, it is characterised in that described sub-set is overlapped main body with described tooth and become non-removable integral structure.

14. the marcel waver as described in claim 2 to 7,9 to 13 any one, it is characterized in that, described first installation portion is in the shell structure with cavity, described heat-insulation layer is sheathed on the outer surface of described first installation portion, described graphene layer is sheathed on the outer surface of described heat-insulation layer, and described heat-conducting layer is sheathed on the outer surface of described graphene layer.

15. marcel waver as claimed in claim 14, it is characterised in that the two ends of described first installation portion are respectively arranged with auxiliary heat-insulation layer, and described auxiliary heat-insulation layer is by the closed at both ends of described first installation portion.

16. the marcel waver as described in claim 2 to 7,9 to 13 any one, it is characterized in that, described marcel waver includes the train wheel bridge arranged and lower plate relatively, one end of described train wheel bridge and one end of described lower plate are connected by a junction, and described train wheel bridge and described lower plate can be rotated by described connecting portion and close to each other, first installation portion of described marcel waver includes the first sub-installation portion and the second sub-installation portion, and described first sub-installation position is in one end away from described connecting portion of described train wheel bridge, and the second sub-installation position is in one end away from connecting portion of described lower plate, described graphene layer includes the first graphene layer and the second graphene layer, described heat-conducting layer includes the first heat-conducting layer and the second heat-conducting layer, described heat-insulation layer includes the first heat-insulation layer and the second heat-insulation layer, described first heat-insulation layer, described first graphene layer and described first heat-conducting layer are cascadingly set on described first sub-installation portion, described second heat-insulation layer, described second graphene layer and described second heat-conducting layer are cascadingly set on described second sub-installation portion, when described train wheel bridge and described lower plate rotate and close to each other time, make described first heat-conducting layer and described second heat-conducting layer laminating.

17. such as claim 2 to 7, marcel waver described in 9 to 13 any one, it is characterized in that, described first installation portion of described support has relative first surface and second surface, described graphene layer includes the first graphene layer and the second graphene layer, described heat-conducting layer includes the first heat-conducting layer and the second heat-conducting layer, described heat-insulation layer includes the first heat-insulation layer and the second heat-insulation layer, be cascading on described first surface described first heat-insulation layer, described first graphene layer and described first heat-conducting layer, be cascading on described second surface described second heat-insulation layer, described second graphene layer and described second heat-conducting layer.