CN203502942U - Touch type remote controller - Google Patents

Abstract

The utility model relates to a touch type remote controller, which comprises a shell, a circuit board, a power supply and a signal transmission source, and the circuit board, the power supply and the signal transmission source are arranged in the shell. The touch type remote controller is characterized in that the touch type remote controller further comprises a capacitive touch screen which is integrated on the shell; the capacitive touch screen is of a curved surface structure and comprises a curved surface-shaped cover board, a carbon nano tube film and a plurality of touch control-sensing electrodes, wherein the carbon nano tube film is arranged on the surface, which is located in the shell, of the cover board, the touch-sensing electrodes are electrically connected with the carbon nano tube film, and the carbon nano tube film is composed of a plurality of carbon nano tubes which extend along the same direction and connected with one another through Van der Waals' force. The touch type remote controller disclosed by the utility model is simpler in structure.

Description

Touch-type remote-controller

Technical field

The utility model relates to a kind of touch-type remote-controller, relates in particular to a kind of multifunctional touch-controlled telepilot.

Background technology

Along with the development of electronics, information, the technology of semiconductor chips, televisor is connected with top box of digital machine in recent years, and top box of digital machine couples together with diverse network again, and televisor is made and become a kind of digitized intelligent terminal and become a kind of development trend.

By top box of digital machine, network and televisor are coupled together, thoroughly break conventional television and can only carry out simple broadcasting and the general layout of zapping, make people can pass through the magnanimity resource in televisor internet login and then shared network, can also do shopping by televisor, browse news etc. simultaneously.For this reason, various multi-functional control device are also developed by corresponding.For example, prior art provides a kind of control device with mouse and keyboard operation function to control this intelligent terminal.

Yet this control device is realized mouse function by one contact panel being set on traditional remote controller surface.Therefore, this control device volume and weight is larger, and complex structure is used inconvenient.

Utility model content

In view of this, necessaryly provide a kind of volume and weight less, simple in structure, multifunctional touch-controlled telepilot easy to use.

A kind of touch-type remote-controller, comprise: housing and the circuit board, power supply and the signal emitting-source that are arranged on enclosure interior, it is characterized in that, further comprising that a capacitive touch screen is integrated is arranged on described housing, described capacitive touch screen is a curve and surface structure, comprise that a curve and surface type cover plate, a carbon nano-tube film are arranged at surface and a plurality of touch-control sensing electrodes that described cover plate is positioned at housing and are electrically connected to described carbon nano-tube film, described carbon nano-tube film is comprised of a plurality of extensions in the same direction and the carbon nano-tube that connect by Van der Waals force each other.

A kind of touch-type remote-controller, it comprises the sensor of a sensing touch signal, described sensor comprises a dielectric base and the carbon nano-tube film that is arranged at dielectric base surface, described carbon nano-tube film comprises a plurality of carbon nano-tube of extending in the same direction, described dielectric base has a curve and surface, and described carbon nano-tube film is attached at described curve and surface surface.

Compared with prior art, the touch-type remote-controller that the utility model provides has the sensor of carbon nano-tube film, simple in structure, lightweight, and can realize the function of mouse and keyboard simultaneously, has wide application space.

Accompanying drawing explanation

The stereographic map of the touch-type remote-controller that Fig. 1 provides for the utility model embodiment.

Fig. 2 is the exploded view of the touch-type remote-controller of Fig. 1.

Fig. 3 is the vertical view of the touch-type remote-controller of Fig. 1.

Fig. 4 is the sectional drawing of the touch-type remote-controller IV-IV along the line of Fig. 3.

Fig. 5 is the structural representation of sensor of the touch-type remote-controller of Fig. 1.

Fig. 6 is the structural representation of sensor of the touch-type remote-controller of another embodiment of the utility model.

A kind of process chart of preparing sensor that Fig. 7 provides for the utility model embodiment.

The connection diagram of each functional module group of touch-type remote-controller that Fig. 8 provides for the utility model.

Fig. 9 is that the utility model adopts this touch-type remote-controller to control the schematic diagram of intelligent television.

Main element symbol description

Touch-type remote-controller	10
		Housing	100
Pedestal	102
		Opening	103
Lid	104
		Crack	105
Power switch key	106
		USB interface	108
Sensor	110
		Dielectric base	112
External circuit	113
		Carbon nano-tube film	114
The first electrode	116
		The first conducting wire	117
The second electrode	118
		The second conducting wire	119
Circuit board	120
		Signal emitting-source	130
Infrared wavelength light emitting diode	132
		One bluetooth module	134
Power supply	140
		Cover plate	150
Pilot lamp	160
		Composite structure of carbon nano tube	170
Intelligent television	20

Following embodiment further illustrates the utility model in connection with above-mentioned accompanying drawing.

Embodiment

Below in conjunction with the accompanying drawings and the specific embodiments, touch-type remote-controller the utility model being provided is described in further detail.

Refer to Fig. 1 to Fig. 4, the utility model the first embodiment provides a kind of touch-type remote-controller 10, and this touch-type remote-controller 10 comprises a housing 100, a sensor 110, a circuit board 120, a signal emitting-source 130, a power supply 140 and a cover plate 150.

Described housing 100 is for accommodating this circuit board 120, signal emitting-source 130 and power supply 140.Described housing 100 comprises a pedestal 102 and one and the lid 104 that matches of this pedestal 102.The shape and size of described pedestal 102 and lid 104 can design as required, but will guarantee that this lid 104 has a curved face type surface.Described pedestal 102 and lid 104 should have certain hardness.The material of described pedestal 102 and lid 104 can be the insulating material such as glass, pottery or plastics.Described pedestal 102 and lid 104 can be for transparent or opaque.In the present embodiment, described pedestal 102 is an open-type structure, and has a plane bottom surface.Described lid 104 is a curve and surface type lid, these lid 104 even thickness, and its inside surface and outside surface be curve and surface, as quafric curve curved surface or free form surface.That is, this lid 104 is curved surface at length direction and Width.Described curve and surface is a curve along the formation of moving of any curvilinear path, or described curve rotates to form along self axis of symmetry, and described curve is the bus of described curve and surface.The material of described pedestal 102 and lid 104 is Polyvinylchloride (PVC).Further, the side of described pedestal 102 has a power switch key 106 and an internal USB interface 108.

As shown in Figure 2, in the present embodiment, the outside surface of described lid 104 has an opening 103, for described sensor 110 is set.The shape and size of the shape and size of this opening 103 and described sensor 110 and cover plate 150 are suitable, make this sensor 110 and cover plate 150 can embed and fix in this opening 103, and adopt this cover plate 150 that sensor 110 is covered, form a detachable capacitive touch screen.The degree of depth of described opening 103 approximates greatly the thickness summation of this cover plate 150 and sensor 110.Described opening 103 bottoms have one and crack 105, for connecting this sensor 110 and circuit board 120.Be appreciated that described opening 103 also can be formed at the inside surface of this lid 104.Be appreciated that described lid 104 can not have opening yet, or described lid 104 can form integrative-structures with described cover plate 150, described sensor 110 directly laminating is fixed on the inside surface of this lid 104.In the present embodiment, the similar rectangle of shape of described opening 103 and cover plate 150, but its four edges and four angles are the arc of evagination.

Described cover plate 150 is also the curve and surface type lid of an even thickness, and its inside surface and outside surface be curve and surface, forms a curved face type structure.Described outside surface is the curve and surface of an evagination.The shape and size of the shape and size of described cover plate 150 and described opening 103 are suitable, and after making in this cover plate 150 and this opening 103 of sensor 110 embeddings, this cover plate 150 can form a complete curve and surface with lid 104.The material of the material of described cover plate 150 and lid 104 can be identical or different.In the present embodiment, the material of this cover plate 150 is Polyvinylchloride.

Further consult Fig. 5, described sensor 110 comprises a dielectric base 112, a carbon nano-tube film 114, a plurality of the first electrode 116, one first conducting wire 117, a plurality of the second electrode 118 and one second conducting wire 119.Described sensor 110 forms a capacitive touch screen with the cover plate 150 that is arranged at described sensor 110 surfaces.Described sensor 110 is a curved face type structure.Described carbon nano-tube film 114 is arranged at the surface of this dielectric base 112.The undersized of described carbon nano-tube film 114 is in the size of this dielectric base 112, thus the cabling region not covered by carbon nano-tube film 114 in definition one touch area being covered by carbon nano-tube film 114 and, the surface of this dielectric base 112.Described the first electrode 116, the first conducting wire 117, the second electrode 118 and one second conducting wire 119 are all arranged at this cabling region.

Described dielectric base 112 is for supporting and protect this carbon nano-tube film 114, the first electrode 116, the second electrode 118, the first conducting wire 117 and the second conducting wire 119.Described dielectric base 112 is the structure of a curved face type, and the shape and size of its shape and size and described cover plate 150 are suitable.The curvature of described dielectric base 112 outside surfaces is identical with the curvature of described cover plate 150 inside surfaces, thereby this sensor 110 is easily fitted with cover plate 150.The thickness of described dielectric base 112 is 100 microns ~ 500 microns.This dielectric base 112 can be formed by the hard materials such as plastics or flexible material.Particularly, described flexible material may be selected to be the polyester materials such as polycarbonate (PC), polymethylmethacrylate (PMMA), tygon (PE), polyimide (PI) or polyethylene terephthalate (PET), or the material such as polyethersulfone (PES), cellulose esters, Polyvinylchloride (PVC), benzocyclobutene (BCB) or acryl resin.Be appreciated that the material that forms described dielectric base 112 is not limited to the above-mentioned material of enumerating.In the present embodiment, the plane PET film that described dielectric base 112 is 150 microns of thickness.

Described carbon nano-tube film 114 is arranged at the outside surface of this dielectric base 112, and is held between described dielectric base 112 and described cover plate 150.Described carbon nano-tube film 114 is one to have the carbon nano-tube film 114 of electrical impedance anisotropy.Described carbon nano-tube film 114 is the self supporting structures that are comprised of some carbon nano-tube (Carbon Nano Tube, CNT).Described some carbon nano-tube are extended along a fixed-direction preferred orientation.In this carbon nano-tube film 114, the whole bearing of trend of most of carbon nano-tube substantially in the same direction.And the whole bearing of trend of described most of carbon nano-tube is basically parallel to the surface of carbon nano-tube film 114.Further, in described carbon nano-tube film 114, most carbon nano-tube are to join end to end by Van der Waals (Van Der Waals) power.In most of carbon nano-tube of extending substantially in the same direction in described carbon nano-tube film 114 particularly,, each carbon nano-tube joins end to end by Van der Waals force with carbon nano-tube adjacent on bearing of trend.Certainly, have the carbon nano-tube of minority random alignment in described carbon nano-tube film 114, these carbon nano-tube can not arranged and form obviously impact the overall orientation of most of carbon nano-tube in carbon nano-tube film 114.Described carbon nano-tube film 114 does not need large-area carrier supported, and it is can be on the whole unsettled and keep self membranaceous state as long as relative both sides provide support power, when soon this carbon nano-tube film 114 is placed on spaced two supporters, the carbon nano-tube film 114 between two supporters can the membranaceous state of unsettled maintenance self.

Particularly, most carbon nano-tube of extending substantially in the same direction in described carbon nano-tube film 114, and nisi linearity, bending that can be suitable; Or not completely according to arranging on bearing of trend, can be suitable depart from bearing of trend.Therefore, can not get rid of between carbon nano-tube arranged side by side in most carbon nano-tube of extending substantially in the same direction of carbon nano-tube film 114 and may have part contact.

Particularly, described carbon nano-tube film 114 comprise a plurality of continuously and the carbon nano-tube fragment aligning.The plurality of carbon nano-tube fragment joins end to end by Van der Waals force.Each carbon nano-tube fragment comprises a plurality of carbon nano-tube that are parallel to each other, and the plurality of carbon nano-tube being parallel to each other is combined closely by Van der Waals force.This carbon nano-tube fragment has length, thickness, homogeneity and shape arbitrarily.Carbon nano-tube in this carbon nano-tube film 114 is arranged of preferred orient in the same direction.

Described carbon nano-tube film 114 can be by directly pulling acquisition from carbon nano pipe array.Particularly, first on the substrate of quartz or wafer or other material, grow carbon nano pipe array, for example, use chemical gaseous phase Shen to amass (Chemical Vapor Deposition, CVD) method; Then, with stretching technique, carbon nano-tube is pulled out from carbon nano pipe array and form.These carbon nano-tube are joined end to end by Fan get Wa Li, form the conductive elongate structure that tool certain orientation and almost parallel are arranged.The electrical impedance that formed carbon nano-tube film 114 is understood in the direction tool minimum stretching, and in the electrical impedance perpendicular to draw direction tool maximum, thereby possess electrical impedance anisotropy.Further, can also adopt this carbon nano-tube film 114 of lasser cutting.The in the situation that of carbon nano-tube film 114 process lasser cutting, on carbon nano-tube film 114, will there be a plurality of laser cut line, such processing not only can not affect the electrical impedance anisotropy that carbon nano-tube film 114 originally just had, and can also increase the light transmission of this carbon nano-tube film 114.

In the present embodiment, the similar rectangle of the shape of described carbon nano-tube film 114, it has the relative first long limit and the second long limit, and its first long limit and the second long limit are to away from the cambered outwards arc in carbon nano-tube film side.The length direction of described carbon nano-tube film 114 is defined as Y-direction, and its Width is defined as directions X.Described directions X is perpendicular to described Y-direction.Carbon nano-tube in described carbon nano-tube film 114 is extended along directions X substantially, and the bearing of trend of described carbon nano-tube is parallel to the bending direction of curve in described curve and surface.

Further, between described carbon nano-tube film 114 and dielectric base 112, an adhesive-layer (not shown) can be set, described carbon nano-tube film 114 is adhered to better to the surface of described dielectric base 112.The thickness of described adhesive-layer is 10 nanometer ~ 50 micron; Preferably, the thickness of described adhesive-layer is 1 micron ~ 2 microns.Described adhesive-layer can be transparent or opaque.The material of this adhesive-layer can be for having thermoplastic or the UV(Ultraviolet Rays of low melting point) glue, as Polyvinylchloride (PVC) or PMMA etc.In the present embodiment, described adhesive-layer is UV glue, and its thickness is about 1.5 microns.

Described a plurality of the first electrode 116 is arranged at intervals at the same long limit of described carbon nano-tube film 114 one side, is arranged in arc, and is electrically connected to this carbon nano-tube film 114 along the long limit of carbon nano-tube film 114; Described a plurality of the second electrode 118 is arranged at intervals at other long limit one side of described carbon nano-tube film 114, is arranged in arc, and is electrically connected to this carbon nano-tube film 114 along the long limit of carbon nano-tube film 114.Described the first conducting wire 117 is electrically connected to the plurality of the first electrode 116, and this sensor 110 is electrically connected to an external circuit 113; Described the second conducting wire 119 is electrically connected to a plurality of the second electrodes 118, and this sensor 110 is electrically connected to an external circuit 113.In the present embodiment, described external circuit 113 is a flexible PCB (FPC), and it 105 is electrically connected to circuit board 120 by cracking.

Described a plurality of the first electrode 116, the material of a plurality of the second electrodes 118 and the first conducting wire 117 and the second conducting wire 119 can be other conductive materials such as metal, carbon nano-tube, tin indium oxide or electrocondution slurry.Described a plurality of the first electrode 116, etching conductive film can be passed through in a plurality of the second electrodes 118 and the first conducting wire 117 and the second conducting wire 119, as metallic film or indium tin oxide films preparation, also can prepare by silk screen print method.In the present embodiment, described a plurality of the first electrodes 116, a plurality of the second electrodes 118 and the first conducting wire 117 and the second conducting wire 119 are conductive silver slurry, and form by silk screen print method simultaneously.Described the first electrode 116 and the second electrode 118 are the conductive silver slurry layer of bar shaped.The composition of this electrocondution slurry comprises metal powder, glass powder with low melting point and cementing agent.Wherein, this metal powder is preferably silver powder, and this cementing agent is preferably terpinol or ethyl cellulose.In this electrocondution slurry, the weight ratio of metal powder is 50% ~ 90%, and the weight ratio of glass powder with low melting point is 2% ~ 10%, and the weight ratio of cementing agent is 8% ~ 40%.

Be appreciated that, in another embodiment, described sensor 110 also can save this dielectric base 112,, this carbon nano-tube film 114, the first electrode 116, the second electrode 118, the first conducting wire 117 and the second conducting wire 119 are directly arranged to the inside surface of this cover plate 150, form a capacitive touch screen.So, can save material and simplify preparation technology, thereby reduce touch-type remote-controller 10 costs.

Consult Fig. 6, in another embodiment, described touch-type remote-controller 10 can also further save cover plate 150, or described cover plate 150 is an integrative-structure with described lid 104, and described lid 104 does not have opening 103.Described sensor 110 is directly arranged at the inside surface of this lid 104, forms a capacitive touch screen.Carbon nano-tube film 114, the first electrode 116, the first conducting wire 117, the second electrode 118 and second conducting wire 119 of described sensor 110 are arranged between this lid 104 and dielectric base 112.These dielectric base 112 these sensors 110 of protection.

Further, described touch-type remote-controller also can comprise that a curve and surface type shows module (not shown) and described attaching capacitive touch screens, described demonstration module can be a film transistor type or Organic Light Emitting Diode (OLED) shows module, in order to real-time demonstration touch information.Described demonstration module can be fitted away from the surface of carbon nano-tube film 114 with described dielectric base 112.

By take the sensor 110 shown in Fig. 5, introduce the preparation method of the sensor 110 of the utility model embodiment as example below.

Refer to Fig. 7, the preparation method of described sensor 110 mainly comprises the following steps:

Step S10, provides a dielectric base 112;

Step S11, arranges a carbon nano-tube film 114 on the surface of described dielectric base 112, form a composite structure of carbon nano tube 170;

Step S12, arranges a plurality of the first electrodes 116 at the spaced surface of described dielectric base 112 and is electrically connected to described carbon nano-tube film 114 with a plurality of the second electrodes 118;

Step S13, arranges one first conducting wire 117 and is electrically connected to described a plurality of the first electrodes 116, one second conducting wire 119 is set and is electrically connected to described a plurality of the second electrodes 118;

Step S14, crooked described composite structure of carbon nano tube 170, forms described sensor 10.

In step S11, described carbon nano-tube film 114 can be attached at by tack coat (not shown) the surface of described dielectric base 112, thereby described carbon nano-tube film 114 is firmly combined with described dielectric base 112.

In step S12 and S13, described a plurality of the first electrodes 116, a plurality of the second electrode 118, the first conducting wire 117 and the second conducting wire 119 can be prepared by the mode of serigraphy.

In step S14, described composite structure of carbon nano tube 170 can carry out bending in the following manner:

Step S141, provides a mould, and described mould has a male model and a master mold, and the surface that described male model and master mold are relative is a curved surface;

Step S142, heats described male model and master mold to predetermined temperature;

Step S143, is arranged at described composite structure of carbon nano tube 170 between described male model and master mold;

Step S144, promotes described male model and master mold and makes its matched moulds schedule time; And

Step S145, by described mould die sinking, forms described sensor 110.

In step S142, the size of described predetermined temperature is selected according to the material of described dielectric base 112, under the effect of this predetermined temperature, described dielectric base 112 is further softened, but can not destroy its global shape, and substantially can not destroy the integrality of described carbon nano-tube film 114 yet.In the present embodiment, described predetermined temperature is 80 degrees Celsius to 120 degrees Celsius.

In step S144, the schedule time of described matched moulds can be selected according to actual needs, so that described composite structure of carbon nano tube 170 is can be fully crooked, and makes its crooked shape identical with curved surface described in described male model, master mold.In crooked process, described carbon nano-tube film 114 carries out bending with described dielectric base 112 simultaneously.Further, bending all can be carried out in described a plurality of the first electrodes 116, a plurality of the second electrode 118, the first conducting wire 117 and described the second conducting wire 119 simultaneously, to guarantee still to keep good electrical connection between each element.The described matched moulds schedule time can be 20 seconds to 180 seconds.

Described circuit board 120 is a printed-wiring board (PWB) (PCB), and integrated various chips and circuit on this printed-wiring board (PWB).Described circuit board 120 is electrically connected to described sensor 110 respectively and signal emitting-source 130 is electrically connected to.The touch signal that this sensor 110 senses can be accepted and analyze to described circuit board 120, and control described signal emitting-source 130 work according to analysis result.Further, described circuit board 120 is also integrated with gyroscope function, thereby makes this touch-type remote-controller 10 have aerial positioning function.

Described signal emitting-source 130 can be one or more in infrared transmitter, bluetooth transmitters, Wifi transmitter or 2.4G transmitter.The wireless signal that described signal emitting-source 130 is exported for radiating circuit plate 120 is to intelligent terminals such as TVs, to control this intelligent terminal work.In the present embodiment, described signal emitting-source 130 comprises an infrared wavelength light emitting diode (LED) 132 and a bluetooth module 134.By infrared transmission and the parallel telecontrol engineering of bluetooth wireless transmission, can guarantee the correctness of remote control.

Described power supply 140 is electrically connected to provide the energy with described sensor 110 and described signal emitting-source 130 respectively by described circuit board 120.Described power supply 140 can be the secondary cells such as the one-shot batteries such as dry cell or lithium battery.In the present embodiment, described power supply 140 is a chargeable lithium cell, thereby makes the compact in size of this touch-type remote-controller 10.

Further, described touch-type remote-controller 10 also comprises at least one pilot lamp 160.This pilot lamp 160 is arranged on described lid 104 and with circuit board 120 and is electrically connected to.This pilot lamp 160 is for showing the mode of operation of this touch-type remote-controller 10, as TV telepilot, common mouse or air mouse (Air Mouse).In the present embodiment, described pilot lamp 160 comprises a red-light LED and a green light LED.

According to the mode shown in Fig. 2 from bottom to top, stacking assembling, is installed to different parts on the pedestal 102 of housing 100 above-mentioned each assembly of described touch-type remote-controller 10 one by one, then that this lid 104 and pedestal 102 is closed fixing.The fixing mode of described lid 104 and pedestal 102 can be glue, ultrasonic fusing, or other method.Preferably, described fixing mode is not used screw fastener.In this manual, " on " D score only refers to relative orientation.In the present embodiment, " on " referring to that touch-type remote-controller 10 is near the surperficial direction of touching, D score refers to that touch-type remote-controller 10 is away from the surperficial direction of touching.

See also Fig. 8, described touch-type remote-controller 10 comprises a plurality of modules, as touch-screen, touch signal processing module, bluetooth module, infrared module, power supply, microphone, gyroscope etc.The touch signal of described touch screen induction outside, and inputted touch signal processing module, described touch signal processing module is according to different touch signals, to other modules, transmit control signal, as to as described in bluetooth module output order, to realize the instruction interaction of touch-type remote-controller 10 and other electrical equipment; To described microphone output control signal, to receive the sound of microphone registers external environment condition; To described gyroscope output control signal, and the signal of gyroscope feedback is processed and is converted to work order, and export to electrical equipment to be controlled by bluetooth module or infrared module.

To introduce the principle of work of this touch-type remote-controller 10 and adopt this touch-type remote-controller 10 to control the method for intelligent terminal below.

Refer to Fig. 9, the present embodiment be take and adopted this touch-type remote-controller 10 to control intelligent televisions 20 to describe as example.The touch-type remote-controller 10 of the present embodiment comprises TV telepilot, common mouse and three kinds of mode of operations of air mouse.Be appreciated that because this sensor 110 is a multipoint mode touch pad, therefore it can identify the multiple touch gestures defining in advance.

10 pairs of touch gestures of touch-type remote-controller of the present embodiment are defined as: finger is drawn ditch and opened intelligent television 20 in touch area; Finger continues to press sensor 110 top, touch area 5 seconds, the conversion that circulates between three kinds of mode of operations of this touch-type remote-controller 10; When this touch-type remote-controller 10 is TV telepilot pattern, finger slides left in touch area and reduces for volume, finger slides to the right in touch area as volume increase, finger is that channel increases at touch area upward sliding, finger is that channel reduces at touch area down sliding, finger slides and returns to homepage in touch area annular, and finger is drawn fork and closed intelligent television 20 in touch area; When this touch-type remote-controller 10 is common mouse pattern, finger continues within 10 seconds, to carry out Bluetooth pairing by sensor 110 bottoms, touch area, finger moves in touch area, cursor respective direction on display moves, finger is clicked in touch area as choosing, and finger is double-clicked in touch area as activating; When this touch-type remote-controller 10 is air mouse pattern, finger continues within 10 seconds, to carry out Bluetooth pairing by sensor 110 bottoms, touch area, touch-type remote-controller 10 aloft moves, cursor respective direction on display moves, finger is clicked in touch area as choosing, and finger is double-clicked in touch area as activating.The definition that is appreciated that 10 pairs of touch gestures of described touch-type remote-controller is not limited to aforesaid way, for example, when this touch-type remote-controller 10 is TV telepilot pattern, can in touch area, writes numeral by finger and control channel.

The step that the present embodiment adopts this touch-type remote-controller 10 to control intelligent television 20 is as follows.First, open touch-type remote-controller 10, and enter homepage by these touch-type remote-controller 10 unlatching intelligent televisions 20.This intelligent television 20 shows a plurality of choice menus.Select this touch-type remote-controller 10 to open as common mouse or air mouse pattern, and click menu and make intelligent television 20 enter respective interface.If intelligent television 20 is television interfaces, selects this touch-type remote-controller 10 to open as TV telepilot pattern, and carry out as required the selection control of volume and channel.If intelligent television 20 is web interface, selecting this touch-type remote-controller 10 is common mouse or air mouse pattern, and clicks as required control.

The touch-type remote-controller that the utility model provides, has following beneficial effect.First, by carbon nano-tube film being integrated in to a substrate surface, form touch-screen, structure, technique are simple, and can with existing telepilot housing process compatible; Secondly, because described carbon nano-tube has good flexibility, therefore the curved surface of described substrate can be a curve and surface, also can be free form surface, so the design of substrate is more flexible; Again, the bearing of trend by carbon nano-tube in carbon nano-tube film is parallel to curved direction and arranges, and can realize the bending that approaches 90 degree, and still keep good touch-control performance, has more wide application space.

In addition, those skilled in the art can also do other and change in the utility model spirit, and the variation that these are done according to the utility model spirit, all should be included in the utility model scope required for protection.

Claims (18)

1. a touch-type remote-controller, comprise: housing and the circuit board that is arranged on enclosure interior, power supply and signal emitting-source, it is characterized in that, further comprising that a capacitive touch screen is integrated is arranged on described housing, described capacitive touch screen is a curve and surface structure, comprise a curve and surface type cover plate, one carbon nano-tube film be arranged at described cover plate be positioned at housing surface and a plurality of touch-control sensing electrodes be electrically connected to described carbon nano-tube film, described carbon nano-tube film is comprised of a plurality of carbon nano-tube of extending in the same direction and connecting by Van der Waals force each other.

2. touch-type remote-controller as claimed in claim 1, is characterized in that, described curve and surface type cover plate and described housing are one-body molded.

3. touch-type remote-controller as claimed in claim 1, is characterized in that, described housing has an opening, the aperture position that is arranged on described housing that described capacitive touch screen is detachable.

4. touch-type remote-controller as claimed in claim 1, is characterized in that, carbon nano-tube film comprises that a plurality of carbon nano-tube extend along a direction preferred orientation, and in described curve and surface type capacitive touch screen, the bending direction of described curve is parallel with carbon nano-tube bearing of trend.

5. touch-type remote-controller as claimed in claim 4, is characterized in that, the bearing of trend of described carbon nano-tube is identical with the bus bearing of trend of curve and surface.

6. touch-type remote-controller as claimed in claim 1, is characterized in that, carbon nano-tube film is arranged on a dielectric base surface, and is fitted in by adhesive-layer the surface that cover plate is positioned at housing, and carbon nano-tube film is between dielectric base and cover plate.

7. touch-type remote-controller as claimed in claim 6, is characterized in that, further comprises that a curve and surface type shows module and the laminating of described touch-screen.

8. touch-type remote-controller as claimed in claim 7, is characterized in that, the setting of described demonstration module is attached at described dielectric base away from the surface of carbon nano-tube film.

9. touch-type remote-controller as claimed in claim 6, is characterized in that, inside surface and the outside surface of described cover plate are curve and surface, and the curvature of described dielectric base is identical with the curvature of described inside surface.

10. touch-type remote-controller as claimed in claim 1, is characterized in that, described carbon nano-tube film has electrical impedance anisotropy.

11. touch-type remote-controllers as claimed in claim 1, is characterized in that, described carbon nano-tube film is joined end to end and formed a self supporting structure by Van der Waals force.

12. touch-type remote-controllers as claimed in claim 1, is characterized in that, described carbon nano-tube film be shaped as rectangle, and its long limit arc that is evagination.

13. touch-type remote-controllers as claimed in claim 1, it is characterized in that, described housing comprises a pedestal and one and the lid that matches of described pedestal, and the outside surface of described lid has an opening, the aperture position that is arranged on described lid that described capacitive touch screen is detachable.

14. touch-type remote-controllers as claimed in claim 13, is characterized in that, described capacitive touch screen is identical with the shape and size of described opening.

15. touch-type remote-controllers as claimed in claim 13, is characterized in that, described capacitive touch screen embeds and is fixed in described opening.

16. touch-type remote-controllers as claimed in claim 1, it is characterized in that, described capacitive touch screen further comprises a dielectric base, and dielectric base is dielectric base prepared by flexible material, and described carbon nano-tube film is held between described dielectric base and described cover plate.

17. touch-type remote-controllers as claimed in claim 1, is characterized in that, described carbon nano-tube film is directly attached at the inside surface of described cover plate.

18. 1 kinds of touch-type remote-controllers, it comprises the sensor of a sensing touch signal, described sensor comprises a dielectric base and the carbon nano-tube film that is arranged at dielectric base surface, described carbon nano-tube film comprises a plurality of carbon nano-tube of extending in the same direction, described dielectric base has a curve and surface, and described carbon nano-tube film is attached at described curve and surface surface.

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