CN202455240U - Remote controller - Google Patents

Abstract

The utility model discloses a remote controller, which comprises a shell, a button arranged on the shell, a power supply arranged in the shell and a remote control circuit module arranged in the shell; the remote control circuit module comprises a circuit board; the power supply is a vibration power generation device manufactured by adopting an electromagnetic induction power generation principle, and the vibration power generation device is internally provided with a magnet assembly for providing a permanent magnetic field and an induction power generation assembly for cutting magnetic lines of force and generating induction current. The utility model discloses can turn into the electric current to the vibration that external force produced to need not to use traditional dry battery as the power, have better environmental protection effect and longer life.

Description

Remote controller

Technical Field

The invention belongs to the technical field of remote controller structure design, and particularly relates to a remote controller without a dry battery.

Background

Remote control refers to a remote control technology, and a device for remotely controlling a machine or an electric appliance is called a remote controller. Modern remote controllers are mainly composed of integrated circuit boards and buttons for generating different messages. Remote control technology has numerous applications in industrial production, military and scientific research.

The existing remote controller uses a direct current battery as a power supply, and particularly the usage amount of a dry battery is large. At present, dry batteries mainly comprise a large series of zinc-manganese and alkaline zinc-manganese 2, and also comprise a small amount of zinc-silver, lithium batteries and other varieties. The most heavily polluted mercury (HgO) cell has been forced to be eliminated in 1999 and thus replaced by a zinc-air cell; the zinc-manganese batteries, alkaline zinc-manganese batteries, zinc-silver batteries, zinc-air batteries and other batteries using zinc electrodes generally use mercury or mercury compounds as corrosion inhibitors, and the zinc-manganese batteries meet the requirement of low mercury content at present according to the regulation of the nine ministries on limiting the mercury content of battery products, but the alkaline zinc-manganese batteries produced by most manufacturers have larger distance between the mercury content and the requirement of low mercury content. Since mercury and its compounds are highly toxic substances, the pollution of the environment by the waste batteries has attracted general attention from the public, media and environmental regulatory authorities. Recently, domestic calls have been particularly strong and seem to be in conflict with the treatment of "white" pollution and automobile exhaust, etc. The zinc-manganese and alkaline zinc-manganese batteries are civil batteries with the largest use amount, and the waste batteries have the pollution of mercury and the pollution of other heavy metals such as zinc, manganese, copper and the like. Due to the dispersed use, the difficult management of recovery and the high regeneration cost of the waste batteries, the conventional scientific and economic treatment method is lacked, and the waste batteries are generally treated as household garbage. Because the treatment methods of the domestic garbage are different, the pollution modes are different. When the garbage is used for composting, the heavy metal content in the crop products used for composting is increased by the waste batteries. When the domestic garbage is buried, the soil near a water system and a landfill site is mainly polluted. When the domestic garbage is incinerated, part of mercury, cadmium, lead, zinc and other heavy metals in the waste batteries are discharged into the atmosphere at high temperature, and part of the heavy metals become ash, so that secondary pollution is generated.

In addition, in many cases, when the battery in the remote controller is exhausted, the battery cannot be found for use in time.

Patent document 200420114116.X discloses a vibration type power generation charger which generates power by generating induction by a permanent magnet vibrating by an external force and moving up and down in a coil. The vibration type charger mainly utilizes the energy of a vibration mechanism of a vehicle in the running process to generate electricity, the vibration type charger is generally large in size and cannot be built in a remote controller with a small size, and the permanent magnet in the vibration type charger is connected through the spring, so that the permanent magnet can move in a large amplitude when the external vibration is strong, and current is generated. In addition, the vibration charger generates power by using a single coil, and the power generation efficiency is low.

Disclosure of Invention

The present invention has an object to provide a remote controller capable of converting vibration generated by an external force into current, thereby eliminating the need to use a conventional dry battery as a power source.

The technical scheme for realizing the purpose of the invention is as follows: a remote controller comprises a shell, a button arranged on the shell, a power supply arranged in the shell and a remote control circuit module arranged in the shell; the remote control circuit module comprises a circuit board; the power supply is a vibration power generation device manufactured by adopting an electromagnetic induction power generation principle, and the vibration power generation device is internally provided with a magnet assembly for providing a permanent magnetic field and an induction power generation assembly for cutting magnetic lines of force and generating induction current.

In the above scheme, be equipped with the storage tank in the shell, vibration power generation facility joint is fixed or sticky the fixing in the storage tank.

In the above scheme, the vibration power generation device is fixed on the circuit board in an adhesive or welding manner.

In the scheme, the vibration power generation device is provided with a plurality of protruding pins, and the pins are welded and fixed on the circuit board; the housing is a sealed, waterproof housing.

In the above scheme, the vibration power generation device further comprises a housing; the magnet assembly is in a straight plate shape or an arc plate shape, the induction power generation assembly is arranged on one side or two sides of the magnet assembly, and the induction power generation assembly cuts magnetic lines of force under the action of external force and generates induction current; the induction power generation assembly comprises at least one coil or at least one bundled wire; when each induction power generation assembly comprises at least two coils or bundling wires, the coils or the bundling wires are connected in parallel or in series; the magnet assembly comprises at least one strip magnet; the magnet is in the direction that is on a parallel with the motion of response electricity generation subassembly, and one end is the S level, and the other end is the N utmost point, perhaps the magnet is in the direction of perpendicular to response electricity generation subassembly motion, and one end is the S level, and the other end is the N utmost point.

In the above scheme, each induction power generation assembly further comprises a counterweight member for fixedly connecting each coil or each bundled wire, the counterweight member is a plastic plate which is connected with each coil or each bundled wire into a whole in an injection molding mode or a non-magnetic conductive plate body provided with an accommodating cavity, and each coil or each bundled wire is fixed in a corresponding accommodating cavity; the shell is a magnetic conduction shell; each coil comprises two linear power generation parts and connecting parts which are positioned at two side ends of the power generation parts and are used for connecting the two linear power generation parts; when each induction power generation assembly comprises at least two coils, the power generation parts of the two adjacent coils are parallel to each other; the bundling wires are parallel to each other; when the magnet is S level along the direction of response electricity generation subassembly motion on one end, when the other end is the N utmost point, the magnet subassembly includes two at least strip magnetites, and two adjacent strip magnetites are arranged according to homopolar mode of bordering on in proper order.

In the scheme, a magnetic conduction piece is arranged between every two adjacent strip-shaped magnets.

In the above scheme, the magnet assembly further comprises a positioning rod penetrating through the magnet assembly, or further comprises clamping pieces clamped at two side ends of the magnet assembly.

In the scheme, the shell is internally provided with a guide rail for limiting the sliding direction of each induction power generation assembly; the guide rail is a guide groove or a sliding column; the extending direction of the guide rail is in a linear or arc shape consistent with the shape of the magnet assembly; when the guide rail is a guide groove, the guide groove is positioned at the upper side and the lower side of the magnet assembly, and the induction power generation assembly can slide along the guide groove to cut magnetic lines of force; (ii) a When the guide rail is a sliding column, the sliding column is located on the left side and the right side of the magnet assembly, and a sliding hole used for being sleeved on the sliding column is formed in the induction power generation assembly.

In the above scheme, the vibration power generation device further includes at least one elastic member for providing a return elastic force for each induction power generation assembly.

When the remote control device is used, the induction power generation assembly in the vibration power generation device can generate induction current to supply to the remote control circuit module only by shaking to enable the induction power generation assembly to generate displacement to cut magnetic lines of force, so that the traditional dry battery is replaced as a power supply of the remote control device; in addition, the invention has the advantages of simple and reasonable structure and convenient use, can be used for a long time due to the absence of the corrosion action of the traditional dry battery, is particularly suitable for serving as a power supply for electronic products such as a remote controller and the like which are used intermittently, and has excellent use effect; in addition, the invention does not need to use heavy pollution materials such as mercury and the like the traditional battery, thereby being more environment-friendly.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is an exploded view of the remote control of FIG. 1;

FIG. 3 is an exploded view of the remote control of FIG. 1 from another angle;

fig. 4 is an exploded view of the vibration power generation apparatus in the remote controller shown in fig. 1;

FIG. 5 is an exploded view of a vibration power generation apparatus in a second configuration of the present invention;

fig. 6 is an exploded view of a vibration power generation apparatus in a third configuration of the present invention;

FIG. 7 is a perspective view of a magnet assembly in a fourth configuration of the present invention;

FIG. 8 is a schematic perspective view of a vibration power generation device in a fifth configuration according to the present invention;

fig. 9 is an exploded view of the vibration power generation apparatus shown in fig. 8;

fig. 10 is an exploded view of a vibration power generation apparatus in a sixth configuration of the present invention;

fig. 11 is an exploded view of a vibration power generation device in an eleventh construction of the present invention;

fig. 12 is a schematic structural view of each bundled wire in the vibration power generation device shown in fig. 11.

The reference signs are: the magnetic induction power generation device comprises a shell 1, an upper plate 11, a lower plate 12, a magnet assembly 2, a strip magnet 21, a magnetic conduction piece 22, a positioning rod 23, a clamping piece 24, an induction power generation assembly 3, a coil 31, a power generation part 311, a connecting part 312, a bundling wire 32, a single wire 320, a counterweight 33, a containing cavity 331, a slide hole 34, a guide rail 4, a guide groove 41, a slide column 42, an elastic piece 5, a shell 6, a button 61, a power supply 7, a vibration power generation device 71, a remote control circuit module 8, a circuit board 81, a containing hole 100, a guide boss 200 and a conductive pin 300.

Detailed Description

(example 1)

Fig. 1 to 4 show a first embodiment of the present invention, wherein fig. 1 is a schematic perspective view of a first structure of the present invention; FIG. 2 is an exploded view of the remote control of FIG. 1; FIG. 3 is an exploded view of the remote control of FIG. 1 from another angle; fig. 4 is an exploded view of the vibration power generation device in the remote controller shown in fig. 1.

The present embodiment is a remote controller, see fig. 1 to 4, including a housing 6, a button 61 provided on the housing 6, a power supply 7 provided in the housing 6, a remote control circuit module 8 provided in the housing 6; the remote control circuit module 8 includes a circuit board 81; the power supply 7 is a vibration power generation device 71 which is made by adopting an electromagnetic induction power generation principle.

In this embodiment, the vibration power generation device 71 is fixed on the circuit board 81 by gluing, and is electrically connected to the remote control circuit module 8 through a wire.

As shown in fig. 4, the vibration power generation device 71 includes a housing 1 made of a magnetic conductive material, a magnet assembly 2 for providing a permanent magnetic field, two induction power generation assemblies 3 for generating induction current, and eight elastic members 5 for providing restoring elastic force for each induction power generation assembly 3; the magnet assembly 2 is in a flat and straight plate shape, the induction power generation assemblies 3 are arranged on two sides of the magnet assembly 2, and each induction power generation assembly 3 can cut magnetic lines of force to move and generate induction current under the action of external force.

Each induction power generation assembly 3 comprises four coils 31 and a weight member 33 for fixedly connecting the coils 31; in this embodiment, the weight member 33 is a flat plastic plate integrally connected to the coils 31 by injection molding. The coils 31 or the bundled wires 32 are connected in parallel or in series, which depends on the actual requirement.

Each coil 31 includes two linear power generation sections 311, and connection sections 312 located at both ends of the power generation section 311 for connecting the two linear power generation sections 311; when each of the induction power generating modules 3 includes at least two coils 31, the power generating sections 311 of the adjacent two coils 31 are parallel to each other; when the coils 31 perform magnetic line cutting motion induction power generation, the two linear power generation parts 311 are mainly used for induction power generation, and the two connection ports 312 generate opposite induced electromotive forces to cancel each other out.

As shown in fig. 4, the housing 1 includes a magnetically conductive upper plate 11 and a magnetically conductive lower plate 12, the upper plate 11 and the lower plate 12 are each provided with a guide groove 41 formed by stamping and bending at an end near the inner side of the magnet assembly 2, and the guide groove 41 serves as a guide rail 4 for limiting the sliding direction of each induction power generation assembly 3; the extending direction of the guide rail 4 is a straight line shape consistent with the shape of the magnet assembly 2, and the induction generating assembly 3 can slide in the guide groove 41 and cut magnetic lines of force.

The magnet assembly 2 comprises ten strip magnets 21 and eleven magnetizers 22; each bar magnet 21 has an S-pole at one end and an N-pole at the other end in a direction perpendicular to the movement direction of the induction power generating assembly 3.

One end of each magnet 21 is S-level and the other end is N-level in the direction parallel to the motion direction of the induction power generation assembly 3; the adjacent two bar magnets 21 are arranged in order with like poles abutting. In order to further concentrate the magnetic lines of force in a certain area, the present embodiment further provides a plate-shaped magnetic conductive member 22 made of a magnetic conductive material on each of both sides of each magnet 21.

The magnet 21 and the magnetic conduction member 22 are arranged in a straight plate shape and are relatively fixed and connected into a whole in a laser spot welding or gluing mode.

Two elastic members 5 are respectively arranged at two side ends of each induction generating assembly 3 along the moving direction, the elastic members 5 used in the embodiment are W-shaped folding springs, and in a specific practice, springs with other structural shapes, such as thread springs, can be selected.

(example 2)

Fig. 5 is an exploded view of a vibration power generation apparatus in a second structure of the present invention, showing a second embodiment of the present invention.

This embodiment is substantially the same as embodiment 1 except that: in this embodiment, only one induction power generation unit 3 is provided on one side of the magnet unit 2, and the induction power generation unit 3 has the same structure as the induction power generation unit 3 in embodiment 1.

(example 3)

Fig. 6 is an exploded view of a vibration power generation device in a third configuration of the present invention, showing a third embodiment of the present invention.

This example is substantially the same as example 1, except that: the magnet assembly 2 in this embodiment includes ten bar magnets 21, and no longer includes the magnetic conductive member 22; each bar magnet 21 has one end of S-pole and the other end of N-pole in the direction perpendicular to the movement direction of the induction power generating assembly 3, and specifically, for the present embodiment, each bar magnet 21 has two ends of S-pole and N-pole in the up-down direction.

(example 4)

FIG. 7 is a perspective view of a magnet assembly in a fourth configuration of the present invention, showing a fourth embodiment of the present invention.

This embodiment is substantially the same as embodiment 1 except that: the magnet assembly 2 in this embodiment includes ten bar magnets 21, and no longer includes the magnetic conductive member 22; one end of each strip magnet 21 is S-level and the other end is N-level in the direction vertical to the motion direction of the induction power generation assembly 3; specifically, the bar magnets 21 have an S pole and an N pole at both ends in the left-right direction. In addition, the case 1 is made of a non-magnetic material in this embodiment.

(example 5)

FIGS. 7 and 8 show a fifth embodiment of the invention, in which FIG. 7 is a perspective view of a magnet assembly in a fourth configuration of the invention; fig. 8 is a schematic perspective view of a vibration power generation device in a fifth configuration according to the present invention.

This example is substantially the same as example 1, except that: the magnet assembly 2 is provided with two through holes penetrating through the magnet assembly along the moving direction of the induction power generation assembly, and the strip magnets 21 and the magnetic conduction piece 22 are fixedly connected in series by two positioning rods 23 penetrating through the through holes. Each of the induction power generating modules 3 includes five coils.

Two weight parts 33 in two induction power generation assemblies 3 positioned at two sides of the magnet assembly 2 are clamped to form a containing hole 100, the magnet assembly 2 is sleeved with the containing hole 100, the weight parts 33 are also respectively provided with a convex guiding lug boss 200 at the left side and the right side of the magnet assembly 2, and each guiding lug boss 200 is provided with a sliding hole 34;

in the embodiment, the guide rail 4 is two sliding columns 42 arranged at two sides of the magnet assembly, each sliding column 42 respectively passes through a sliding hole 34 on one induction generating assembly, and the induction generating assembly 3 slides under the guiding action of the sliding column 42.

In addition, the elastic member 5 in this embodiment is not a W-shaped folded spring, but a screw spring, and the screw springs are sleeved on one side end of the sliding column 42, one end of each screw spring abuts against the housing 1, and the other end abuts against the guide boss 200 of the induction power generation assembly 3.

In addition, in the present embodiment, a conductive pin 300 protruding from the housing 1 is provided on each of the slide posts 42, and the conductive pin 300 can be integrally soldered and fixed to the circuit board 81 in the remote control circuit module 8 and electrically connected to the remote control circuit module 8 as two electrodes. In particular practice, it is also possible to provide several more pins 300 on the housing 1, so as to fix itself more firmly on the circuit board 81.

In this embodiment, the circuit board 81 is provided with through holes matching with the pins 300, and each pin 300 is inserted into a corresponding through hole and then is welded and fixed, i.e. ordinary wave soldering; of course, a patch welding mode can be selected according to actual needs.

(example 6)

Fig. 10 is an exploded view of a sixth configuration of the invention showing a sixth embodiment of the invention.

This example is substantially the same as example 5 except that: this embodiment is substantially the same as embodiment 1 except that: in this embodiment, the magnet assembly 2 is not provided with the through hole and the positioning rod 23, but two clamping plates disposed at the left and right ends of the magnet assembly 2 are used as the clamping members 24, and each bar magnet 21 and the magnetic conductive member 22 are fixedly connected under the clamping action of the two clamping plates.

(example 7)

This embodiment is substantially the same as embodiment 1 except that: in this embodiment, a total of four elastic members 5 are provided, and one elastic member 5 is provided at each of the two side ends of each induction power generation assembly 3 in the moving direction.

(example 8)

This embodiment is substantially the same as embodiment 1 except that: in this embodiment, the elastic member 5 is not provided, and the induction generating assemblies 3 are moved only by the external force.

(example 9)

This embodiment is substantially the same as embodiment 1 except that: the shape of magnet subassembly 2 is pitch arc plate form, the whole shape of each response electricity generation subassembly 3 is pitch arc plate form unanimous with magnet subassembly 2, the direction of setting up of guide rail also is unanimous with the pitch arc extending direction of magnet subassembly 2.

(example 10)

This example is substantially the same as example 1, except that: the weight member 33 is a non-magnetic conductive plate body provided with accommodating cavities 331, and each coil 31 is fixed in a corresponding one of the accommodating cavities 331.

(example 11)

Fig. 11 and 12 show an eleventh embodiment of the present invention, wherein fig. 11 is an exploded view of a vibration power generation apparatus in an eleventh configuration of the present invention; fig. 12 is a schematic structural view of each bundled wire in the vibration power generation device shown in fig. 11.

This embodiment is substantially the same as embodiment 1 except that: referring to fig. 11 and 12, the induction power generating device 3 does not use the coil 31, but uses the bundled wires 32, each bundled wire 32 is formed by combining tens of or even hundreds of straight single wires 320, the basic shape is linear, and the bundled wires 32 are parallel to each other. The bundled wires 32 are connected in parallel or in series according to actual needs.

(example 12)

This embodiment is substantially the same as embodiment 1 except that: the magnet assembly in this embodiment includes only one bar magnet 21 and two magnetic conductive members located on both sides of the bar magnet.

(example 13)

This embodiment is substantially the same as embodiment 1 except that: each induction power generating assembly 3 in this embodiment comprises only one coil 31.

(example 14)

This embodiment is substantially the same as embodiment 1 except that: the housing 6 is provided with a containing groove, and the vibration power generation device 71 is clamped and fixed in the containing groove.

(example 15)

This example is substantially the same as example 1, except that: the housing 6 is provided with a containing groove, and the vibration power generation device 71 is clamped and fixed in the containing groove.

(example 15)

This embodiment is substantially the same as embodiment 1 except that: since the vibration power generation device 71 is disposed in the remote controller housing 6 and does not need to be replaced, the housing 6 is made into a sealed waterproof housing in the present embodiment, so that the housing has a better moisture-proof and damp-proof effect and a more reliable use function.

When the embodiments 1 to 15 are used, only the induction power generation assembly in the vibration power generation device needs to be shaken to generate displacement to cut magnetic lines of force, so that the induction power generation assembly can generate induction current to be supplied to the remote control circuit module, and the induction power generation assembly can be used as a power supply of a remote controller instead of a traditional dry battery; in addition, the invention has the advantages of simple and reasonable structure and convenient use, can be used for a long time due to the absence of the corrosion action of the traditional dry battery, is particularly suitable for serving as a power supply for electronic products such as a remote controller and the like which are used intermittently, and has excellent use effect; in addition, the invention does not need to use heavy pollution materials such as mercury and the like the traditional battery, thereby being more environment-friendly.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And such obvious changes and modifications as fall within the true spirit of the invention are deemed to be covered by the present invention.

Claims (10)

1. A remote controller comprises a shell (6), a button (61) arranged on the shell (6), a power supply (7) arranged in the shell (6), and a remote control circuit module (8) arranged in the shell (6); the remote control circuit module (8) comprises a circuit board (81); the method is characterized in that: the power supply (7) is a vibration power generation device (71) manufactured by adopting an electromagnetic induction power generation principle, and a magnet assembly (2) for providing a permanent magnetic field and an induction power generation assembly (3) for cutting magnetic lines of force and generating induction current are arranged in the vibration power generation device (71).

2. The remote controller according to claim 1, wherein: the vibration power generation device is characterized in that a containing groove is formed in the shell (6), and the vibration power generation device (71) is clamped and fixed or fixed in the containing groove in an adhesive mode.

3. The remote controller according to claim 1, wherein: the vibration power generation device (71) is fixed on the circuit board (81) in an adhesive or welding mode.

4. The remote control of claim 3, wherein: the vibration power generation device (71) is provided with a plurality of protruding pins (300), and the pins are welded and fixed on the circuit board (81); the housing (6) is a sealed, waterproof housing.

5. The remote controller according to claim 1, wherein: the vibration power generation device (71) further comprises a shell (1); the magnet assembly (2) is in a straight plate shape or an arc plate shape, the induction power generation assembly (3) is arranged on one side or two sides of the magnet assembly (2), and the induction power generation assembly (3) cuts magnetic lines of force to move under the action of external force and generates induction current; the induction power generation assembly (3) comprises at least one coil (31) or at least one bundled wire (32); when each induction power generation assembly (3) comprises at least two coils (31) or bundled wires (32), the coils (31) or the bundled wires (32) are connected in parallel or in series; the magnet assembly (2) comprises at least one strip-shaped magnet (21); one end of the magnet is S-level and the other end is N-level in the direction parallel to the motion direction of the induction power generation assembly (3), or one end of the magnet is S-level and the other end is N-level in the direction perpendicular to the motion direction of the induction power generation assembly (3).

6. The remote control of claim 5, wherein: each induction power generation assembly (3) further comprises a counterweight part (33) used for fixedly connecting each coil (31) or each bundling wire (32), the counterweight part (33) is a plastic plate which is connected with each coil (31) or each bundling wire (32) into a whole in an injection molding mode or a non-magnetic-conductive plate body provided with an accommodating cavity (331), and each coil (31) or bundling wire (32) is fixed in a corresponding accommodating cavity (331); the shell (1) is a magnetic conduction shell; each coil (31) comprises two linear power generation parts (311) and connecting parts (312) which are positioned at two side ends of the power generation parts (311) and are used for connecting the two linear power generation parts (311); when each induction power generation assembly (3) comprises at least two coils (31), the power generation parts (311) of the two adjacent coils (31) are parallel to each other; the bundling wires (32) are parallel to each other; when the magnet is S level in one end along the direction of motion of induction power generation subassembly (3), and the other end is the N utmost point, magnet subassembly (2) include two at least strip magnetite (21), and two adjacent strip magnetite (21) arrange according to homopolar mode of bordering on in proper order.

7. The remote controller according to claim 6, wherein: a magnetic conduction piece (22) is arranged between two adjacent strip magnets (21).

8. The remote control of claim 6, wherein: the magnet assembly (2) further comprises a positioning rod (23) penetrating through the magnet assembly, or further comprises clamping pieces (24) clamped at two side ends of the magnet assembly.

9. The remote controller according to claim 6, wherein: a guide rail (4) for limiting the sliding direction of each induction generating assembly (3) is arranged in the shell (1); the guide rail (4) is a guide groove (41) or a sliding column (42); the extending direction of the guide rail (4) is in a linear or arc shape consistent with the shape of the magnet assembly (2); when the guide rail (4) is a guide groove (41), the guide groove (41) is positioned on the upper side and the lower side of the magnet assembly (2), and the induction generating assembly (3) can slide along the guide groove (41) to cut magnetic lines of force; (ii) a When guide rail (4) are traveller (42), traveller (42) are located the left and right sides of magnetite subassembly (2), be equipped with on response electricity generation subassembly (3) and be used for the cover to establish slide opening (34) on traveller (42).

10. The remote controller according to one of claims 5 to 9, wherein: the vibration power generation device (71) further comprises at least one elastic piece (5) used for providing reset elastic force for each induction power generation assembly (3).

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