JP2020205226A - Corridor energy-saved indicator lamp capable of generating power by using motion - Google Patents

Abstract

To provide a corridor energy-saved indicator lamp which can generate power by using a motion.SOLUTION: A corridor energy-saved indicator lamp includes a base 18 fixable to a stairway, and a lamp base 11 fixable to a wall. The lamp is simple in a constitution, easy in an operation, convenient in maintenance, and can generate power by using a motion for stepping the stairway when people ascend and descend the stairway. There is no necessity for laying a circuit at a corridor, and also there is no necessity for consuming energy at the corridor.EFFECT: This lamp can switch a normal lighting mode and an emergency lighting mode if necessary, can reduce an installation cost of an emergency lamp at the corridor, can improve a lighting effect of the corridor, and is high in a worth of use and a worth of prevailing.SELECTED DRAWING: Figure 1

Description

The present invention takes up the field of energy-saving lighting, and specifically, is a corridor energy-saving indicator light capable of generating electricity by utilizing exercise.

Corridor indicator lights are luminaires installed in the corridor and can provide lighting to the corridor, but existing corridor indicator lights reduce energy consumption only by controlling the lighting time and are still supported by the electricity in the corridor. Moreover, when installing the corridor indicator lamp, it is necessary to install the lighting circuit independently, the installation process is complicated, the installation cost is relatively high, and the conventional corridor indicator lamp has a function. It is a single, and in the event of an emergency, it is necessary to install and illuminate a separate corridor indicator lamp, and the lighting effect is poor, so the present invention does not require a single circuit to be installed in the corridor energy-saving indicator lamp. The purpose is to design.

Chinese Patent Application Publication No. 102600755

Technical problem:
In normal and emergency situations, conventional corridor indicator lights require two circuits to be installed independently, the installation cost is relatively high, and in the lighting process, they need to be supported by the power of the corridor, energy. High consumption.

In order to solve the above problem, the present invention designs a corridor energy-saving indicator light capable of generating electricity using motion, and the corridor energy-saving indicator light capable of generating electricity using the motion of the present invention may be fixed to a staircase. A base that can be mounted and a lamp base that can be fixed to a wall are included, a slide groove is installed in the base, and a pedal that can slide up and down is installed in the slide groove. A pressing spring is installed so as to have elasticity between the slide groove, and a power generation power chamber communicated with the slide groove is symmetrically installed in the inner walls on both left and right sides of the slide groove to generate power. A turning chamber is symmetrically installed in the inner walls on both the upper and lower sides of the chamber, a power generation chamber is installed in the rear wall of the turning chamber at the top, and a power generation mechanism is installed in the power generation chamber. A turning device capable of holding the rotation direction of the power generation mechanism is installed in the power generation power chamber, power is generated by a person moving up and down a staircase, and a slide chamber is installed in the lamp base. A slidable lamp is installed in the slide chamber, a rotatable lamp plate is installed in the lamp, a lighting lamp capable of normal illumination is installed at the bottom end of the lamp plate, and the top end of the lamp plate is installed. An emergency light capable of emergency lighting is installed in the room, a symmetrical refraction chamber is installed in the inner walls on both the left and right sides of the slide chamber, and a refraction device is installed in the refraction chamber to further expand the lighting range. A switching chamber can be installed in the wall of the refracting chamber on the right side close to the slide chamber, and the switching device capable of switching the lighting state of the equipment in the switching chamber. Is installed, a storage device capable of accommodating the lamp is installed in the slide chamber, and a power chamber is installed in the top wall of the slide chamber to control the operating state of the equipment. A drive unit is installed in the chamber to provide lighting in the corridor, and floor lamps are installed on the outer walls of the base and the pedals to be used for floor guidance.

Preferably, the turning device includes a drive shaft installed in the power generation chamber, racks are symmetrically installed on the left and right end walls of the pedal, and the rack is installed at the rear end of the drive shaft. A drive gear that meshes with the drive gear is installed, a drive bevel gear is installed at the front end of the drive shaft, a vertically symmetrical turning shaft is installed in the power generation power chamber, and the power generation power chamber of the turning shaft is installed. A turning bevel gear that meshes with the driving bevel gear is installed at one end close to the gear, and the turning shaft can be interlocked to rotate, and one end of the turning shaft that is separated from the power generation power chamber A turning gear located in the turning chamber is installed, a vertical axis is installed in the turning chamber, and an outer wall of the vertical axis is located in the turning chamber and is located in the turning chamber. A unidirectional gear that meshes with the turning gear is installed, and a unidirectional bevel gear that can be rotated in conjunction with the power generation mechanism is installed at the top end of the vertical shaft, and rotation of the unidirectional gear at both upper and lower ends. The possible directions are opposite, and when the rotation direction of the drive gear changes, the rotation direction of the bevel gear in the same direction does not change.

Preferably, the power generation mechanism includes a lateral shaft installed in the turning chamber, at the front end of the lateral shaft a power generation bevel gear that meshes with the co-directional bevel gear, further interlocking the lateral shafts. It can be rotated, a ring gear is installed at the rear end of the lateral shaft, a power generation shaft is installed in the turning chamber, a sun gear is installed at the front end of the power generation shaft, and the sun gear and the above. A planetary gear is installed between the ring gear so that it can be transmitted, and the power generation shaft can be interlocked to rotate at high speed. At the rear end of the power generation shaft, a mouth located in the power generation chamber A type permanent magnet was installed, a coil was installed in the power generation chamber, and a battery capable of storing electric energy was installed in the bottom wall of the power generation chamber.

Preferably, the drive unit includes a prime mover installed in the power chamber, in which a power shaft connected to the prime mover so that power can be transmitted is installed, and the apex of the power shaft. A power gear is installed in the power chamber, a transmission shaft is installed in the power chamber, and a transmission gear located in the power chamber and meshing with the power gear is on the outer wall of the transmission shaft. A transmission bevel gear that is installed and can be rotated in conjunction with the transmission shaft, and can be rotated in conjunction with the refracting device is installed at the top end of the transmission shaft, and the outer wall of the transmission shaft is said to have the above. A main pulley that can be rotated in conjunction with the switching device is installed, and a worm that is located in the slide chamber on the outer wall of the transmission shaft and can be rotated in conjunction with the storage device is provided. It was installed.

Preferably, the storage device includes a stretch shaft symmetrically installed in the slide chamber, a worm wheel meshing with the worm is installed at the rear end of the stretch shaft, and the stretch shaft is further mounted. It can be rotated in conjunction with each other, a driving bevel gear is installed at the front end of the extension shaft, a cam shaft is installed symmetrically in the slide chamber, and the cam shaft is close to the transmission shaft. A driven bevel gear that meshes with the main driving bevel gear is installed at one end thereof, and a cam that can contact and cooperate with the lamp is installed at one end of the cam shaft that is distant from the transmission shaft. Further, the driven bevel gear can be slid downward by interlocking the lamp with the cam shaft and the cam, and the return spring is installed between the lamp and the top wall of the slide chamber so as to have elasticity. Was done.

Preferably, the refracting device includes a reflector installed so that it can rotate on the driven bevel gear, the reflectors on both the left and right sides can cooperate to close the slide chamber, and a screw rod is contained in the refracting chamber. A slidable slider is installed on the outer wall of the screw rod, the slider and the screw rod are connected by a screw thread, the slider and the reflector are connected by a hinge through a conrod, and further, the above. The reflectors can be rotated in conjunction with each other, and symmetrical reflection shafts are installed in the power chamber, and one end of the reflection shafts close to the power chamber is inside the power chamber. A refraction bevel gear that is positioned and meshes with the transmission bevel gear is installed, power is transmitted between the reflection shaft and the screw rod by a transmission belt, and the reflection shaft interlocks the screw rod with the transmission belt. It can be rotated.

Preferably, the switching device includes a transmission shaft installed in the power chamber, and a driven pulley located in the power chamber is installed at the top end of the transmission shaft, and the driven pulley and the driven pulley are installed. A transmission belt is installed between the pulley and the transmission belt so that it can be transmitted, and the transmission shaft can be rotated in conjunction with the transmission shaft. A driven shaft is installed in the switching chamber, and the left end of the driven shaft is the said. A switching bevel gear that is fixedly connected to the lamp plate and is located at the right end of the driven shaft is installed in the switching chamber, and the lamp plate can be further interlocked and rotated, and further, the equipment. A slidable spline shaft is installed in the switching chamber to switch the illumination state, the spline shaft and the transmission shaft are connected by a spline, and the bottom end of the spline shaft meshes with the switching bevel gear. A rotating bevel gear is installed, and the switching bevel gear can be interlocked to rotate. A rotating block is installed on the outer wall of the spline shaft, and an electromagnetic groove is formed in the top wall of the switching chamber. It is installed so that a permanent magnet fixedly connected to the rotating block can slide in the electromagnetic groove, and the permanent magnet is interlocked and slides up and down in the top wall of the electromagnetic groove. An electromagnet that can be rotated was installed, and an electromagnetic spring was installed between the electromagnet and the permanent magnet so as to have elasticity.

The beneficial effects of the present invention are: The present invention is simple to configure, easy to operate, convenient to maintain, and the equipment generates power by utilizing the action of stepping on the stairs when a person goes up and down the stairs. There is no need to lay a circuit in the corridor, there is no need to consume energy in the corridor, the equipment can switch between normal and emergency lighting modes in some cases, and the cost of installing emergency lights in the corridor It can be lowered and the lighting effect in the corridor can be improved, so that the equipment has high utility value and widespread value.

In order to explain the present invention in detail with reference to FIGS. 1 to 5 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention, and is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic diagram of the overall configuration of a corridor energy-saving indicator lamp that can generate electricity using the motion of the present invention. FIG. 2 is a schematic configuration diagram of A in FIG. FIG. 3 is a schematic configuration diagram of B in FIG. FIG. 4 is a schematic configuration diagram of C in FIG. FIG. 5 is a schematic configuration diagram of DD of FIG.

The present invention relates to a corridor energy-saving indicator lamp that can generate electricity by utilizing exercise, and is mainly applied to lighting work in a corridor. The present invention will be further described below with reference to the drawings of the present invention.

The corridor energy-saving indicator light capable of generating electricity by utilizing the motion of the present invention includes a base 18 that can be fixed to a staircase and a lamp base 11 that can be fixed to a wall. A slide groove 21 is installed, a pedal 20 that can slide up and down is installed in the slide groove 21, and a pressing spring 22 is installed between the pedal 20 and the slide groove 21 so as to have elasticity. The power generation power chamber 80 communicated with the slide groove 21 is symmetrically installed in the inner walls on both the left and right sides of the slide groove 21, and the turning chamber 27 is inside the inner walls on both the upper and lower sides of the power generation power chamber 80. It is installed symmetrically, a power generation chamber 25 is installed in the rear wall of the turning chamber 27 at the top, a power generation mechanism 102 is installed in the power generation chamber 25, and a power generation mechanism 102 is installed in the power generation power chamber 80. A turning device 101 capable of holding the rotation direction of the power generation mechanism 102 is installed, and power is generated by a person moving up and down a staircase. A slide chamber 12 is installed in the lamp base 11, and the slide chamber 12 is installed. A slidable lamp 17 is installed inside the lamp 17, a rotatable lamp plate 15 is installed inside the lamp 17, and a lighting lamp 16 capable of normal illumination is installed at the bottom end of the lamp plate 15, and the lamp plate is installed. An emergency light 14 capable of emergency lighting is installed at the apex of the 15th, a symmetrical refraction chamber 52 is installed in the inner walls on both left and right sides of the slide chamber 12, and a refracting device 105 is installed in the refracting chamber 52. The switching chamber 72 is installed in the wall of the refracting chamber 52 on the right side close to the slide chamber 12, and the switching chamber 72 is inside the switching chamber 72. A switching device 106 capable of switching the lighting state of the equipment is installed, and a storage device 104 capable of controlling the operating state of the equipment and accommodating the lamp 17 is installed in the slide chamber 12, and the slide. A power chamber 37 is installed in the top wall of the chamber 12, a drive device 103 is installed in the power chamber 37, and lighting can be provided in the corridor, and the outer walls of the base 18 and the pedal 20 are provided. A floor lamp 19 is installed and used for floor guidance.

According to the embodiment, the turning device 101 will be described in detail below, and the turning device 101 includes a drive shaft 78 installed in the power generation power chamber 80, and racks are attached to the left and right end walls of the pedal 20. 73 is installed symmetrically, a drive gear 79 that meshes with the rack 73 is installed at the rear end of the drive shaft 78, and a drive bevel gear 77 is installed at the front end of the drive shaft 78. A vertically symmetrical turning shaft 75 is installed in the 80, and a turning bevel gear 76 that meshes with the drive bevel gear 77 is installed at one end of the turning shaft 75 that is close to the power generation power chamber 80, and further. The turning shaft 75 can be interlocked and rotated, and a turning gear 74 located in the turning chamber 27 is installed at one end of the turning shaft 75 away from the power generation power chamber 80. A vertical shaft 35 is installed in the turning chamber 27, and a unidirectional gear 34 located in the turning chamber 27 on the outer wall of the vertical shaft 35 and meshing with the turning gear 74. Is installed, and the same-direction bevel gear 33 capable of interlocking and rotating the power generation mechanism 102 is installed at the top end of the vertical axis 35, and the directions in which the one-way gears 34 at both the upper and lower ends can rotate are opposite. Further, when the rotation direction of the drive gear 79 changes, the rotation direction of the bevel gear 33 in the same direction does not change.

According to the embodiment, the power generation mechanism 102 will be described in detail below, and the power generation mechanism 102 includes a lateral shaft 31 installed in the turning chamber 27, and the front end of the lateral shaft 31 is a bevel gear 33 in the same direction. A power generation bevel gear 32 that meshes with the horizontal shaft 31 is installed, and the lateral shaft 31 can be interlocked and rotated. A ring gear 30 is installed at the rear end of the horizontal shaft 31, and power is generated in the turning chamber 27. A shaft 26 is installed, a sun gear 29 is installed at the front end of the power generation shaft 26, a planetary gear 28 is installed between the sun gear 29 and the ring gear 30 so that the planetary gear 28 can be transmitted, and further, the power generation shaft 26 is installed. A mouth-shaped permanent magnet 24 located in the power generation chamber 25 is installed at the rear end of the power generation shaft 26, and a coil 23 is installed in the power generation chamber 25. Was installed, and a battery 99 capable of storing electric energy was installed in the bottom wall of the power generation chamber 25.

According to the embodiment, the drive device 103 will be described in detail below, the drive device 103 includes a prime mover 44 installed in the power chamber 37, and the prime mover 44 and power are contained in the power chamber 37. A power shaft 43 connected so as to be able to transmit is installed, a power gear 41 is installed at the top end of the power shaft 43, a power transmission shaft 45 is installed in the power chamber 37, and an outer wall of the power transmission shaft 45 is installed. A transmission gear 42 located in the power chamber 37 and meshing with the power gear 41 is installed in the power chamber 37, and the transmission shaft 45 can be interlocked and rotated, and the transmission shaft 45 can be rotated. A transmission bevel gear 39 capable of interlocking and rotating the refracting device 105 is installed at the apex end, and a driving pulley 40 capable of interlocking and rotating the switching device 106 is installed on the outer wall of the transmission shaft 45. On the outer wall of the transmission shaft 45, a worm 46, which is located in the slide chamber 12 and can be rotated in conjunction with the storage device 104, is installed.

According to the embodiment, the storage device 104 will be described in detail below, and the storage device 104 includes an extension shaft 49 installed symmetrically in the slide chamber 12, and at the rear end of the extension shaft 49. A worm wheel 47 that meshes with the worm 46 is installed, and the extension shaft 49 can be interlocked and rotated. A driving bevel gear 48 is installed at the front end of the extension shaft 49, and the inside of the slide chamber 12 A cam shaft 62 is installed symmetrically in the cam shaft 62, and a driven bevel gear 50 that meshes with the main driving bevel gear 48 is installed at one end of the cam shaft 62 that is close to the transmission shaft 45. A cam 61 capable of contacting and cooperating with the lamp 17 is installed at one end of the transmission shaft 45 away from the transmission shaft 45, and the driving bevel gear 48 is further connected to the lamp by the cam shaft 62 and the cam 61. 17 can be interlocked and slid downward, and a return spring 13 is installed between the lamp 17 and the top wall of the slide chamber 12 so as to have elasticity.

According to the embodiment, the refracting device 105 will be described in detail below, and the refracting device 105 includes a reflector 36 installed so as to be rotatable on the driven bevel gear 50, and the reflectors 36 on both the left and right sides cooperate with each other. The slide chamber 12 can be closed, a screw rod 55 is installed in the refraction chamber 52, a slideable slider 54 is installed on the outer wall of the screw rod 55, and a screw is inserted between the slider 54 and the screw rod 55. It is connected by a mountain, and the slider 54 and the reflector 36 are connected by a hinge through a conrod 53, and the reflector 36 can be interlocked and rotated, and is symmetrical in the power chamber 37. The refraction bevel gear 38 is located at one end of the reflection shaft 65 close to the power chamber 37 and is located in the power chamber 37 and meshes with the transmission bevel gear 39. Is installed, power is transmitted between the reflection shaft 65 and the screw rod 55 by a transmission belt 64, and the reflection shaft 65 can be rotated by interlocking the screw rod 55 with the transmission belt 64.

According to the embodiment, the switching device 106 will be described in detail below, and the switching device 106 includes a transmission shaft 60 installed in the power chamber 37, and the top end of the transmission shaft 60 is a power chamber 37. A driven pulley 63 located inside is installed, a transmission belt 66 is installed between the driven pulley 63 and the main pulley 40 so that the transmission belt 66 can be transmitted, and the transmission shaft 60 is interlocked and rotated. A driven shaft 51 is installed in the switching chamber 72, the left end of the driven shaft 51 is fixedly connected to the lamp plate 15, and the right end of the driven shaft 51 is in the switching chamber 72. A switching bevel gear 57 located at is installed, and the lamp plate 15 can be interlocked to rotate, and the lighting state of the equipment is switched, and a slideable spline shaft 59 is provided in the switching chamber 72. A rotary bevel gear 58 that is installed, the spline shaft 59 and the transmission shaft 60 are connected by a spline, and a rotary bevel gear 58 that can mesh with the switching bevel gear 57 is installed at the bottom end of the spline shaft 59, and further, the switching bevel gear. A rotating block 71 that can be rotated in conjunction with the 57 and that can be rotated is installed on the outer wall of the spline shaft 59, and an electromagnetic groove 68 is installed in the top wall of the switching chamber 72. A permanent magnet 70 fixedly connected to the rotating block 71 is installed in the inside so as to be slidable, and the permanent magnet 70 is interlocked and slid up and down in the top wall of the electromagnetic groove 68. An electromagnet 67 capable of rotating the magnet 67 was installed, and an electromagnetic spring 69 was installed between the electromagnet 67 and the permanent magnet 70 so as to have elasticity.

The following details the steps of using the corridor energy-saving indicator lamp that can generate electricity using the motion of the present invention with reference to the following figures:

In the initial state, the reflectors 36 on both the left and right sides are in contact with each other, the electromagnet 67 is not energized, and the rotating bevel gear 58 is separated from the contact with the switching bevel gear 57.

When using the equipment: When a person goes up and down a staircase, the pedal 20 is stepped on, the pedal 20 slides up and down, and the rack 73, the drive gear 79, the drive shaft 78, the drive bevel gear 77, and so on. The turning shaft 75, the turning gear 74, the one-way gear 34, and the vertical shaft 35 interlock the same-direction bevel gear 33 to hold the rotation in the same direction, and the same-direction bevel gear 33 is the power generation bevel gear 32. The lateral shaft 31, the ring gear 30, the planetary gear 28, the sun gear 29, and the power generation shaft 26 interlock and rotate the mouth-shaped permanent magnet 24, and the mouth-shaped permanent magnet 24 and the coil 23 move relative to each other. The coil 23 cuts the lines of magnetic force to generate electric energy and stores it in the battery 99.

At the time of lighting, the prime mover 44 starts to operate, and the power shaft 43, the power gear 41, the transmission gear 42, and the transmission shaft 45 rotate the main pulley 40, the transmission bevel gear 39, and the worm 46 in conjunction with each other. The transmission bevel gear 39 is slid toward the side close to the slide chamber 12 by interlocking the slider 54 with the refraction bevel gear 38, the reflection shaft 65, the transmission belt 64, and the screw rod 55, and further by the conrod 53, the reflection plate 36. The left and right reflecting plates 36 are separated and the slide chamber 12 is opened. At the same time, the worm 46 includes the worm wheel 47, the extension shaft 49, the main bevel gear 48, the driven bevel gear 50, and the cam. The cam 61 is interlocked with the shaft 62 to rotate, and the cam 61 is interlocked with the lamp 17 to slide downward. At the same time, the illumination lamp 16 emits light to illuminate the corridor.

When an emergency occurs, the electromagnet 67 is energized and the permanent magnet 70 and the rotating block 71 interlock the spline shaft 59 and slide it downward, and the rotating bevel gear 58 and the switching bevel gear 57 mesh with each other. The transmission belt 66, the driven pulley 63, the transmission shaft 60, the spline shaft 59, the rotating bevel gear 58, the switching bevel gear 57, and the driven shaft 51 are used to rotate the lamp plate 15 in conjunction with each other, and further to the illumination lamp 16. When the position with the first aid light 14 is switched and the lamp plate 15 rotates 180 degrees, the power of the electromagnet 67 is turned off, the rotating bevel gear 58 is separated from the contact with the switching bevel gear 57, the first aid light 14 emits light, and the corridor. Illuminate.

The beneficial effects of the present invention are: The present invention is simple to configure, easy to operate, convenient to maintain, and the equipment generates power by utilizing the action of stepping on the stairs when a person goes up and down the stairs. There is no need to lay a circuit in the corridor, there is no need to consume energy in the corridor, the equipment can switch between normal and emergency lighting modes in some cases, and the cost of installing emergency lights in the corridor It can be lowered and the lighting effect in the corridor can be improved, so that the equipment has high utility value and widespread value.

The above is merely a specific embodiment of the present invention, but the scope of protection of the present invention is not limited to this. Changes and replacements that come to mind through all creative labor are covered by the scope of the invention. Therefore, the scope of protection of the present invention is based on the scope of protection in which the request for rights is limited.

The present invention takes up the field of energy-saving lighting, and specifically, is a corridor energy-saving indicator light capable of generating electricity by utilizing exercise.

Corridor indicator lights are luminaires installed in the corridor and can provide lighting to the corridor, but existing corridor indicator lights reduce energy consumption only by controlling the lighting time and are still supported by the electricity in the corridor. Moreover, when installing the corridor indicator lamp, it is necessary to install the lighting circuit independently, the installation process is complicated, the installation cost is relatively high, and the conventional corridor indicator lamp has a function. It is a single, and in the event of an emergency, it is necessary to install and illuminate a separate corridor indicator lamp, and the lighting effect is poor, so the present invention does not require a single circuit to be installed in the corridor energy-saving indicator lamp. The purpose is to design.

Chinese Patent Application Publication No. 102600755

Technical problem: Traditional corridor indicator lights require two circuits to be installed independently in normal and emergency situations, the installation cost is relatively high, and the lighting process needs to be supported by the power of the corridor. Yes, energy consumption is high.

In order to solve the above problem, the present invention designs a corridor energy-saving indicator light capable of generating electricity using motion, and the corridor energy-saving indicator light capable of generating electricity using the motion of the present invention may be fixed to a staircase. A base that can be mounted and a lamp base that can be fixed to a wall are included, a slide groove is installed in the base, and a pedal that can slide up and down is installed in the slide groove. A pressing spring is installed so as to have elasticity between the slide groove, and a power generation power chamber communicated with the slide groove is symmetrically installed in the inner walls on both left and right sides of the slide groove to generate power. A turning chamber is symmetrically installed in the inner walls on both the upper and lower sides of the chamber, a power generation chamber is installed in the rear wall of the turning chamber at the top, and a power generation mechanism is installed in the power generation chamber. A turning device capable of holding the rotation direction of the power generation mechanism is installed in the power generation power chamber, power is generated by a person moving up and down a staircase, and a slide chamber is installed in the lamp base. A slidable lamp is installed in the slide chamber, a rotatable lamp plate is installed in the lamp, a lighting lamp capable of normal illumination is installed at the bottom end of the lamp plate, and the top end of the lamp plate is installed. An emergency light capable of emergency lighting is installed in the room, a symmetrical refraction chamber is installed in the inner walls on both the left and right sides of the slide chamber, and a refraction device is installed in the refraction chamber to further expand the lighting range. A switching chamber can be installed in the wall of the refracting chamber on the right side close to the slide chamber, and the switching device capable of switching the lighting state of the equipment in the switching chamber. Is installed, a storage device capable of accommodating the lamp is installed in the slide chamber, and a power chamber is installed in the top wall of the slide chamber to control the operating state of the equipment. A drive unit is installed in the chamber to provide lighting in the corridor, and floor lamps are installed on the outer walls of the base and the pedals to be used for floor guidance.

Preferably, the turning device includes a drive shaft installed in the power generation chamber, racks are symmetrically installed on the left and right end walls of the pedal, and the rack is installed at the rear end of the drive shaft. A drive gear that meshes with the drive gear is installed, a drive bevel gear is installed at the front end of the drive shaft, a vertically symmetrical turning shaft is installed in the power generation power chamber, and the power generation power chamber of the turning shaft is installed. A turning bevel gear that meshes with the driving bevel gear is installed at one end close to the gear, and the turning shaft can be interlocked to rotate, and one end of the turning shaft that is separated from the power generation power chamber A turning gear located in the turning chamber is installed, a vertical axis is installed in the turning chamber, and an outer wall of the vertical axis is located in the turning chamber and is located in the turning chamber. A unidirectional gear that meshes with the turning gear is installed, and a unidirectional bevel gear that can be rotated in conjunction with the power generation mechanism is installed at the top end of the vertical shaft, and rotation of the unidirectional gear at both upper and lower ends. The possible directions are opposite, and when the rotation direction of the drive gear changes, the rotation direction of the bevel gear in the same direction does not change.

Preferably, the power generation mechanism includes a lateral shaft installed in the turning chamber, at the front end of the lateral shaft a power generation bevel gear that meshes with the co-directional bevel gear, further interlocking the lateral shafts. It can be rotated, a ring gear is installed at the rear end of the lateral shaft, a power generation shaft is installed in the turning chamber, a sun gear is installed at the front end of the power generation shaft, and the sun gear and the above. A planetary gear is installed between the ring gear so that it can be transmitted, and the power generation shaft can be interlocked to rotate at high speed. At the rear end of the power generation shaft, a mouth located in the power generation chamber A type permanent magnet was installed, a coil was installed in the power generation chamber, and a battery capable of storing electric energy was installed in the bottom wall of the power generation chamber.

Preferably, the drive unit includes a prime mover installed in the power chamber, in which a power shaft connected to the prime mover so that power can be transmitted is installed, and the apex of the power shaft. A power gear is installed in the power chamber, a transmission shaft is installed in the power chamber, and a transmission gear located in the power chamber and meshing with the power gear is on the outer wall of the transmission shaft. A transmission bevel gear that is installed and can be rotated in conjunction with the transmission shaft, and can be rotated in conjunction with the refracting device is installed at the top end of the transmission shaft, and the outer wall of the transmission shaft is said to have the above. A main pulley that can be rotated in conjunction with the switching device is installed, and a worm that is located in the slide chamber on the outer wall of the transmission shaft and can be rotated in conjunction with the storage device is provided. It was installed.

Preferably, the storage device includes a stretch shaft symmetrically installed in the slide chamber, a worm wheel meshing with the worm is installed at the rear end of the stretch shaft, and the stretch shaft is further mounted. It can be rotated in conjunction with each other, a driving bevel gear is installed at the front end of the extension shaft, a cam shaft is installed symmetrically in the slide chamber, and the cam shaft is close to the transmission shaft. A driven bevel gear that meshes with the main driving bevel gear is installed at one end thereof, and a cam that can contact and cooperate with the lamp is installed at one end of the cam shaft that is distant from the transmission shaft. Further, the driven bevel gear can be slid downward by interlocking the lamp with the cam shaft and the cam, and the return spring is installed between the lamp and the top wall of the slide chamber so as to have elasticity. Was done.

Preferably, the refracting device includes a reflector installed in the slide chamber so that it can rotate, the reflectors on both the left and right sides can cooperate to close the slide chamber, and a screw rod is contained in the refracting chamber. A slidable slider is installed on the outer wall of the screw rod, the slider and the screw rod are connected by a screw thread, the slider and the reflector are connected by a hinge through a conrod, and further, the above. The reflectors can be rotated in conjunction with each other, and symmetrical reflection shafts are installed in the power chamber, and one end of the reflection shafts close to the power chamber is inside the power chamber. A refraction bevel gear that is positioned and meshes with the transmission bevel gear is installed, power is transmitted between the reflection shaft and the screw rod by a transmission belt, and the reflection shaft interlocks the screw rod with the transmission belt. It can be rotated.

Preferably, the switching device includes a transmission shaft installed in the power chamber, and a driven pulley located in the power chamber is installed at the top end of the transmission shaft, and the driven pulley and the driven pulley are installed. A transmission belt is installed between the pulley and the transmission belt so that it can be transmitted, and the transmission shaft can be rotated in conjunction with the transmission shaft. A driven shaft is installed in the switching chamber, and the left end of the driven shaft is the said. A switching bevel gear that is fixedly connected to the lamp plate and is located at the right end of the driven shaft is installed in the switching chamber, and the lamp plate can be further interlocked and rotated, and further, the equipment. A slidable spline shaft is installed in the switching chamber to switch the illumination state, the spline shaft and the transmission shaft are connected by a spline, and the bottom end of the spline shaft meshes with the switching bevel gear. A rotating bevel gear is installed, and the switching bevel gear can be interlocked to rotate. A rotating block is installed on the outer wall of the spline shaft, and an electromagnetic groove is formed in the top wall of the switching chamber. It is installed so that a permanent magnet fixedly connected to the rotating block can slide in the electromagnetic groove, and the permanent magnet is interlocked and slides up and down in the top wall of the electromagnetic groove. An electromagnet that can be rotated was installed, and an electromagnetic spring was installed between the electromagnet and the permanent magnet so as to have elasticity.

The beneficial effects of the present invention are: The present invention is simple to configure, easy to operate, convenient to maintain, and the equipment generates power by utilizing the action of stepping on the stairs when a person goes up and down the stairs. There is no need to lay a circuit in the corridor, there is no need to consume energy in the corridor, the equipment can switch between normal and emergency lighting modes in some cases, and the cost of installing emergency lights in the corridor It can be lowered and the lighting effect in the corridor can be improved, so that the equipment has high utility value and widespread value.

In order to explain the present invention in detail with reference to FIGS. 1 to 5 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention, and is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic diagram of the overall configuration of a corridor energy-saving indicator lamp that can generate electricity using the motion of the present invention. FIG. 2 is a schematic configuration diagram of A in FIG. FIG. 3 is a schematic configuration diagram of B in FIG. FIG. 4 is a schematic configuration diagram of C in FIG. FIG. 5 is a schematic configuration diagram of DD of FIG.

The present invention relates to a corridor energy-saving indicator lamp that can generate electricity by utilizing exercise, and is mainly applied to lighting work in a corridor. The present invention will be further described below with reference to the drawings of the present invention.

The corridor energy-saving indicator light capable of generating electricity by utilizing the motion of the present invention includes a base 18 that can be fixed to a staircase and a lamp base 11 that can be fixed to a wall. A slide groove 21 is installed, a pedal 20 that can slide up and down is installed in the slide groove 21, and a pressing spring 22 is installed between the pedal 20 and the slide groove 21 so as to have elasticity. The power generation power chamber 80 communicated with the slide groove 21 is symmetrically installed in the inner walls on both the left and right sides of the slide groove 21, and the turning chamber 27 is inside the inner walls on both the upper and lower sides of the power generation power chamber 80. It is installed symmetrically, a power generation chamber 25 is installed in the rear wall of the turning chamber 27 at the top, a power generation mechanism 102 is installed in the power generation chamber 25, and a power generation mechanism 102 is installed in the power generation power chamber 80. A turning device 101 capable of holding the rotation direction of the power generation mechanism 102 is installed, and power is generated by a person moving up and down a staircase. A slide chamber 12 is installed in the lamp base 11, and the slide chamber 12 is installed. A slidable lamp 17 is installed inside the lamp 17, a rotatable lamp plate 15 is installed inside the lamp 17, and a lighting lamp 16 capable of normal illumination is installed at the bottom end of the lamp plate 15, and the lamp plate is installed. An emergency light 14 capable of emergency lighting is installed at the apex of the 15th, a symmetrical refraction chamber 52 is installed in the inner walls on both left and right sides of the slide chamber 12, and a refracting device 105 is installed in the refracting chamber 52. The switching chamber 72 is installed in the wall of the refracting chamber 52 on the right side close to the slide chamber 12, and the switching chamber 72 is inside the switching chamber 72. A switching device 106 capable of switching the lighting state of the equipment is installed, and a storage device 104 capable of controlling the operating state of the equipment and accommodating the lamp 17 is installed in the slide chamber 12, and the slide. A power chamber 37 is installed in the top wall of the chamber 12, a drive device 103 is installed in the power chamber 37, and lighting can be provided in the corridor, and the outer walls of the base 18 and the pedal 20 are provided. A floor lamp 19 is installed and used for floor guidance.

According to the embodiment, the turning device 101 will be described in detail below, and the turning device 101 includes a drive shaft 78 installed in the power generation power chamber 80, and racks are attached to the left and right end walls of the pedal 20. 73 is installed symmetrically, a drive gear 79 that meshes with the rack 73 is installed at the rear end of the drive shaft 78, and a drive bevel gear 77 is installed at the front end of the drive shaft 78. A vertically symmetrical turning shaft 75 is installed in the 80, and a turning bevel gear 76 that meshes with the drive bevel gear 77 is installed at one end of the turning shaft 75 that is close to the power generation power chamber 80, and further. The turning shaft 75 can be interlocked and rotated, and a turning gear 74 located in the turning chamber 27 is installed at one end of the turning shaft 75 away from the power generation power chamber 80. A vertical shaft 35 is installed in the turning chamber 27, and a unidirectional gear 34 located in the turning chamber 27 on the outer wall of the vertical shaft 35 and meshing with the turning gear 74. Is installed, and the same-direction bevel gear 33 capable of interlocking and rotating the power generation mechanism 102 is installed at the top end of the vertical axis 35, and the directions in which the one-way gears 34 at both the upper and lower ends can rotate are opposite. Further, when the rotation direction of the drive gear 79 changes, the rotation direction of the bevel gear 33 in the same direction does not change.

According to the embodiment, the power generation mechanism 102 will be described in detail below, and the power generation mechanism 102 includes a lateral shaft 31 installed in the turning chamber 27, and the front end of the lateral shaft 31 is a bevel gear 33 in the same direction. A power generation bevel gear 32 that meshes with the horizontal shaft 31 is installed, and the lateral shaft 31 can be interlocked and rotated. A ring gear 30 is installed at the rear end of the horizontal shaft 31, and power is generated in the turning chamber 27. A shaft 26 is installed, a sun gear 29 is installed at the front end of the power generation shaft 26, a planetary gear 28 is installed between the sun gear 29 and the ring gear 30 so that the planetary gear 28 can be transmitted, and further, the power generation shaft 26 is installed. A mouth-shaped permanent magnet 24 located in the power generation chamber 25 is installed at the rear end of the power generation shaft 26, and a coil 23 is installed in the power generation chamber 25. Was installed, and a battery 99 capable of storing electric energy was installed in the bottom wall of the power generation chamber 25.

According to the embodiment, the drive device 103 will be described in detail below, the drive device 103 includes a prime mover 44 installed in the power chamber 37, and the prime mover 44 and power are contained in the power chamber 37. A power shaft 43 connected so as to be able to transmit is installed, a power gear 41 is installed at the top end of the power shaft 43, a power transmission shaft 45 is installed in the power chamber 37, and an outer wall of the power transmission shaft 45 is installed. A transmission gear 42 located in the power chamber 37 and meshing with the power gear 41 is installed in the power chamber 37, and the transmission shaft 45 can be interlocked and rotated, and the transmission shaft 45 can be rotated. A transmission bevel gear 39 capable of interlocking and rotating the refracting device 105 is installed at the apex end, and a driving pulley 40 capable of interlocking and rotating the switching device 106 is installed on the outer wall of the transmission shaft 45. On the outer wall of the transmission shaft 45, a worm 46, which is located in the slide chamber 12 and can be rotated in conjunction with the storage device 104, is installed.

According to the embodiment, the storage device 104 will be described in detail below, and the storage device 104 includes an extension shaft 49 installed symmetrically in the slide chamber 12, and at the rear end of the extension shaft 49. A worm wheel 47 that meshes with the worm 46 is installed, and the extension shaft 49 can be interlocked and rotated. A driving bevel gear 48 is installed at the front end of the extension shaft 49, and the inside of the slide chamber 12 A cam shaft 62 is installed symmetrically in the cam shaft 62, and a driven bevel gear 50 that meshes with the main driving bevel gear 48 is installed at one end of the cam shaft 62 that is close to the transmission shaft 45. A cam 61 capable of contacting and cooperating with the lamp 17 is installed at one end of the transmission shaft 45 away from the transmission shaft 45, and the driving bevel gear 48 is further connected to the lamp by the cam shaft 62 and the cam 61. 17 can be interlocked and slid downward, and a return spring 13 is installed between the lamp 17 and the top wall of the slide chamber 12 so as to have elasticity.

According to the embodiment, the refracting device 105 will be described in detail below, and the refracting device 105 includes a reflector 36 installed so as to be rotatable in the slide chamber 12, and the reflectors 36 on both the left and right sides cooperate with each other. The slide chamber 12 can be closed, a screw rod 55 is installed in the refraction chamber 52, a slideable slider 54 is installed on the outer wall of the screw rod 55, and a screw is inserted between the slider 54 and the screw rod 55. It is connected by a mountain, and the slider 54 and the reflector 36 are connected by a hinge through a conrod 53, and the reflector 36 can be interlocked and rotated, and is symmetrical in the power chamber 37. The refraction bevel gear 38 is located at one end of the reflection shaft 65 close to the power chamber 37 and is located in the power chamber 37 and meshes with the transmission bevel gear 39. Is installed, power is transmitted between the reflection shaft 65 and the screw rod 55 by a transmission belt 64, and the reflection shaft 65 can be rotated by interlocking the screw rod 55 with the transmission belt 64.

According to the embodiment, the switching device 106 will be described in detail below, and the switching device 106 includes a transmission shaft 60 installed in the power chamber 37, and the top end of the transmission shaft 60 is a power chamber 37. A driven pulley 63 located inside is installed, a transmission belt 66 is installed between the driven pulley 63 and the main pulley 40 so that the transmission belt 66 can be transmitted, and the transmission shaft 60 is interlocked and rotated. A driven shaft 51 is installed in the switching chamber 72, the left end of the driven shaft 51 is fixedly connected to the lamp plate 15, and the right end of the driven shaft 51 is in the switching chamber 72. A switching bevel gear 57 located at is installed, and the lamp plate 15 can be interlocked to rotate, and the lighting state of the equipment is switched, and a slideable spline shaft 59 is provided in the switching chamber 72. A rotary bevel gear 58 that is installed, the spline shaft 59 and the transmission shaft 60 are connected by a spline, and a rotary bevel gear 58 that can mesh with the switching bevel gear 57 is installed at the bottom end of the spline shaft 59, and further, the switching bevel gear. A rotating block 71 that can be rotated in conjunction with the 57 and that can be rotated is installed on the outer wall of the spline shaft 59, and an electromagnetic groove 68 is installed in the top wall of the switching chamber 72. A permanent magnet 70 fixedly connected to the rotating block 71 is installed in the inside so as to be slidable, and the permanent magnet 70 is interlocked and slid up and down in the top wall of the electromagnetic groove 68. An electromagnet 67 capable of rotating the magnet 67 was installed, and an electromagnetic spring 69 was installed between the electromagnet 67 and the permanent magnet 70 so as to have elasticity.

The following details the steps of using the corridor energy-saving indicator lamp that can generate electricity using the motion of the present invention with reference to the following figures:

In the initial state, the reflectors 36 on both the left and right sides are in contact with each other, the electromagnet 67 is not energized, and the rotating bevel gear 58 is separated from the contact with the switching bevel gear 57.

When using the equipment: When a person goes up and down a staircase, the pedal 20 is stepped on, the pedal 20 slides up and down, and the rack 73, the drive gear 79, the drive shaft 78, the drive bevel gear 77, and so on. The turning shaft 75, the turning gear 74, the one-way gear 34, and the vertical shaft 35 interlock the same-direction bevel gear 33 to hold the rotation in the same direction, and the same-direction bevel gear 33 is the power generation bevel gear 32. The lateral shaft 31, the ring gear 30, the planetary gear 28, the sun gear 29, and the power generation shaft 26 interlock and rotate the mouth-shaped permanent magnet 24, and the mouth-shaped permanent magnet 24 and the coil 23 move relative to each other. The coil 23 cuts the lines of magnetic force to generate electric energy and stores it in the battery 99.

At the time of lighting, the prime mover 44 starts to operate, and the power shaft 43, the power gear 41, the transmission gear 42, and the transmission shaft 45 rotate the main pulley 40, the transmission bevel gear 39, and the worm 46 in conjunction with each other. The transmission bevel gear 39 is slid toward the side close to the slide chamber 12 by interlocking the slider 54 with the refraction bevel gear 38, the reflection shaft 65, the transmission belt 64, and the screw rod 55, and further by the conrod 53, the reflection plate 36. The left and right reflecting plates 36 are separated and the slide chamber 12 is opened. At the same time, the worm 46 includes the worm wheel 47, the extension shaft 49, the main bevel gear 48, the driven bevel gear 50, and the cam. The cam 61 is interlocked with the shaft 62 to rotate, and the cam 61 is interlocked with the lamp 17 to slide downward. At the same time, the illumination lamp 16 emits light to illuminate the corridor.

When an emergency occurs, the electromagnet 67 is energized and the permanent magnet 70 and the rotating block 71 interlock the spline shaft 59 and slide it downward, and the rotating bevel gear 58 and the switching bevel gear 57 mesh with each other. The transmission belt 66, the driven pulley 63, the transmission shaft 60, the spline shaft 59, the rotating bevel gear 58, the switching bevel gear 57, and the driven shaft 51 are used to rotate the lamp plate 15 in conjunction with each other, and further to the illumination lamp 16. When the position with the first aid light 14 is switched and the lamp plate 15 rotates 180 degrees, the power of the electromagnet 67 is turned off, the rotating bevel gear 58 is separated from the contact with the switching bevel gear 57, the first aid light 14 emits light, and the corridor. Illuminate.

The beneficial effects of the present invention are: The present invention is simple to configure, easy to operate, convenient to maintain, and the equipment generates power by utilizing the action of stepping on the stairs when a person goes up and down the stairs. There is no need to lay a circuit in the corridor, there is no need to consume energy in the corridor, the equipment can switch between normal and emergency lighting modes in some cases, and the cost of installing emergency lights in the corridor It can be lowered and the lighting effect in the corridor can be improved, so that the equipment has high utility value and widespread value.

The above is merely a specific embodiment of the present invention, but the scope of protection of the present invention is not limited to this. Changes and replacements that come to mind through all creative labor are covered by the scope of the invention. Therefore, the scope of protection of the present invention is based on the scope of protection in which the request for rights is limited.

Claims (7)

In front view, it includes a base that can be fixed to the stairs and a lamp base that can be fixed to the wall, a slide groove is installed in the base, and up and down in the slide groove. A slideable pedal is installed, a pressing spring is installed between the pedal and the slide groove so as to have elasticity, and power generation power communicated with the slide groove is contained in the inner walls on both the left and right sides of the slide groove. The chambers are installed symmetrically, the turning chambers are symmetrically installed in the inner walls on both the upper and lower sides of the power generation power chamber, and the power generation chambers are installed in the rear wall of the turning chambers at the top to generate the power. A power generation mechanism is installed in the chamber, a turning device capable of holding the rotation direction of the power generation mechanism is installed in the power generation power chamber, and power is generated by a person moving up and down a staircase to generate electricity. A slide chamber is installed in the base, a slideable lamp is installed in the slide chamber, a rotatable lamp plate is installed in the lamp, and the bottom end of the lamp plate can be normally illuminated. An illuminating light is installed, an emergency light capable of emergency lighting is installed at the top end of the lamp plate, symmetrical refraction chambers are installed in the inner walls on both left and right sides of the slide chamber, and inside the refraction chamber. A refracting device is installed, and the illumination range can be further expanded. A switching chamber is installed in the wall of the refracting chamber on the right side close to the slide chamber, and the switching chamber is inside the switching chamber. A switching device capable of switching the lighting state of the equipment is installed, and a storage device capable of controlling the operating state of the equipment and accommodating the lamp is installed in the slide chamber, and the top wall of the slide chamber is installed. A power chamber is installed inside, a drive device is installed in the power chamber, lighting can be provided in the corridor, and floor lamps are installed on the outer wall of the base and the pedal. A corridor energy-saving indicator light that can generate electricity using exercise. The turning device includes a drive shaft installed in the power generation chamber, racks are symmetrically installed on the left and right end walls of the pedal, and the rear ends of the drive shaft mesh with the rack. A drive gear is installed, a drive bevel gear is installed at the front end of the drive shaft, a vertically symmetrical turning shaft is installed in the power generation power chamber, and the turning shaft is close to the power generation power chamber. A turning bevel gear that meshes with the driving bevel gear is installed at one end thereof, and the turning shaft can be further interlocked to rotate, and the turning chamber is located at one end of the turning shaft that is separated from the power generation power chamber. A turning gear located in is installed, a vertical axis is installed in the turning chamber, and the turning gear is located in the turning chamber on the outer wall of the vertical axis. A unidirectional gear that meshes with is installed, and a unidirectional bevel gear that can be rotated in conjunction with the power generation mechanism is installed at the top end of the vertical axis, and the direction in which the unidirectional gear at both upper and lower ends can be rotated is A corridor energy-saving indicator light capable of generating power by utilizing the movement according to claim 1, characterized in that it is reversed. The power generation mechanism includes a sideways shaft installed in the turning chamber, and a power generation bevel gear that meshes with the same direction bevel gear is installed at the front end of the sideways shaft, and the sideways shaft is linked and rotated. A ring gear is installed at the rear end of the lateral shaft, a power generation shaft is installed in the turning chamber, a sun gear is installed at the front end of the power generation shaft, and the sun gear and the ring gear are connected to each other. A planetary gear is installed between them so that it can be transmitted, and the power generation shaft can be interlocked to rotate at high speed. At the rear end of the power generation shaft, a mouth-shaped permanent magnet located in the power generation chamber The movement according to claim 1, wherein a coil is installed in the power generation chamber, and a battery capable of storing electric energy is installed in the bottom wall of the power generation chamber. A corridor energy-saving indicator light that can generate electricity. The drive device includes a prime mover installed in the power chamber, and a power shaft connected to the prime mover so as to be able to transmit power is installed in the power chamber, and power is installed at the top end of the power shaft. A gear is installed, a transmission shaft is installed in the power chamber, and a transmission gear located in the power chamber and meshing with the power gear is installed on the outer wall of the transmission shaft. Further, a transmission bevel gear that can be rotated by interlocking the transmission shaft and can be rotated by interlocking the refracting device is installed at the top end of the transmission shaft, and the switching device is mounted on the outer wall of the transmission shaft. A main pulley that can be interlocked and rotated is installed, and a worm that is located in the slide chamber and can be interlocked and rotated is installed on the outer wall of the transmission shaft. A corridor energy-saving indicator light capable of generating power by utilizing the exercise according to claim 1. The storage device includes a stretch shaft symmetrically installed in the slide chamber, and a worm wheel meshing with the worm is installed at the rear end of the stretch shaft, and the stretch shaft is further interlocked with the stretch shaft. It can be rotated, a drive bevel gear is installed at the front end of the extension shaft, a cam shaft is installed symmetrically in the slide chamber, and one end of the cam shaft that is close to the transmission shaft. A driven bevel gear that meshes with the driving bevel gear is installed in the camshaft, and a cam that can come into contact with the lamp and cooperate with the lamp is installed at one end of the camshaft that is distant from the transmission shaft. The bevel gear can be slid downward by interlocking the lamp with the cam shaft and the cam, and a return spring is installed between the lamp and the top wall of the slide chamber so as to have elasticity. A corridor energy-saving indicator light capable of generating power by utilizing the movement according to claim 1. The refracting device includes a reflector installed so as to be rotatable on the driven bevel gear, the reflectors on both the left and right sides can cooperate to close the slide chamber, and a screw rod is installed in the refracting chamber. A slidable slider is installed on the outer wall of the screw rod, the slider and the screw rod are connected by a screw thread, the slider and the reflector are connected by a hinge through a conrod, and the reflector is further connected. It can be rotated in conjunction with each other, and a symmetrical reflection shaft is installed in the power chamber, and one end of the reflection shaft close to the power chamber is located in the power chamber. The motion according to claim 1, wherein a refraction bevel gear that is in mesh with the transmission bevel gear is installed, and power is transmitted between the reflection shaft and the screw rod by a transmission belt. Corridor energy saving indicator light that can be done. The switching device includes a transmission shaft installed in the power chamber, and a driven pulley located in the power chamber is installed at the top end of the transmission shaft, and the driven pulley and the main pulley A transmission belt is installed between them so that it can be transmitted, and the transmission shaft can be interlocked and rotated. A driven shaft is installed in the switching chamber, and the left end of the driven shaft is the lamp plate. A switching bevel gear that is fixedly connected and is located at the right end of the driven shaft is installed in the switching chamber, and the lamp plate can be further interlocked and rotated to further control the lighting state of the equipment. Switching, a slideable spline shaft is installed in the switching chamber, the spline shaft and the transmission shaft are connected by a spline, and a rotation capable of meshing with the switching bevel gear at the bottom end of the spline shaft. A bevel gear is installed, and the switching bevel gear can be interlocked to rotate, a rotating block is installed on the outer wall of the spline shaft, and an electromagnetic groove is installed in the top wall of the switching chamber. A permanent magnet fixedly connected to the rotating block is installed in the electromagnetic groove so that it can slide, and the permanent magnet can be interlocked and slid up and down in the top wall of the electromagnetic groove. A corridor energy-saving indicator lamp capable of generating power by utilizing the motion according to claim 1, wherein an electromagnet capable of being generated is installed, and an electromagnetic spring is installed between the electromagnet and the permanent magnet so as to have elasticity. ..

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