KR101074635B1 - Hybrid lighting device - Google Patents

Abstract

The present invention relates to a hybrid lighting device, the lighting unit provided in the body fixed to the structure, including the ceiling, wall or pillar of the building can emit light through renewable energy, including wind, solar light, etc. Therefore, it is not necessary to supply a separate energy source to the lighting unit, and thus, there is an effect of building an energy-saving eco-friendly lighting system on the structure.

Description

Hybrid lighting device {HYBRID ILLUMINATION APPARATUS}

The present invention is a lighting unit provided in the body fixed to the structure, including the ceiling, wall or strut of the building can emit light through renewable energy, including wind, solar, etc. The present invention relates to a hybrid lighting device capable of providing an energy-saving, environmentally friendly lighting system in a structure, as well as not having to supply.

The green growth policy, which seeks to solve economic growth and environmental preservation at the same time, is being adopted as a major economic revival policy in various countries in conjunction with the global financial crisis of Sasang Colostrum.

Korea is also pursuing policies under the plan to achieve economic revival, create adaptation to climate change and create new growth engines through intensive investment in environment and renewable energy through low carbon green growth.

The Low Carbon Green Growth Declaration is increasing the importance of climate change and eco-friendliness.

Accordingly, the government is demanding that the government actively participate in government policies to respond to climate change and reduce greenhouse gas emissions.

Among them, in the lighting industry, sustainable technology development such as high efficiency LED lighting equipment is becoming important.

As a means to meet these demands, it is true that the government has recently made a policy tendency, such as high-efficiency LED lighting equipment distribution projects carried out by the government and public institutions.

In addition, as people's interest in environmental quality and the generalization of environmental awareness of big cities and buildings increases, many investments and developments in lighting, high efficiency, eco-friendly, economical and emotional LED lighting are being made, and the efforts are further materialized. have.

In other words, they are gradually deviating from development methods that are indiscriminate and inconsistent with the natural environment, and introduced eco-friendly concepts in a way that harmonizes and balances the environment and human activities. I'm investing.

The inventors have a separate energy source as the lighting unit because the lighting unit provided in the body fixed to the structure including the ceiling, wall or pillar of the building can emit light through renewable energy including wind, solar light, and the like. As a result, there is no need to supply a hybrid lighting device that can build an energy-saving eco-friendly lighting system.

The present invention is a lighting unit provided in the body fixed to the structure, including the ceiling, wall or strut of the building can emit light through renewable energy, including wind, solar, etc. The purpose of this is to provide a hybrid lighting device that can not only supply, but also to build an energy-saving eco-friendly lighting system for the structure.

The present invention for achieving the above object is fixed to the structure, the power generation unit for generating electrical energy therein, and the body is provided with a storage battery is the electrical energy generated by the power generation unit; A fixed shaft fixed to the lower portion of the body; An illumination unit provided below the fixed shaft; A rotating blade unit comprising a rotating sleeve rotatably coupled to the fixed shaft and a blade provided at a predetermined interval on the rotating sleeve; It provides a hybrid-type lighting device comprising a; rotational force transmission unit for transmitting the rotational force of the rotating sleeve of the rotating blade portion to the power generation unit.

Here, it is preferable that the solar cell unit is provided on the blade of the rotating blade unit.

In addition, the rotational force transmitting unit is preferably made of one or more gears.

In particular, the rotational force transmission unit and a drive gear provided on the upper end of the rotating sleeve; And a driven gear axially coupled to the lower end of the shaft of the power generation unit and receiving a rotational force of the rotary sleeve through the drive gear to rotate the shaft of the power generation unit.

Further, the power generation unit provided in the body is preferably disposed on the central axis of the body.

In addition, a fixing plate is provided inside the body, and an upper portion of the fixing shaft is fixed to a bottom of the fixing plate, a shaft hole is formed at one side of the fixing plate, and a connecting shaft is axially coupled in the shaft hole, and an upper end of the connecting shaft. It is preferable that the lower end has a connecting gear engaged with the driven gear and the drive gear provided in the upper end of the rotary sleeve and the shaft coupled to the lower end of the shaft of the power generation unit.

In addition, it is preferable that the fixing bracket for fixing the body to the structure on the upper portion of the body.

In addition, the vibration absorbing unit is preferably provided between the fixing bracket and the body.

In particular, the vibration absorbing portion and the rubber plate provided between the fixing bracket and the body; A shaft member vertically formed at both sides of a bottom surface of the fixing bracket, and vertically passing through both sides of the rubber plate and both sides of the upper portion of the body; A nut member screwed to a lower end of the shaft member, respectively; It is preferable to include an elastic member provided between the upper both sides of the body and the nut member in the state wrapped around the shaft member.

Furthermore, it is preferable that the lighting unit is detachably provided under the fixed shaft.

In addition, the fixed shaft is preferably formed in a tubular shape.

According to the present invention, the ceiling of a building can emit light by receiving the electrical energy stored in the battery while the electrical energy generated by the power generation unit is received by the rotational force of the rotating blade rotating by the wind. , The lighting unit provided on the body fixed to the structure including the wall or the pillar, etc. do not need to supply a separate energy source to the light to emit light as well as to build an energy-saving eco-friendly lighting system for the structure It can work.

1 is a front view schematically showing a hybrid type lighting device of one embodiment of the present invention,
2 is a cross-sectional view schematically showing a rotational force transmitting unit made of a spur gear,
3 is a cross-sectional view schematically showing a rotational force transmitting portion made of a bevel gear,
Figure 4 is a front view schematically showing a state that the fixing bracket is provided on the upper portion of the body,
5 to 7 is a front view schematically showing a state in which the body is fixed to the structure,
8 is a partially enlarged cross-sectional view schematically showing a state in which the vibration absorbing unit is provided between the fixing bracket and the body;
9 is a partially enlarged cross-sectional view schematically showing an operating state of the vibration absorbing unit;
10 is an exploded front view schematically showing a state in which the lighting unit is separated from the fixed shaft,
11 is a partially enlarged cross-sectional view schematically illustrating a state in which a line is accommodated in a fixed shaft.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a front view schematically showing a hybrid lighting apparatus according to an embodiment of the present invention.

Hybrid type lighting device according to an embodiment of the present invention as shown in Figure 1, large, including a body 10, a fixed shaft 20, the lighting unit 30, the rotating blade unit 40 and the rotational force transmission unit 50 It is done by

2 is a cross-sectional view schematically showing the rotational force transmitting unit 50 made of a spur gear.

First, the body 10 is fixed to a structure (5 of FIGS. 5 to 7) including a ceiling, a wall or a pillar of a building such as a house.

As shown in FIG. 2, the power generation unit 110 generating electrical energy is provided inside the body 10.

The upper both sides of the power generation unit 110 may be bolted to the upper inner circumferential surface one side and the upper inner circumferential surface other side of the body 10, respectively.

In addition, the body 10 is provided with a storage battery 120 in which the electrical energy generated by the power generation unit 110 is stored.

Next, the fixed shaft 20 is fixed to the upper portion of the lower portion of the body (10).

Next, the lighting unit 30 is provided below the fixed shaft 20.

The lighting unit 30 may emit light by receiving electrical energy stored in the storage battery 120.

The lighting unit 30 may be made of a Hanji luminaire, etc. The Korean paper luminaire is a well-known technology and will be clearly understood by those skilled in the art to which the present invention pertains. .

Next, the rotating blade unit 40 is composed of a rotating sleeve 410 and the blade 420.

The upper and lower portions of the rotary sleeve 410 are bearing-coupled to the fixed shaft 20 so as to be capable of forward and reverse rotation while the fixed shaft 20 is accommodated inside the rotary sleeve 410.

The blade 420 is vertically provided at a predetermined interval to the rotary sleeve 410.

Connection bar 430 for connecting the blade 420 and the rotary sleeve 410 may be provided.

The connection bar 430 may include an upper connection bar 431 and a lower connection bar 432.

Both ends of the upper connection bar 431 and both ends of the lower connection bar 432 may be integrally connected to the inner circumferential surface of the blade 420 and the outer circumferential surface of the rotary sleeve 410, respectively, in a welded state.

Next, the rotational force transmission unit 50 transmits the forward and reverse rotational power of the rotary sleeve 410 forward and reverse rotation along the blade 420 forward and backward rotation by the wind to the power generation unit (110).

The power generation unit 110 receives the reverse rotational power of the rotary sleeve 410 through the rotational force transmission unit 50 to generate electrical energy.

Next, as shown in FIGS. 1 and 2, the solar cell unit 60 may be provided at a predetermined interval in the vertical direction on the outer circumferential surface of the blade 420 of the rotating blade unit 40.

The solar cell unit 60 may be formed of a solar cell that collects solar heat and converts it into electrical energy, or in particular, a solar cell that collects and converts sunlight into electrical energy.

Electrical energy generated by the solar cell unit 60 may be stored in the storage battery 120.

The power generation unit 110 is required for the lighting unit 30 to emit light because the rotation force transmission unit 50 does not transmit the reverse rotational power of the rotation sleeve 410 of the rotary blade unit 40 because the wind is not blown. Even if the electrical energy is not generated, the lighting unit 30 may emit light through the electrical energy generated by the solar cell unit 60.

3 is a cross-sectional view schematically showing the rotational force transmitting unit 50 made of a bevel gear.

Next, as shown in FIGS. 2 and 3, the rotational force transmitting unit 50 may be formed of one or more gears 500.

The forward and reverse rotational power of the rotary sleeve 410 of the rotary blade unit 40 is rotated forward and backward by wind to the power generation unit 110 through the rotational force transmission unit 50 consisting of one or more of the gears 500. There is an advantage that can be easily delivered.

Next, the torque transmission unit 50 which may be made of one or more gears 500 may include a drive gear 510 and a driven gear 520 in FIGS. 2 and 3.

The drive gear 510 may be horizontally provided at the upper end of the rotary sleeve 410 while being axially coupled to the upper end of the rotary sleeve 410.

The driven gear 520 may be horizontally provided at the lower end of the shaft 111 of the power generator 110 in a state in which the driven gear 520 is axially coupled to the lower end of the shaft 111 of the power generator 110.

The driven gear 520 receives the reverse rotational power of the rotary sleeve 410 through the drive gear 510 so that the power generator 110 generates electrical energy. 111) can be reversed.

The drive gear 510 and the driven gear 520 may be made of a spur gear as shown in FIG. 2 or bevel gears as shown in FIG. 3.

Next, as shown in FIGS. 2 and 3, the power generation unit 110 provided in the body 10 may be vertically disposed on an internal central axis of the body 10.

When the power generation unit 110 is vertically disposed on the inner central axis of the body 10, the power generation unit 110 may easily generate vibration in the body 10 during the process of generating electrical energy. There is an advantage that can be prevented.

Next, as shown in FIGS. 2 and 3, the fixing plate 130 may be integrally horizontally provided on the inner lower side of the body 10.

The other side of the upper surface of the fixing plate 130 may be equipped with the storage battery 120 is fixed in a bolted state.

An upper portion of the fixed shaft 20 vertically penetrating the bottom central portion of the body 10 may be fixedly welded to a central portion of the bottom surface of the fixing plate 130.

One side of the fixing plate 130 may be formed with a shaft hole 131, the upper and lower sides are open.

In the shaft hole 131, the connecting shaft 70 may be vertically coupled to the shaft.

The lower portion of the connecting shaft 70 may be exposed to a predetermined length in the outer direction of the bottom surface of the body 10 by vertically penetrating one side of the bottom surface of the body 10.

Connection gears 710 may be horizontally provided at upper and lower ends of the connecting shaft 70, respectively.

The connecting gear 710 may be composed of an upper connecting gear 711 and a lower connecting gear 712.

The upper connection gear 711 may be engaged with the driven gear 520 that is axially coupled to the upper end of the connecting shaft 70 and axially coupled to the lower end of the shaft 111 of the power generation unit 110.

The lower connection gear 712 is axially coupled to the lower end of the connecting shaft 70 may be engaged with the drive gear 510 provided at the upper end of the rotary sleeve 710.

The connection gear 710 may be made of a spur gear as shown in FIG. 2 or a bevel gear as shown in FIG. 3.

The drive gear 510 has an advantage that it is possible to more easily transfer the reverse rotational power of the rotary sleeve 410 to the power generation unit 110 through the connection gear 710.

4 is a front view schematically showing a state in which the fixing bracket 80 is provided on the upper portion of the body 10.

Next, as shown in Figure 4, the upper portion of the body 10 may be provided with a plate-shaped fixing bracket 80 for fixing the body 10 to the structure (5).

The upper one side and the upper other side of the body 10 may be bolted to the bottom side and the other side of the bottom of the fixing bracket 80 of the plate, respectively.

5 to 7 are front views schematically showing a state in which the body 10 is fixed to the structure 5.

As shown in FIG. 5, one side and the other side of the fixing bracket 80 are bolted to the ceiling of a building such as a house so that the body 10 may be fixed to the structure 5 including the ceiling of a building such as a house. Can be fixed.

Alternatively, as shown in FIG. 6, the body 10 may be fixed to a structure 5 including a wall surface of a building such as a house, and one side and the other side of the fixing bracket 80 may have a separate connection body 100. One side of the bottom and the other side of the bottom of the bolt can be fixed.

The connection body 100 may be formed in various shapes, such as a cross-sectional shape of a right triangle.

The upper and lower portions of the separate connection body 100 may be bolted to the wall surface of the building, such as a house, respectively.

Alternatively, one side and the other side of the fixing bracket 80 as shown in Figure 7 so that the body 10 can be fixed to the structure (5) including the post and one side of the bottom of the separate connection body 100 and The bottom may be bolted to the other side respectively.

The upper and lower portions of the separate connection body 100 may be bolted to the upper one side of the holding respectively.

8 is a partially enlarged cross-sectional view schematically illustrating a state in which the vibration absorbing unit 90 is provided between the fixing bracket 80 and the body 10.

Meanwhile, vibration may occur in the rotary blade unit 40 during the reverse rotation of the rotary sleeve 410 and the blade 420 of the rotary blade unit 40 by wind.

Due to the vibration generated in the rotating blade unit 40, there is a high possibility that cracks or the like may occur in the structure 5 to which the body 10 is fixed.

As shown in FIG. 8, in order to prevent cracks and the like from occurring in the structure 5 to which the body 10 is fixed due to the vibration generated in the rotating blade part 40, the bottom surface of the fixing bracket 80 and the Vibration absorbing unit 90 may be provided between the upper surface of the body (10).

In particular, the vibration absorbing unit 90 may include an elastic member 940 including a rubber plate 910, a shaft member 920, a nut member 930, and a spring, as shown in FIG. 8.

The rubber plate 910 may be horizontally provided between the bottom surface of the fixing bracket 80 and the top surface of the body 10.

The shaft member 920 may be vertically formed in one body on one side of the bottom and the other bottom of the fixing bracket 80, respectively.

The shaft member 920 is a through hole (911 of FIG. 9) formed on one side and the other side of the rubber plate 910 and a through hole formed in the upper one side and the upper other side of the body 10, respectively (11 of FIG. 9) Each can be vertically penetrated.

The outer diameter of the shaft member 920 may be formed to be smaller than the inner diameter of the through hole 11 formed on one upper side and the other upper side of the body 10, respectively.

The nut member 930 may be screwed to the lower end of the shaft member 920, respectively.

The elastic member 940 may be vertically provided in an expanded state between the upper both sides of the body 10 and the nut member 930 with the shaft member 920 wrapped.

9 is a partially enlarged cross-sectional view schematically showing an operating state of the vibration absorbing unit 90.

Both sides of the upper portion of the body 10 may be fixed to the bottom side and the other side of the rubber plate 910 by the expansion force of the elastic member 940, respectively.

As shown in FIG. 9, the rotating sleeve 410 and the blade 420 of the rotating blade unit 40 are rotated by the wind due to the vibration generated in the rotating blade unit 40. When the upper both sides of the flow in the vertical direction, the elastic member 940 is able to contract and expand in the vertical direction.

The elastic force of the rubber plate 910 and the contraction and expansion force of the elastic member 940 can more easily alleviate the vibration generated in the rotary blade unit 40, and as a result, cracks in the structure 5 are caused. There is an advantage that can be more easily prevented from occurring.

10 is an exploded front view schematically illustrating a state in which the lighting unit 30 is separated from the fixed shaft 20.

Next, as shown in FIG. 10, the lighting unit 30 may be integrally provided at the lower portion of the fixed shaft 20, but preferably, the lighting unit 30 is disposed below the fixed shaft 20. It is good to be detachably provided.

To this end, a fastening part 200 for detachably fastening the lighting unit 30 to the lower portion of the fixed shaft 20 may be provided.

The fastening part 200 may include an upper flange 210, a lower flange 220, and a fastening member 230.

The upper flange 210 may be integrally horizontally provided at the lower end of the fixed shaft 20.

The lower flange 220 may be integrally horizontally provided at the upper end of the support shaft 31 vertically formed at the upper center of the lighting unit 30.

The fastening member 230 may be composed of a bolt 231 and a nut 232.

The bolt 231 may vertically penetrate the lower flange 220 and the upper flange 210 at a predetermined interval.

The nut 232 may be screwed to the upper end of the bolt 231.

When the lighting unit 30 is damaged, the operator can release the fastening state of the fastening unit 200 to easily replace and repair the damaged lighting unit 30 under the fixed shaft 20. Will be.

11 is a partially enlarged cross-sectional view schematically showing a state in which the line 7 is accommodated in the fixed shaft 20.

Next, as shown in FIG. 11, the fixed shaft 20 may be formed in a tubular shape.

A guide hole 132 communicating with the fixed shaft 20 may be formed at the center of the fixed plate 130.

A line 7 including wires for electrically connecting the lighting unit 30 and the storage battery 120 to each other may be provided.

The other end of the line 7 may be connected to one side of the storage battery 120.

One end of the line 7 may be introduced into the fixed shaft 20 through the guide hole 132.

The support shaft 31 of the lighting unit 30 may also be formed in a tubular shape so that one end of the line 7 may be more easily connected to the lighting unit 30.

One end of the line 7 including an electric wire or the like may be connected to the lighting unit 30 in a state in which the fixed shaft 20 is introduced into the interior of the fixed shaft 20 and the support shaft 31.

Since the line 7 including an electric wire or the like is introduced into the tubular fixed shaft 20 and the tubular support shaft 31 and is not exposed to the outside, the rotary blade unit 40 and the lighting unit 30 are not exposed to the outside. There is an advantage that the appearance of can be more beautiful.

According to the present invention configured as described above, the lighting unit may receive electric power generated by the power generation unit 110 by receiving the rotational force of the rotating blade unit 40 rotated by wind. The lighting unit provided in the body 10 fixed to the structure 5 including the ceiling, the wall, or the pillar of the building because 30 may receive light from the electrical energy stored in the storage battery 120. In order to emit light, the light source 30 does not need to supply a separate energy source to the lighting unit 30, and thus, an energy-saving environment-friendly lighting system can be built in the structure 5.

10; Body 20; Fixed shaft,
30; Lighting unit 40; Rotating Blade,
50; Torque transmission unit.

Claims (11)

A body 10 fixed to the structure 5 and having a power generation unit 110 for generating electrical energy therein, and a storage battery 120 for storing electrical energy generated by the power generation unit 110;
A fixed shaft 20 fixed to the lower portion of the body 10;
An illumination unit 30 provided below the fixed shaft 20;
A rotating blade unit 40 consisting of a rotating sleeve 410 rotatably coupled to the fixed shaft 20 and a blade 420 provided at a predetermined interval on the rotating sleeve 410;
And a rotational force transmission unit 50 for transmitting the rotational force of the rotary sleeve 410 of the rotary blade unit 40 to the power generation unit 110.
Hybrid type lighting device, characterized in that the fixing bracket (80) for fixing the body (10) to the structure (5) is provided on the top of the body (10).
The method of claim 1,
Hybrid type lighting device, characterized in that the solar cell unit 60 is provided on the blade 420 of the rotating blade unit (40).
The method of claim 1,
The rotational force transmission unit 50 is a hybrid type lighting device, characterized in that consisting of one or more gears (500).
The method of claim 3,
The rotational force transmitting unit 50 includes a drive gear 510 provided at the upper end of the rotating sleeve 410;
It is coupled to the lower end of the shaft 111 of the power generation unit 110, and receives the rotational force of the rotary sleeve 410 through the drive gear 510 to rotate the shaft 111 of the power generation unit 110. Hybrid gear 520 to make; comprising a.
The method of claim 1,
The power generation unit 110 provided in the body 10 is a hybrid type lighting device, characterized in that disposed on the central axis of the body (10).
The method of claim 4, wherein
The fixing plate 130 is provided inside the body 10,
The upper portion of the fixed shaft 20 is fixed to the bottom surface of the fixing plate 130, the shaft hole 131 is formed on one side of the fixing plate 130,
A connecting shaft 70 is axially coupled in the shaft hole 131,
The driving gear 520 provided at the upper end of the rotary gear 410 and the driven gear 520 coupled to the lower end of the shaft 111 of the power generation unit 110 at the upper end and the lower end of the connecting shaft 70 ( Hybrid gear is characterized in that the connection gear 710 is meshed with 510 is provided.
The method of claim 1,
Hybrid type lighting device, characterized in that the vibration absorbing portion 90 is provided between the fixing bracket 80 and the body (10).
The method of claim 7, wherein
The vibration absorbing unit 90 is a rubber plate 910 provided between the fixing bracket 80 and the body 10;
Shaft members 920 vertically formed at both sides of the bottom surface of the fixing bracket 80 and vertically penetrating both sides of the rubber plate 910 and upper both sides of the body 10;
A nut member 930 screwed to a lower end of the shaft member 920, respectively;
And an elastic member (940) provided between the upper both sides of the body (10) and the nut member (930) in a state of wrapping the shaft member (920).
The method of claim 1,
Hybrid lighting device, characterized in that the lighting unit 30 is detachably provided below the fixed shaft (20).
The method of claim 1,
The fixed shaft 20 is a hybrid lighting device, characterized in that formed in a tubular shape. delete

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