KR101350967B1 - Hybrid Lighting Apparatus - Google Patents

Abstract

The present invention relates to a hybrid lighting device that can conserve energy by condensing sunlight during the day and illuminating the interior using the collected light and illuminating the interior using electricity at night. The present invention condensing means for condensing the incident sunlight; A guide tube 20 for guiding the movement of the light collected by the light collecting means; Distribution means (30) for distributing the light guided by the guide tube (20); Irradiating means (40) for irradiating light distributed from the distributing means (30); An optical sensor 50 for sensing an amount of light collected by the light collecting means and transmitting an operation signal according to the amount of light being sensed; And a lamp 60 that emits light using electricity input by being operated by an operation signal transmitted from the optical sensor 50. The present invention can be used to illuminate the room using sunlight in the daytime, to illuminate the room using a lamp at night, and to absorb heat from the concentrated sunlight can be used for hot water or heating.

Description

Hybrid Lighting Apparatus

The present invention relates to a hybrid lighting device that can conserve energy by condensing sunlight during the day and illuminating the interior using the collected light and illuminating the interior using electricity at night.

In general, people need lights that emit electricity using electricity to operate at night. In particular, since the interior of the building is dark during the daytime, lighting is used.

Here, the building has a problem that the electrical energy is consumed for about 24 hours by using the lighting using electricity both during the day or at night.

In addition, in order to solve the above-mentioned problems, a rod-shaped transparent body is installed in a state penetrating the roof of the room, and the solar light is incident on one end and irradiated with the other end is used as illumination.

However, since the transparent body has to be installed through the roof or wall, there is a troublesome problem of installing it through the roof or wall wherever lighting is required.

In addition, there is a problem that can not use the sunlight efficiently because the lack of a structure that can use hot water or heating by using the sunlight incident to the transparent body.

The present invention has been made to solve the above problems, it is an object of the present invention to provide a hybrid lighting device that can illuminate the room by using sunlight in the daytime, and illuminate the room by using a lamp at night.

In addition, another object is to provide a hybrid lighting device that can absorb heat from the concentrated solar light and use it for hot water or heating.

The present invention for achieving the above object, the light collecting means for condensing the incident sunlight; A guide tube 20 for guiding the movement of the light collected by the light collecting means; Distribution means (30) for distributing the light guided by the guide tube (20); Irradiating means (40) for irradiating light distributed from the distributing means (30); An optical sensor 50 for sensing an amount of light collected by the light collecting means and transmitting an operation signal according to the amount of light being sensed; And a lamp 60 that emits light using electricity input by being operated by an operation signal transmitted from the optical sensor 50.

The condensing means may include: a condensing enclosure 11 installed at an upper end of the guide tube 20 and having a condensing space provided at one side thereof; And a reflector 13 provided in the condensing space of the condensing enclosure 11 to reflect the light incident through the opening of the condensing enclosure 11 to the guide tube 20.

And an additional reflector 15 reflecting the light flowing through the opening of the light condenser 11 to the reflector 13.

The guide tube 20 is characterized in that the reflective layer is provided on the inner surface to reflect the light.

The distribution means 30 is characterized by concentrating the light guided by the guide tube 20 to one side and dispersing the concentrated light to the other side.

The irradiating means 40 is an optical fiber that irradiates and irradiates the light distributed by the distributing means 30.

The present invention includes a circulation means for circulating while refracting the light moved in the guide tube (20); And an endothermic means 80 that absorbs heat from the light circulated by the circulation means.

The circulation means is provided in the guide tube 20 to pass the light guided in a straight line along the longitudinal direction of the guide tube 20 and to reflect the guided light while being reflected on the inner surface of the guide tube 20 Reflective member 71; And a circulation member 73 which reflects back to the reflection member 71 while circulating the light reflected by the reflection member 71.

The circulation member 73 may include a downward reflection portion 73a installed in the guide tube 20 in a state located above the reflection member 71 and reflecting light reflected from the reflection member 71 downward; And an upward reflection unit 73b that upwardly reflects the light reflected by the downward reflection unit 73a.

The heat absorbing means 80 is characterized in that the heat absorbing tube of the coil type circulates the fluid absorbing heat of the circulation means while wrapping the outer peripheral surface of the circulation means in close contact with the circulation means.

The present invention can illuminate the room by using sunlight in the daytime, and illuminate the room by using a lamp at night.

In addition, heat can be absorbed from the collected solar light and used for hot water or heating.

1 is a cross-sectional view showing the internal configuration of the present invention.
Fig. 2 is a perspective view of Fig. 1; Fig.
Figure 3 is a block diagram showing a use state to which the present invention is applied.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

The present invention provides a light collecting means as shown in Figure 1 and 2; Guide tube 20; Distribution means (30); Irradiation means 40; Optical sensor 50; And a lamp 60;

The condensing means is for condensing the incident sunlight, for example, a condenser housing 11; And a reflector plate 13.

The light collecting enclosure 11 is installed at the upper end of the guide tube 20 and one side is opened while the light collecting space is provided.

In addition, the light collecting enclosure 11 may be rotated by the rotating means to rotate along the sun. Here, the rotation means is a driving member for rotating the first gear (RT1) and the second gear (RT2) and the second gear (RT2) mated with the first gear (RT1) integrally fixed to the light collecting enclosure (11). RT3 and the driving member RT3 may be configured as the solar sensor RT4 shown in FIG. 3 that senses and transmits a rotation signal while tracking the direction of sunlight. At this time, the drive member (RT3) is preferably composed of a step motor. The solar sensor RT4 is preferably fixed to the light collecting enclosure 11 described above.

Accordingly, the light collecting enclosure 11 may be rotated about the guide tube 20 by the rotating means, so that the opening side may face the sun, and thus, the light may be collected as much as possible.

In this case, the opening of the light condensing enclosure 11 may extend beyond the path through which the light is guided to increase the light condensing amount.

For example, the opening may be extended in the form of a horn or a trapezoid.

The reflection plate 13 is provided in the light condensing space of the light condenser 11 to reflect the light incident through the opening of the light condenser 11 to the guide tube 20. Here, it is preferable that a plurality of reflecting plates 13 are provided in the condensing spaces at different angles so as to reflect the light incident on the inner side of the condenser 11 to the guide tube 20. In addition, the reflective plate 13 may be configured as a mirror, a reflective coating for reflecting light onto the plate (coating), or a reflective film may be attached. In addition, the reflective plate 13 may be formed in a concave shape.

The light collecting means further includes an additional reflector plate 15. The additional reflector 15 is for reflecting the light flowing through the aperture of the light condenser 11 to the reflector 13, and is preferably provided at one side of the aperture of the light concentrator 11. In addition, the additional reflector 15 may be made of the same material as the reflector 13.

The guide tube 20 is for guiding the movement of the light collected by the light collecting means, and the reflective layer 21 is provided (coated) as shown in FIG. 1 which reflects the light on the inner surface of the tube. desirable. At this time, the lower portion of the reflective layer 21 may be further formed on the inner surface of the UV layer 23 to block ultraviolet rays and the heat resistant layer 25 to protect the inner wall by blocking the heat of sunlight. Alternatively, the guide tube 20 may be configured such that the mirror is formed in a tubular shape.

Distributing means 30 is for distributing the light guided by the guide tube 20, the light that is inclined surface 31 of the upper and lower strait is formed and concentrated so as to focus the light guided by the guide tube 20 to one side It has a reverse inclined surface 33 of upper and lower light opposite to the inclined surface 31 so as to disperse and distribute to the other side. Here, the inclined surface 31 and the reverse inclined surface 33 may be formed of the same material as the above-described reflective plate 13 while being installed inside. Alternatively, the distribution means 30 may be made of glass on which the inclined surface 31 and the reverse inclined surface 33 are formed.

In addition, the distribution means 30 may be configured to further include an optical fiber 32 for providing the light distribution means 40 to the irradiation means 40 is connected to the irradiation means 40 to be described later. Here, since the optical fiber 32 is composed of a plurality of one end is connected to each of the distribution means 30, it is possible to provide each of the light distributed by the distribution means 30 to the plurality of irradiation means 40 connected to each other end. . Therefore, the plurality of irradiation means 40 may illuminate several places in the room by using the light distributed from one distribution means 30.

The irradiating means 40 is for irradiating the light distributed by the distributing means 30, and may be composed of an optical fiber irradiated by scattering or scattering the light distributed by the distributing means 30.

The optical sensor 50 senses the amount of light collected by the light collecting means and transmits an operation signal according to the amount of light sensed. That is, the optical sensor 50 is set to transmit the operation signal when the light is not sensed. Here, the optical sensor 50 may be connected to the controller 100 to send an operation signal to the controller 100 shown in FIG. Such a light sensor 50 is preferably provided at the opening side so as to sense light incident on the opening side of the light collecting means.

On the contrary, the optical sensor 50 may be configured to switch or switch external power to the lamp 60 according to the amount of light.

The lamp 60 is operated by an operation signal transmitted from the optical sensor 50 and is enlarged in FIG. 2 so as to emit light using power supplied from the battery BT which is input from the outside or described later. 61, a plurality of LEDs 61 may be configured as a ring member 63 is fixed to the guide tube 20 while being arranged at equal intervals. Here, the lamp 60 may be turned on by the controller 100 shown in FIG. 3 to receive an operation signal transmitted from the optical sensor 50.

Therefore, the lamp 60 may be turned on at night or on a cloudy day when the light sensor 50 cannot sense light.

The present invention also provides a circulation means; And a heat absorbing means (80).

The circulation means is for circulating while refracting the light traveling in the guide tube 20, for example, a reflection member 71; And a circulation member 73.

The reflection member 71 is provided inside the guide tube 20 to allow the light guided in a straight line along the longitudinal direction of the guide tube 20 to pass and reflect the guided light while being reflected on the inner surface of the guide tube 20. . Such, the reflecting member 71 may be composed of a glass rod having a smaller diameter in the center than the diameter of both ends. At this time, the reflective member 71 is preferably filled in the form from the center to the top of the inclined surface 71a is opened from the center to the bottom outside. Accordingly, the light incident to the center of the portion filled up to the reflective member 71 passes in a straight line, and the light incident on the inclined surface 71a is reflected to the downward reflection portion 73a described later.

The circulation member 73 is for reflecting back to the reflective member 71 while circulating the light reflected by the reflective member 71, for example, a downward reflection portion 73a; And an upward reflection unit 73b.

The downward reflection portion 73a is installed in the guide tube 20 in a state located above the reflective member 71 and reflects light reflected from the outer surface of the reflective member 71 and the inclined surface 71a described above. .

The upward reflection unit 73b upwardly reflects the light reflected by the downward reflection unit 73a. Here, the downward reflection portion (73a) and the upward reflection portion (73b) is formed in a funnel form is configured to face each other.

Therefore, the light passing through the reflective member 71 is guided through the guide tube 20, and the light reflected from the inclined surface 71a of the reflective member 71 is circulated continuously in the circulation member 73.

The heat absorbing means (80) is for absorbing heat from the light circulated in the circulation means, it is a coil endothermic tube in which the fluid absorbing heat of the circulation means is circulated while covering the outer peripheral surface of the circulation means in close contact with the circulation means It is preferable.

Therefore, the heat absorbing means 80 absorbs heat from the circulation means and can be used for heating or hot water.

Here, the heat absorbing means 80 may be controlled by the controller 100 of FIG.

In addition, the controller 100 further includes a temperature sensor 82 for measuring a temperature of the heat absorbing means 80 and transmitting a temperature signal to circulate the fluid when the internal fluid temperature of the heat absorbing means 80 rises. Can be configured.

On the other hand, the present invention is a solar cell (SC) for generating power using sunlight; And a battery BT that charges electricity generated by the solar cell SC. The solar cell SC is preferably fixed to an upper portion of the light collecting box 11 that is a light collecting means, as shown in FIGS. 1 and 2.

Accordingly, the battery BT may be controlled by the controller 100 to provide the above-described lamp 60 with electricity charged by the solar cell SC.

Here, the controller 100 receives the operation signal of the optical sensor 50 described above, turns on the lamp 60, receives the rotation signal of the solar sensor RT4, drives the driving member RT3, and the solar cell. And controlling the SC to allow the electricity of the solar cell SC to be charged in the battery BT and to circulate the fluid of the heat absorbing means 80 according to the temperature signal of the temperature sensor 82. . The controller 101 may be configured as a circuit board on which electronic components are mounted, or may be configured as a program when the controller 100 is a PC.

Hereinafter, the operation and operation of the present invention.

First, as shown in FIG. 1, the light is reflected by the reflector 13 while entering the light collecting space through the opening of the light collecting enclosure 11. The light is reflected by the reflector plate 13 and irradiated to the guide tube 20. At this time, the light that escapes to the outside of the opening of the light collecting enclosure 11 is reflected by the additional reflecting plate 15 to the reflecting plate 13 and irradiated back to the guide tube 20. The light condensing enclosure 11 condenses while rotating along the sunlight by the rotating means.

Subsequently, part of the light irradiated to the guide tube 20 passes through the reflective member 71 embedded in the guide tube 20 and is provided to the distribution means 30, and the remaining part of the light is provided on the inclined surface of the reflective member 71. 71a) is circulated from the upward reflection portion 73b to the upward reflection portion 73b to the downward reflection portion 73a.

Subsequently, the light passing through the member 71 is distributed by the distribution means 30 and provided to the irradiation means 40 through the optical fiber 32 to illuminate the room while being irradiated by the irradiation means 40.

Therefore, in the present invention, when the light collecting means 10 is installed outdoors and the irradiating means 40 is installed indoors, it is possible to illuminate the interior using sunlight in the daytime. In addition, when the light of the street lamp is received even at night, it may be used to illuminate the interior.

In addition, when the light is not received at night, the present invention provides the lamp 60 with the charging power charged in the battery BT by the operation signal of the optical sensor 50 to emit the lamp 60.

As such, the present invention can not only illuminate the room for 24 hours by using sunlight in the daytime and use the charging electricity at night, but also use the sunlight to save electrical energy.

Since the above-described embodiments are merely illustrative of the preferred embodiments of the present invention, the scope of application of the present invention is not limited to the above, and appropriate modifications are possible within the scope of the same idea. Therefore, since the shape and structure of each component shown in the embodiment of the present invention can be carried out by deformation, it is natural that the modification of the shape and structure belong to the appended claims of the present invention.

20: guide
30: distribution means
40: investigation means
50: light sensor
60 lamp

Claims (5)

Installed at the upper end of the guide tube 20 and provided with a light condensing space, one side is provided in the light condensing compartment 11 and the light condensing space of the light condensing compartment 11, and is incident through an opening of the light condensing compartment 11. Condensing means comprising a reflecting plate 13 for reflecting light to the guide tube 20 to collect the incident sunlight;
A guide tube (20) provided with a reflection layer for reflecting light on an inner surface to guide the movement of the light collected by the light collecting means;
Distribution means (30) for concentrating the light guided by the guide tube (20) to one side and distributing the concentrated light to the other side;
Irradiating means (40) made of an optical fiber for irradiating and irradiating light distributed in the distributing means (30);
An optical sensor 50 for sensing an amount of light collected by the light collecting means and transmitting an operation signal according to the amount of light being sensed; And
And a lamp (60) which emits light using electricity input by being operated by an operation signal transmitted from the optical sensor (50). delete The method of claim 1,
And an additional reflector (15) reflecting the light exiting through the opening of the light collecting enclosure (11) to the reflector (13). The method of claim 1,
Circulating means for circulating while refracting light moved from the guide tube 20;
The heat absorbing means 80 further absorbs heat from the light circulated by the circulation means, wherein the circulation means is provided inside the guide tube 20 to be guided in a straight line along the longitudinal direction of the guide tube 20. Circulation reflecting back to the reflecting member 71 while circulating the light reflected by the reflecting member 71 and the reflecting member 71 and the light guided while being reflected on the inner surface of the guide tube 20 Hybrid lighting apparatus further comprises a member (73). 5. The method of claim 4,
The circulation member 73 is installed in the guide tube 20 in a state located above the reflective member 71 and is provided with a downward reflection portion 73a for reflecting down the light reflected from the reflective member 71 and the Further comprising an upward reflecting portion (73b) for reflecting upward the light reflected from the downward reflecting portion (73a), the heat absorbing means 80 is in close contact with the circulation means while wrapping the outer peripheral surface of the circulation means of the circulation means A hybrid lighting device, characterized in that the endothermic tube of the coil form in which the fluid absorbing heat is circulated.

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