KR20080040660A - Boiler apparatus of a solar focus type - Google Patents

Abstract

A focusing type solar heating boiler is provided to enhance the heating efficiency by installing a rotation plate including a reflecting mirror and a water tank. A focusing type solar heating boiler comprises a base(4) having a hollow structure, a transverse support(6), a lengthwise support(8), a reflecting part(10), a tank part(20) and a sun-trajectory tracing part(40). The base has a circular cutting hole(5) and is formed like a hexahedron. The transverse support is mounted on an upper surface of the base. The lengthwise support is connected to two supper surfaces of the transverse support. The reflecting part is disposed on an upper part of the lengthwise support to reflect sunlight. The tank is disposed on an opposite upper part of the lengthwise support to focus sunlight on a center portion and store water. The sun-trajectory tracking part is disposed on the base and the transverse support to move the transverse support along a trajectory of the sun.

Description

Solar centralized boiler device {BOILER APPARATUS OF A SOLAR FOCUS TYPE}

The present invention relates to a solar-focused boiler device, and more specifically, a plurality of reflectors are arranged in multiple angles so that the reflected light of the sunlight through the plurality of reflectors are concentrated at the central concentration point of the water tank, the reflector and the water tank is mounted It relates to a solar intensive boiler device by allowing the rotating plate to move along the trajectory of the sun, the installation cost is very low, and the water in the boiler can be easily heated.

As is well known, a boiler is a device for boiling water to a constant temperature for use as heating water or shower water, including industrial use, and usually uses gaseous fuel such as liquefied fuel such as fossil fuel or kerosene or gas. It is composed of boiling water by forming a heat source.

However, in recent years, as the oil price, which is the basis of fossil fuels, has soared, development of various alternative fuels is being promoted as a measure of high oil prices, and energy development using solar energy, which is a representative fuel of alternative fuels, is actively progressing. There is a situation.

In general, a configuration using solar energy can be roughly divided into a solar heating apparatus for boiling water and a solar power generating apparatus for generating electric power from sunlight.

However, the solar heating apparatus converts solar energy into electric power using a solar cell, and uses the electric power to boil water, and to store water to be heated in transparent customs and to irradiate sunlight. It is made of a device.

However, in the case of the electronic heating device, since the solar cell is expensive, there is a problem that the installation cost for installing the solar heating device in each home is very excessive. In the latter heating system, since the water is simply stored in transparent tubules and warmed with sunlight, the installation cost of the device is low, but there is a problem that the water is hardly heated and takes a considerable time to warm up.

In addition, there is a problem that water is hardly warmed in the winter when the temperature of the outside air is low, and the water is hardly heated in the late afternoon because the direction of transparent customs does not move along the trajectory of the sun. there was.

The present invention has been made in view of the above-described prior art, and the plurality of reflectors are arranged at various angles so that the reflected light of the sunlight through the plurality of reflectors is concentrated at the central concentration point of the water tank, and the reflector and the water tank are seated. It is an object of the present invention to provide a solar intensive boiler device in which the rotating plate is moved according to the sun's trajectory so that the installation cost is very low and the water of the boiler can be easily heated.

In order to achieve the above object, according to a preferred embodiment of the present invention is a hollow state, the base (4) made of a hexagonal shape having a circular cut hole (5) formed on the upper surface; A horizontal support 6 seated on an upper surface of the base 4; Vertical supports (8) connected to both upper surfaces of the horizontal support (6); A reflection unit (10) configured on an upper portion of the vertical support (8) and reflecting sunlight; It is configured on the upper side of the vertical support (8) on the opposite side of the reflecting portion 10, the sunlight reflected from the reflecting portion 10 is configured to be concentrated in the central predetermined portion, the tank portion 20 for storing water therein )Wow; Is provided on the base (4) and the horizontal support (6), provided with a solar-focused boiler device, characterized in that consisting of a solar trajectory follower 40 for moving the horizontal support (6) along the movement trajectory of the sun. do.

Preferably, the reflector 10 includes a reflector 16 for reflecting sunlight; A reflector cover 18 coupled to a rear surface of the reflector 16; A vertical support (12) for fixing the reflector cover (18) to the vertical support (8); There is provided a solar-focused boiler device, characterized in that consisting of an oblique reinforcement 14 for reinforcing the vertical support (12).

Preferably, the tank unit 20 includes a water tank 26 in which water inlet pipes 28 and outlet pipes 30 are formed on side and top surfaces thereof to store water therein and to flow in and out of water; A vertical support (22) for fixing the water tank (26) to the vertical support (8); An oblique reinforcing bar 24 for reinforcing the vertical support 22; Provided with a predetermined portion of the inlet pipe 28 is provided with a solar centralized boiler device comprising an inlet valve 32 to regulate the flow of water.

Preferably, the sun trajectory follower 40 includes a circular rotary plate 42 recessed in the cutting hole 5 of the base 4; A battery 44 fixed to a predetermined upper surface of the rotating plate 42; A geared motor 48 which generates a rotational force through the power of the battery 44; A first pulley (46) condensed on the geared motor (48); A first belt (52) for transmitting the rotational force of the first pulley (46); A second pulley 54 which receives the rotational force through the first belt 52 and is condensed on the input shaft of the worm reducer 56; A worm reducer 56 for increasing driving force by reducing the rotational force transmitted through the second pulley 54; A third pulley 58 condensed on the output shaft of the worm reducer 56; A second belt 60 receiving the rotational force of the third pulley 58; A fourth pulley 62 which rotates by receiving the rotational force of the second belt 60; A rotation shaft 64 condensed on the fourth pulley 62; A bevel gear (66) formed at an end of the rotation shaft (64) to vertically convert the rotation force; A fifth pulley 68 condensed on the bevel gear 66 to receive rotational force; A third belt 70 receiving the rotational force of the fifth pulley 68; A sixth pulley 72 which rotates by receiving the rotational force of the third belt 70; A pinion gear 72 condensed and rotated by the sixth pulley 72; It is fitted to the pinion gear 72, there is provided a solar-focused boiler device, characterized in that consisting of a rack gear (7) formed along the inner circumference of the cutting hole (5).

Preferably, the reflector 16 is provided with a solar-focused boiler device, characterized in that each reflector 16 is mounted to be bent at multiple angles in order to centrally reflect the reflected light in the central predetermined portion of the tank unit 20. .

Preferably, the reflector 16 is provided with a solar-focused boiler device, characterized in that the concave reflector for focusing the reflected light at one point.

Preferably, the water tank 26 is provided with a solar centralized boiler device characterized in that the black coating to facilitate the absorption of the reflected light.

Preferably, the sun trajectory tracking unit 40 includes a memory storing 365 days of sunrise and sunset time data, position data of the sun and pulse values for each sun trajectory; A control unit for controlling the geared motor 48 to be moved along the sun trajectory through position data of the sun extracted from the memory; Provided is a solar intensive boiler device further comprising a timer for timing the elapsed time.

Preferably, the geared motor 48 is provided with a solar centralized boiler device, characterized in that the DC stationary motor.

Solar intensive boiler device according to the present invention heats the water stored in the water tank by concentrating the solar reflected light in the water tank through a plurality of reflectors bent at multiple angles, so that it is used directly as a shower water, or used as an auxiliary boiler for heating water The energy consumption can be effectively reduced, and the reflected light is moved along the trajectory of the sun to increase the energy efficiency of the solar light, thereby maximizing energy efficiency.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

1 is a perspective view showing the configuration of a solar centralized boiler apparatus according to an embodiment of the present invention, Figure 2 is a side view showing the configuration of a solar centralized boiler apparatus according to an embodiment of the present invention.

Referring to this, in the solar centralized boiler apparatus 2 according to an embodiment of the present invention, the plurality of reflectors are arranged at various angles so that the reflected light of the sunlight through the plurality of reflectors is concentrated at the central concentration point of the water tank, It is a device that makes it easy to heat the boiler water by installing the rotating plate on which the water tank is mounted and moving along the sun's trajectory.

To this end, the solar centralized boiler apparatus 2 according to an embodiment of the present invention is provided with a base 4 made of a hexagonal shape having a hollow inside and having a circular incision 5 formed thereon. A horizontal support 6 seated on an upper surface of the base 4; A vertical support (8) connected to the upper surfaces of both sides of the horizontal support (6), the upper support of any one of the vertical support (8), the reflector (10) for reflecting the sunlight; It is configured on the upper side of the vertical support (8) on the opposite side of the reflecting portion 10, the sunlight reflected from the reflecting portion 10 is configured to be concentrated in the central predetermined portion, the tank portion 20 for storing water therein ) Is provided.

In addition, the solar centralized boiler apparatus 2 according to an embodiment of the present invention is configured in the base 4 and the horizontal support 6, the sun for moving the horizontal support 6 along the trajectory of the sun The locus following part 40 is provided.

Therefore, in the solar centralized boiler apparatus 2 according to the embodiment of the present invention, in the state in which the reflector 10 and the tank unit 20 are configured to face each other, the sun is reflected through the reflector 10. The light irradiates the tank unit 20 to heat the water stored in the tank unit 20.

In addition, the solar centralized boiler apparatus 2 according to an embodiment of the present invention heats the water in the tank unit 20 using the sun reflected light, due to the driving of the solar trajectory follower 40, The reflection unit 10 and the tank unit 20 are moved along the trajectory, so that the reflection of sunlight is optimally achieved.

That is, the position of the reflector 10 is changed by driving the sun trajectory follower 40 so that the reflector 10 can face the sun at all times.

In more detail, the reflector 10 configured in the solar centralized boiler apparatus 2 according to an embodiment of the present invention includes a reflector 16 for reflecting sunlight; A reflector cover 18 coupled to a rear surface of the reflector 16; A vertical support (12) for fixing the reflector cover (18) to the vertical support (8); It consists of an oblique reinforcement 14 for reinforcing the vertical support 12.

At this time, the reflector 16 is mounted to be bent at multiple angles, respectively, as shown in Figure 2, a plurality of reflectors 16 to concentrate the reflected light in the central predetermined portion of the tank unit 20.

In addition, the reflector 16 is preferably a concave reflector for concentrating the reflected light at one point.

In more detail, the tank unit 20 configured in the solar centralized boiler apparatus 2 according to an embodiment of the present invention stores water therein, and an inlet pipe 28 on its side and upper surface in order to flow water in and out. And a water tank 26 in which an outlet pipe 30 is formed, and a vertical support 22 for fixing the water tank 26 to the vertical support 8; An oblique reinforcement stand 24 for reinforcing the vertical support 22 is provided, and an inlet valve 32 provided in a predetermined portion of the inlet pipe 28 to control the flow of water is configured.

At this time, the water tank 26 is preferably coated in black to facilitate the absorption of the reflected light.

In addition, the solar track following unit 40 configured in the solar centralized boiler apparatus 2 according to an embodiment of the present invention is a circular rotary plate 42 which is recessed in the cutting hole 5 of the base 4 and ; A battery 44 fixed to a predetermined upper surface of the rotating plate 42; A geared motor 48 which generates a rotational force through the power of the battery 44; A first pulley (46) condensed on the geared motor (48); A first belt (52) for transmitting the rotational force of the first pulley (46); A second pulley 54 which receives the rotational force through the first belt 52 and is condensed on the input shaft of the worm reducer 56; A worm reducer 56 for increasing driving force by reducing the rotational force transmitted through the second pulley 54; A third pulley 58 condensed on the output shaft of the worm reducer 56; A second belt 60 receiving the rotational force of the third pulley 58; A fourth pulley 62 which rotates by receiving the rotational force of the second belt 60; A rotation shaft 64 condensed on the fourth pulley 62; A bevel gear (66) formed at an end of the rotation shaft (64) to vertically convert the rotation force; A fifth pulley 68 condensed on the bevel gear 66 to receive rotational force; A third belt 70 receiving the rotational force of the fifth pulley 68; A sixth pulley 72 which rotates by receiving the rotational force of the third belt 70; A pinion gear 72 condensed and rotated by the sixth pulley 72; The pinion gear 72 is meshed with the rack gear 7 formed along the inner circumference of the cutting hole 5.

At this time, the sun trajectory tracking unit 40 includes a memory (not shown) storing 365 days of sunrise and sunset time data, sun position data, and pulse values for each sun trajectory therein; A controller (not shown) for controlling the geared motor 48 to move along the sun trajectory through position data of the sun extracted from the memory; A timer (not shown) for timing the elapsed time is further included.

Accordingly, in the solar centralized boiler apparatus 2 according to the embodiment of the present invention, the rotor plate 42 is moved in consideration of the trajectory of the sun according to the 364 day unit and the elapsed time unit of each day, thereby moving the energy of sunlight. It is configured to use optimally.

On the other hand, the geared motor 48 is preferably a DC forward and reverse motor that can generate a precise rotational force by applying a pulse wave while using the power of the battery, and electrically connected to the control unit for the initial time setting and drive command Further provided is an operating switch 46.

The function and action of the solar centralized boiler apparatus according to an embodiment of the present invention having the above-described configuration will be described in detail with reference to the accompanying drawings.

First, when the solar centralized boiler apparatus 2 according to the exemplary embodiment of the present invention operates an operation switch 46 to set an initial current time, a controller (not shown) separates time data and solar trajectories from memory. The pulse value is extracted to start driving.

In this state, the plurality of reflecting mirrors 16 reflect the sunlight to face the sunlight and overlap the reflected light with the light focusing point 21 provided at the central predetermined portion of the water tank 26 to provide the water tank 26. Start to warm up the water contained inside.

Then, the controller determines whether the time for changing the position of the sun has elapsed through a timer, extracts a preset pulse value for each sun trajectory from the memory, and drives the geared motor 48.

Then, while the first pulley 46 condensed on the geared motor 48 rotates, the rotational force is transmitted to the second pulley 54 condensed on the input shaft of the worm reducer 56 via the first belt 52. To pass.

Then, the driving force is increased while decelerating the rotational force transmitted through the second pulley 54 through the worm reducer 56. Then, the rotational force is output to the third pulley 58 condensed on the output shaft of the worm reducer 56.

Then, the rotational force of the third pulley 58 is transmitted to the fourth pulley 62 via the second belt 60, and the rotation shaft 64 condensed on the fourth pulley 62 rotates in linkage. Will be.

Then, while the rotational force is vertically converted through the bevel gear 66 formed at the end of the rotation shaft 64, the rotational force is transmitted to the fifth pulley 68 condensed on the bevel gear 66, the fifth pulley ( The rotational force of the 68 is transmitted by the third belt 70 to the sixth pulley 72.

Then, the pinion gear 72 condensed on the sixth pulley 72 is rotated by receiving the rotational force. Then, the pinion gear 72 moves the rotating plate 42 while rotating along the rack gear 7 formed along the inner circumference of the cutting hole 5.

Then, the reflector 16 is always positioned to face the sun, it is possible to reflect the optimum sunlight light.

In addition, the water tank 26 configured in the solar centralized boiler apparatus 2 according to an embodiment of the present invention is further provided with a separate temperature sensor (not shown), the temperature inside the water tank 26 through a temperature sensor When the temperature is above a certain temperature showered with warm water in the summer through a hose (not shown) connected to the outlet pipe 30, or by connecting the hose with a separate main boiler to use a higher temperature using a small energy in the main boiler It can also be boiled and used as heating water for indoor heating in winter.

That is, the solar centralized boiler apparatus 2 according to the embodiment of the present invention may be used as a summer shower hot water supply by itself, or used as an auxiliary boiler to preheat heating water to be supplied to the main boiler. May be used. It is obvious that the energy consumption can be effectively used both for shower hot water supply and for supplementary preheating of the heating water.

On the other hand, the solar centralized boiler apparatus according to an embodiment of the present invention is not limited to the above embodiment, but various modifications can be made without departing from the technical gist of the invention.

1 is a perspective view showing the configuration of a solar centralized boiler apparatus according to an embodiment of the present invention,

2 is a side view showing the configuration of the solar centralized boiler apparatus according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

4: bass, 10: reflector,

16: reflector, 20: tank,

26: water tank, 40: sun trajectory follower,

48: geared motor, 56: worm reducer,

66: bevel gear, 73: pinion gear.

Claims (9)

A base 4 formed in a hexagonal shape having a hollow inside and having a circular cutout 5 formed on an upper surface thereof; A horizontal support 6 seated on an upper surface of the base 4; Vertical supports (8) connected to both upper surfaces of the horizontal support (6); A reflection unit (10) configured on an upper portion of the vertical support (8) and reflecting sunlight; It is configured on the upper side of the vertical support (8) on the opposite side of the reflecting portion 10, the sunlight reflected from the reflecting portion 10 is configured to be concentrated in the central predetermined portion, the tank portion 20 for storing water therein )Wow; Concentrated on the base (4) and the horizontal support (6), the solar centralized boiler apparatus, characterized in that consisting of a solar trajectory follower (40) for moving the horizontal support (6) along the trajectory of the sun. The method of claim 1, wherein the reflector 10 A reflector 16 for reflecting sunlight; A reflector cover 18 coupled to a rear surface of the reflector 16; A vertical support (12) for fixing the reflector cover (18) to the vertical support (8); Solar concentrated boiler device, characterized in that made of diagonal reinforcement (14) for reinforcing the vertical support (12). The method of claim 1, wherein the tank unit 20 A water tank 26 in which water inflow pipes 28 and outlet pipes 30 are formed on side and top surfaces thereof to store water therein and to flow in and out of water; A vertical support (22) for fixing the water tank (26) to the vertical support (8); An oblique reinforcing bar 24 for reinforcing the vertical support 22; The solar centralized boiler apparatus is provided with a predetermined portion of the inlet pipe (28) consisting of an inlet valve (32) to regulate the flow of water. The method of claim 1, wherein the sun trajectory follower 40 A circular rotary plate 42 recessed in the cutting hole 5 of the base 4; A battery 44 fixed to a predetermined upper surface of the rotating plate 42; A geared motor 48 which generates a rotational force through the power of the battery 44; A first pulley (46) condensed on the geared motor (48); A first belt (52) for transmitting the rotational force of the first pulley (46); A second pulley 54 which receives the rotational force through the first belt 52 and is condensed on the input shaft of the worm reducer 56; A worm reducer 56 for increasing driving force by reducing the rotational force transmitted through the second pulley 54; A third pulley 58 condensed on the output shaft of the worm reducer 56; A second belt 60 receiving the rotational force of the third pulley 58; A fourth pulley 62 which rotates by receiving the rotational force of the second belt 60; A rotation shaft 64 condensed on the fourth pulley 62; A bevel gear (66) formed at an end of the rotation shaft (64) to vertically convert the rotation force; A fifth pulley 68 condensed on the bevel gear 66 to receive rotational force; A third belt 70 receiving the rotational force of the fifth pulley 68; A sixth pulley 72 which rotates by receiving the rotational force of the third belt 70; A pinion gear 72 condensed and rotated by the sixth pulley 72; The pinion gear (72) is coupled to the solar centralized boiler device, characterized in that consisting of a rack gear (7) formed along the inner circumference of the cutting hole (5). The reflector (16) according to any one of claims 1 to 2, characterized in that each reflector (16) is mounted so as to be bent at multiple angles in order to reflect the reflected light to a central predetermined portion of the tank (20). Photovoltaic boiler system. The solar concentrating boiler apparatus according to any one of claims 1 to 2, wherein the reflector (16) is a concave reflector for focusing the reflected light at one point. 4. The solar centralized boiler apparatus according to claim 3, wherein the water tank (26) is coated in black to facilitate absorption of reflected light. [5] The apparatus of claim 4, wherein the sun trajectory tracking unit 40 includes: a memory storing 365 days of sunrise and sunset time data, sun position data, and pulse values for each sun trajectory; A control unit for controlling the geared motor 48 to be moved along the sun trajectory through position data of the sun extracted from the memory; Solar centralized boiler apparatus further comprises a timer for timing the elapsed time. 5. The solar concentrating boiler apparatus according to claim 4, wherein the geared motor (48) is a DC forward and reverse motor.

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