KR200324338Y1 - An independent electric power plant and an independent heating system - Google Patents

Abstract

The present invention generates its own heat by using superheated solar energy and supersaturated heat generating material without supplying fuel from the outside to make hot water and use it for heating as well as passing through a generator when hot water passes through a pipe. It is to build a self-generating facility by increasing the rotation speed of the generator.

In addition, it is intended to facilitate installation and management in an uncomplicated configuration, such as a method using solar heat, and to increase space utilization by utilizing empty space.

Description

An independent electric power plant and an independent heating system using solar and heating materials

The present invention relates to the construction of its own power generation and heating facilities by generating a natural energy source using heat and supersaturated heat generating materials.

Existing power generation facilities include hydroelectric power generation using dams, wind power generation using large plains and high winds, and risks, but they are non-polluting. These power generation facilities produce large amounts of electricity and supply them to homes and factories, and because of their size and the importance of the facilities, they are not managed by the state. In addition, electric shock accidents caused by high-voltage equipment caused by large-scale and long-distance supply are also seriously occurring.

In addition, homes, offices, and other places that require heating are heated by boilers using oil or gas, but the inconvenience of replacement due to aging or fuel costs due to the continuous supply of fuel is burdened. Some cheaper late night electricity is used, but the use of late night electricity is also low due to an increase in electricity costs due to the rising cost of fossil fuels. In addition, there is a need for a separate space for installing such a facility, and the problem of space utilization is also raised in an over-density area such as a city, where a space is also important.

As an alternative to these things, the method of using solar heat using the rooftop, which is an unused space of a home or a building, has been mentioned. However, due to the limitation of power generation due to changes in weather or season and uneven sunshine, other boiler facilities using oil are practically used. As it is used as such, installation cost is overlapped and space utilization is not the same as existing boiler facilities using fossil fuels.

The present invention has been devised to improve these problems, and generates hot water by using its superheated solar material and superheated heat generating material without supplying fuel from the outside. It is to build a self-generation facility by increasing the flow velocity when passing through the pipe.

In general, it is generally used as a heat generating material, but it hardens in a solid state, but when heated to a high temperature, it turns into a liquid and contains a lot of heat absorbed when it is melted. When it cools, it retains its supersaturated state as it dissipates heat and solid crystals must precipitate. The supersaturation is very unstable, so with a little impact, solid crystals are deposited all at once, releasing the heat they contain. This property is not a one-time, but a one-time one, so it can be used repeatedly and is also used for things such as hand stoves.

In addition, it is easy to install and manage in an uncomplicated configuration, such as using solar heat, and to increase space utilization by utilizing empty space.

1 is a perspective view showing the overall installation state of the present invention

Figure 2 is an exploded perspective view showing the configuration of each cell of the heating plate of the subject innovation

3 is an exploded perspective view showing the configuration of the heating plate of the present invention

4a to 4d is an operating state diagram showing the flow of hot water according to the heat of the heating material

5A is a partially cutaway perspective view of a cell with a heating material filled

5B is a cross-sectional view of a heating plate with a heating material filled

Explanation of symbols on the main parts of the drawings

2,3,4,5: cells a, b, c, d 10: case 11: cell case

12: hot water pipe 13: insulation 14: reflector

15: hot wire 16: inlet 17: outlet

18: stopper 19: impact line 20: permanent magnet

21: electromagnet 22: temperature sensor 23: inlet pipe

24: drain pipe 25: inlet pipe a 26: drain pipe a '

27: inlet pipe b 28: drain pipe b '30: heat generating material

40: glass plate 41: cell glass plate 60: heating main plate

70: impact portion 101: storage battery 102: gearbox

103: generator 104: circulation pump

Looking at the configuration of the present invention for achieving the above object, each cell consisting of a plurality of cells is installed in the interior of the heating plate with a heat insulating material, the inside of each cell is a continuous use of the reflector plate and heat generating material to absorb radiant heat and release radiant heat For this purpose, shock wires for shocking the heating wire and the heating material are provided, and each cell and the heating plate are covered with a glass plate, respectively, and a double structure that can collect and trap heat to effectively use the heat generated from the solar heat and the heating material. Will be achieved.

In addition, by installing the generator and the circulation pump integral with the increaser in the inlet pipe extending to the outside of the heating plate, and the generator is integrated with the increaser in the drainage pipe to increase the amount of power generated and the produced electricity is sent to the storage battery.

In addition, it is composed of a control line for controlling the shock and hot wires, the generator integrated with the gearbox, and the circulation pump to enter the inside of each cell.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view showing the overall installation state of the present invention, Figure 2 is an exploded perspective view showing the configuration of each cell of the heating plate of the present invention, Figure 3 is an exploded perspective view showing the configuration of the heating plate of the present invention, Figure 4a to Figure 4d is an operating state diagram showing the flow of hot water according to the heating of the heating material, Figure 5a is a partially cutaway perspective view of the cell in the heating material is filled, Figure 5b is a cross-sectional view of the heating plate in the heating material is filled.

There is an inlet 16 and an outlet 17 together with a stopper 18 at the upper and lower sides, and an inlet port a 25 and a drain port a ′ 26 at both sides, and at one end and at the other end of the support pin. The reflector plate 14 and the heating wire 15 are sequentially formed in the cell case 11 in which the electromagnets 21 and the permanent magnets 20 are formed, and the impact wires 19 are introduced to contact the electromagnets 21, respectively. After the hot water pipe 12 is connected to the inlet / drainage pipes 23 and 24 inserted into the inlet / drainage pipe a, a '(25), and 26', the cell glass plate 41 is covered. A heating main plate 60 in which cells a, b, c, d (2) (3) (4) (5) are connected in series; The heating main plate 60 is fitted in the case 10 in which the inlet / drainage pipes b and b '(27) 28 are formed at the lower right end, and the handles 202 are formed at both side surfaces, and the heat insulating material 13 is installed. After the glass plate 40 is covered and the heating material 30 is filled through the inlet 16 of each cell a, b, c, d (2) (3) (4) (5).

In addition, after the heating main plate 60 is installed in the case 10, the support plate 201 is configured to support the heating plate 1 formed by installing the glass plate 40, and the case 10 through the inlet pipe b (27). The increaser 102 integrally formed with the generator 103 is connected to the water supply pipe 23 extending to the outside, and the circulation pump 104 is continuously connected to the water supply pipe, and at the same time, the drain pipe b '( The generator 103 and the speed increaser 102 are integrally formed and connected and installed in the drain pipe 24 extending through the case 10 to the outside of the case 10. A drain pipe 24 extending through the generator 103 and the increaser 102 formed integrally is connected to the water tank 50, and is integrated with the impact line 19 and the heating line 15 from each cell. Control panel 100 configured to control the speed increaser 102 and the generator 103, the storage battery 101 is connected to the heating plate.

In the drawings, reference numeral 200 denotes a wire connecting the control panel 100, the storage battery 101, the speed increaser 102, the generator 103, and the circulation pump 104.

An example of operation by solar heat of the present invention configured as described above will be described in detail as shown.

When the water in the hot water pipe 12 is warmed to a certain temperature by the direct heat of the sun and the radiant heat of the reflector 14, the temperature of the water is sensed by the temperature sensor 22 installed in the drain pipe 24, and the control panel 100 circulates. The pump 104 is operated and the water is continuously heated by sequentially turning the inlet pipe 23, the hot water pipe 12, and the drain pipe 24 to be used as heating water by being stored in the water tank 50. At this time, the water passes through the speed increaser 102 connected to and installed in the water supply pipe 23, and power generation starts in the generator 103 integrally formed with the speed increaser 102. Here, the speed increaser 102 increases the rotation speed of the generator 103 and enables power generation even at a slow flow rate. The water thus passed is also integrated with the generator 103 to generate power once again through the gearbox 102 connected and installed in the drain pipe 24, and the generated electricity is stored in the storage battery 101 to be used in real life. will be.

Referring to the operation example using the heating material of the present invention in detail as shown in the accompanying drawings as follows.

Sodium thiosulfate (Na ₂ S ₂ O ₃ .5H ₂ O) or sodium acetate (CH ₃ CO ₂ Na) filled in cells a, b, c, d (2) (3) (4) (5) supersaturated The impact wire 19 introduced into the cell a 2 first to the heat generating material 30, etc., comes into contact with the electromagnet 21 at the bottom of the support pin (not shown), so that a current flows, thereby permanently at the other end of the support pin. While the magnet 20 is repeatedly attached to and dropped off the electromagnet, the heat generating material 30 is shocked to generate heat; At regular time intervals, the heating materials 30 of the cells b, c, d (3) (4) (5) are sequentially shocked to generate heat. When the heat generating material 30 of the cell d (5) is about to generate heat, the temperature of the water in the hot water pipe 12 of the cell a (2) rises more than a predetermined time, so that the temperature sensor 22 detects the temperature of the water. Since the hot water is circulated by operating the circulation pump 104 in the control panel 100, power generation is started as in the case of using the solar heat.

Over time, the heat generation of the heat generating material 30 ends and the heat generating material 30 is solidified again. The heat generating material 30 hardened by the heating wire 15 is heated for a predetermined time. The state of the heating material 30 is to be returned to the supersaturated state.

As the development of alternative energy due to severe environmental pollution and the depletion of fossil fuels is required, the present invention is an alternative solution to both of these problems. Economic effect and value as alternative energy by constructing power generation and heating system by using heat generating material that generates heat itself without needing external energy source to compensate for uneven sunshine caused by weather and seasonal changes. There is also.

Claims (3)

In the self-generation and heating system that uses the solar radiant heat to heat water for heating, install generators in the inlet and drain pipes, and produce electricity in real life, A drain pipe 24 and an inlet pipe 23 with a temperature sensor 22 are installed on the upper and lower sides and one side of the unit cells a, b, c, d (2) (3) (4) (5), respectively. And a heating main plate 60 at which both ends of the plurality of hot water pipes 12 are connected to and installed with the inlet / drainage pipes 23 and 24, and the inlet and drainage pipes b and b'27 and 28 at the lower right end thereof. The case 10 is formed and handles 202 are formed at both side surfaces, and the heat insulating member 13 is installed therein, and the heating plate 1 having a dual structure in which the glass plate 40 is sequentially connected and installed on the heating main plate and the case. ; A heat generating material 30 introduced into the cells a, b, c, d (2) (3) (4) (5); An increaser 102 connected to each of the inlet pipe 23 and the drain pipe 24 extending out of the heating plate 1; A control panel 100 connected to the heating plate; Self-heating and power generation system using solar and heating materials, characterized in that the generator 103 and the circulation pump 104 is integrally formed with the speed increaser 102 connected to the water inlet pipe (23). The method of claim 1 The basic cells a, b, c, and d (2, 3, 4, 5) have a stopper 18, an inlet 16, and an outlet 17 formed on the upper and lower sides thereof, respectively. and a '(25) (26) are molded and configured such that the electromagnet 21 and the permanent magnet 20 are attached to the inner lower end by supporting pins, and the impact line 19 is drawn in contact with the electromagnet 21. A cell case 11 in which an impact part 70 is formed; After the reflector plate 14 and the heating wire 15 are sequentially inserted into the cell case 11, the self-heating and power generation using solar heat and heating material, characterized in that the cell glass plate 41 is covered with a structure that is covered. system. The method according to claim 1 or 2, The exothermic material introduced into the cell (2,3,4,5) is selectively applied either sodium thiosulfate (Na ₂ S ₂ O ₃ .5H ₂ O) or sodium acetate (CH ₃ CO ₂ Na). Self heating and power generation system using solar heat and heating material.