KR101060709B1 - A heat accumulator for boiler using microwave plasma - Google Patents

Abstract

PURPOSE: A thermal energy storage boiler using the microwave is provided to reduce the consumption of the electric energy by coupling the thermal energy member with the inner wall of the heating member and maintaining the raised inner temperature. CONSTITUTION: A thermal energy storage boiler using the microwave comprises a body portion(100), a plurality of heating portions(200), an air circulating portion(800), a sensor unit(300), and a controller(400). The body portion comprises a body, a heating member, a thermal energy storage member(130), and a conduit(140). The exterior wall of the body is formed into the plural layers of the thermal insulating member(111). The thermal energy storage member is coupled with in the inner wall of the heating member. The heating member emits the microwave in the thermal heat storage member. The air circulation portion circulates the internal air of the thermal heat storage member. The controller automatically controls the heating member according to the change of the temperature, and displays the temperature of the sensor unit in the digital screen.

Description

A heat accumulator for boiler using microwave plasma}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat storage boiler, and more particularly, to a heat storage boiler having a plurality of heat insulating materials, a heating material, and a heat storage material, and enabling automatic control of a target temperature value using microwaves as a heat source.

In general, the heat medium (water) circulated into the pipe of the main heat exchanger heated by the burner of the boiler is heated when the burner is operated, and the temperature is raised by heating, and the temperature is rapidly cooled after the operation is stopped. do.

In order to compensate for such a rapid cooling problem, there is 20-0378148 of the Republic of Korea registered room.

1 is an exploded perspective view of a conventional heat storage and instant heating electric boiler.

In a boiler in which a heater is mounted in a tank in which a heat insulation layer is formed, and an inlet pipe equipped with a discharge pipe and a circulation pump is formed in the tank, the body 10 having a cover to form an outer shape of the boiler and open the upper side; It is wound around the body 10 and provided in the inlet pipe 20 and the discharge pipe 30, the fluid pipe 40 for flowing water by the circulation pump, and in contact with the fluid pipe 40 The liquid heat storage member 50, which is a heat transfer material provided in the body 10, and an electric heater 60 for supplying heat to the heat storage member 50 to heat water in the fluid pipe 40. Instant heating electric boiler.

However, if the heat storage member is heated to heat the heat storage member, the heat storage member may be cooled to maximize the thermal efficiency unless the heat is continuously applied.

In addition, even when reaching a constant temperature, that is, a high temperature capable of heating water, it provides continuous heat, causing a problem of waste of power.

In addition, since the electric heater is used as a heat source, it is difficult to provide a desired temperature in a short time.

The present invention has been made in order to achieve the above object, it is to provide a microwave emitter as a heat source, and to provide a heating material and a heat storage material to maintain the temperature inside the heat storage material for a long time.

In order to achieve the above object, the present invention is the outer wall is formed of a plurality of layers of heat insulating material and the space is formed therein, the heating material coupled to the inner wall of the body, and the heat storage coupled to the inner wall of the heating material Ash, a body portion formed in the interior of the heat storage material, the inlet and the discharge port protrudes to the outside and the water flows into the interior, and a plurality of rows mounted inside the body to emit microwaves to the heat storage material A generation unit, an air circulation means formed in the heat storage material to circulate the air inside the heat storage material, a first temperature sensor which measures and transmits a temperature of the cooling water which is formed at the rear of the inlet and flows in, and an end of the heat storage material; A second temperature sensor formed inside the heat storage material and measuring and transmitting the temperature of the internal space; and coupled to the heating material to adjust the temperature of the heating material. And a sensor unit and a power switch including a third temperature sensor which is fixedly transmitted and a fourth temperature sensor which is formed at the rear of the outlet and measures the temperature of the water discharged and is discharged. It is characterized in that it comprises a control unit for automatically controlling the heat generating unit according to the temperature fluctuating in connection with the sensor, and displays the temperature of the first, second, third, and fourth on the digital screen.

Here, the heat generating unit, a housing having a space formed therein and an opening is formed on one side, a microwave emitter mounted inside the housing to emit microwaves into the opening, and formed behind the housing and the microwave divergence It may be made to include heat to discharge the heat generated from the air to the outside.

The housing may have a blocking film formed at an outer rear end thereof to prevent leakage of microwaves generated during operation of the microwave emitter.

In addition, the heat storage rod may be coupled to the inside of the heat storage material to extend the heat storage heat retention time.

In addition, the opening and closing valve for controlling the opening and closing of the inlet and outlet of the conduit may be provided.

The air circulation means is rotated by being coupled to the motor, and is coupled to the central axis formed through the internal space of the heat storage material, and circulated with the central axis to circulate the air inside the heat storage material. It may be made of a wind vane for rapidly heating the cooling water passing through the interior.

In addition, a gap is formed between the heat storage material and the central shaft penetrating the heat storage material, so that the expanded air caused by the wind vane is leaked into the gap.

At this time, the central axis and the wind vane, it is characterized in that it is coated with silicon carbide (Sic) to prevent self-heating and reflected waves.

According to the present invention of the configuration described above, the following effects can be expected.

First, the heating material is heated using microwaves, which may cause a rapid temperature rise, and by coupling the heat storage material to the inner wall of the heating material, it is possible to maintain an elevated internal temperature for a long time, thereby reducing power consumption. .

Accordingly, since the heat storage is used instead of the direct heating method, hot water can be effectively supplied for a certain time even when the power supply is turned off, which is efficient and economical.

In addition, there is an advantage that can automatically control the operation of the power supply according to whether the target temperature value is reached by the controller to recognize the temperature value provided from the plurality of temperature sensors.

It is also provided with air circulation means for circulating the hot air inside the heat storage material it is possible to heat the cooling water flowing in the conduit faster.

1 is an exploded perspective view of a conventional heat storage and instant heating electric boiler.
2 is a side cross-sectional view of a microwave heat storage boiler according to the present invention.
3 is a cross-sectional view showing an embodiment of the present invention.
4 is a cross-sectional view showing another embodiment of the present invention.

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

Figure 2 is a side cross-sectional view of a microwave heat storage boiler according to the present invention, Figure 3 is a cross-sectional view showing an embodiment of the present invention, Figure 4 is a cross-sectional view showing another embodiment of the present invention.

As shown in Figures 2 to 4, the present invention largely comprises a body portion 100, heat generating unit 200, air circulation means 800, the sensor unit 300 and the control unit 400.

The body portion 100 is formed to the outer wall to overlap the insulating material 111 of a plurality of layers to increase the heat retention, the body 110 is formed to form a space therein, and the inner wall of the body 110 The heating material 120 to be coupled, the heat storage material 130 coupled to the inner wall of the heating material 120, and formed inside the heat storage material 130, the inlet 141 and the outlet 142 is external Protruded to form a conduit 140 to discharge the hot water to the water storage tank.

In addition, the heat generating unit 200 is mounted inside the body 110 to emit microwaves to the heating material 120, so that all the cross-sections of the heating material 120 can be instantaneously heated. Plurality is provided.

The air circulation means 800 is further provided with an air circulation means 800 for circulating the internal air inside the heat storage material 130 to heat the cooling water flowing in the conduit 140 in a faster time. To do it.

In addition, the sensor unit 300 is formed in the rear of the inlet 141, the first temperature sensor 310 for measuring and transmitting the temperature of the incoming cooling water, and the end is inside the heat storage material 130 A second temperature sensor 320 formed to measure and transmit a temperature of an internal space, and a third temperature sensor 330 coupled to the heating material 120 to measure and transmit a temperature of the heating material 120; The fourth temperature sensor 340 is formed at the rear of the discharge port 142 to measure and transmit the temperature of the discharged water.

The control unit 400 is a power switch is formed to operate, and is connected to the first, second, third, fourth temperature sensor (310, 320, 330, 340) to automatically control the heat generating unit 200 according to the fluctuating temperature The temperature provided from the first, second, third, and fourth (310, 320, 330, 340) can be displayed on the digital screen.

Here, the heat generating unit 200 is made of a housing 210, a microwave emitter 220 and the fin 230.

The housing 210 has a space formed therein, and an opening is formed at one side, that is, in the direction of the heating material 120 so that microwaves can be emitted. The shape of the housing 210 is wider than that of the heating material 120. It is desirable to be manufactured so that it can spread to an area.

The microwave emitter 220 is mounted inside the housing 210 to emit microwaves into the opening to heat the heating material 120.

In addition, the fin 230 is formed in the rear of the housing 210 to discharge the heat generated by the microwave diverter 220 to the outside to reduce the malfunction of the microwave diverter 220. .

On the other hand, a blocking film 500 for preventing leakage of microwaves generated during the operation of the microwave diverter 220 is formed at the outer rear end of the housing 210, that is, the rear of the fin 230.

In addition, the heat storage rod 600 is coupled to the inside of the heat storage material 130 to extend the heat storage warming time, and the heat storage rod 600 may be any one capable of maintaining heat for a long time without being quenched. something to do.

On the other hand, the opening and closing valve 700 for controlling the opening and closing of the inlet 141 and the outlet 142 of the conduit 140 is provided.

Here, the on-off valve 700 is manufactured to be automatically controlled in connection with the control unit 400, which is a known technique will be omitted.

Referring back to FIG. 2, the air circulation means 300 is rotated by being coupled with a motor, and is formed through the internal space of the heat storage material 130, and the center axis 810. The wind vane 820 is coupled to interlock with the air to circulate the air inside the heating material 120 to quickly heat the cooling water passing through the conduit 140.

Here, the wind vane 820, the rotation direction and the inclination angle can be manufactured according to the discretion of those skilled in the art so as to cause a whirlwind to generate a sufficient circulation of air.

On the other hand, a gap is formed between the heat storage material 130 and the central shaft 810 penetrating the heat storage material 130, the expanded air by the operation of the wind vane 820 to the Leaking into the gap eliminates the risk of explosion.

In addition, the central axis 810 and the wind vane 820 is coated with silicon carbide (Sic) to minimize the frictional resistance during rotation, absorb the microwaves through the heat generating means 110 to induce self-heating Therefore, it is possible to prevent the reflected wave that may occur during rotation.

The operation sequence and operation principle of the present invention configured as described above will be described with reference to FIGS. 2 to 4.

When the power switch is operated in the control unit 400, microwaves are generated in the microwave emitter 220 and injected into the heating material 120 so that the heating temperature is rapidly heated while the heating material 120 is heated to a third temperature. The sensor 330 is displayed on the control unit 400, and at the same time, heat is transmitted to the heat storage material 130 to accumulate high temperature heat, and at the same time, the hot water temperature is supplied to the fourth temperature sensor 340. When the hot water temperature reaches the set temperature, the power of the microwave diverter 220 is automatically turned off to a standby power state and displayed on the control unit 400.

When the generation of the microwave is stopped as described above, the on-off valve 700 formed in the outlet 142 is opened to discharge the hot water into the hot water tank, and at the same time, the coolant is introduced into the inlet 141.

As such, the temperature of the space inside the heat storage material 130 decreases according to the flow of hot water and cooling water, and the temperature inside the heat storage material 130 is digitally controlled by the controller 400 by the second temperature sensor 320. The display is automatically controlled according to the temperature values of the first, second, third and fourth temperature sensors 310, 320, 330 and 340 to turn the power on and off to automatically operate the temperature of the internal space of the heat storage material 130. Maintain a constant to heat the temperature of the hot water discharged to a set temperature.

At this time, by operating the motor to rotate the wind vane 820 so that the cooling water flowing in the conduit 140 can be heated more quickly.

As described above, the present invention heats the heating material using microwaves, which may cause a rapid temperature increase, and by maintaining the elevated internal temperature for a long time by bonding the heat storage material to the inner wall of the heating material, The control unit recognizes the temperature value provided by the temperature sensor to automatically control the operation of the power supply according to whether the target temperature value is reached, and also includes an air circulation means for circulating the hot air inside the heating material. It can be seen that it is a basic technical idea to provide a microwave heat storage boiler that can heat the cooling water flowing faster, and within the scope of the basic idea of the present invention, Of course, many other variations are possible.

100: body 110: body
111: heat insulating material 120: heating material
130: heat storage material 140: conduit
141: inlet 142: outlet
200: heat generating unit 210: housing
220: microwave emitter 230: 휀
300: sensor unit 310: the first temperature sensor
320: second temperature sensor 330: third temperature sensor
340: fourth temperature sensor 400: control unit
500: blocking film 600: heat storage rod
700: on-off valve 800: air circulation means
810: central axis 820: wind vane

Claims (8)

The outer wall is formed of a plurality of layers of heat insulating material 111 and the space 110 is formed therein, the heating material 120 is coupled to the inner wall of the body, and the heat storage material is coupled to the inner wall of the heating material ( 130 and a body portion 100 formed in the heat storage material, the inlet 141 and the outlet 142 protruding to the outside and made of a conduit 140 through which water flows;
A plurality of heat generating parts 200 mounted inside the body to radiate microwaves into the heat storage material;
An air circulation means (800) formed in the heat storage material to circulate air in the heat storage material;
A first temperature sensor 310 formed at the rear of the inlet to measure and transmit a temperature of the inflowing coolant, and an end of the second temperature sensor 320 formed at the inside of the heat storage material to measure and transmit the temperature of the internal space; And a third temperature sensor 330 coupled to the heating material to measure and transmit the temperature of the heating material, and a fourth temperature sensor 340 to measure and transmit the temperature of the water discharged and formed at the rear of the outlet. Sensor unit 300 consisting of;
A power switch is formed and connected to the first, second, third and fourth temperature sensors to automatically control the heat generator according to the fluctuating temperature, and display the temperature of the first, second, third and fourth on a digital screen. Microwave heat storage boiler, characterized in that comprises a.
The method of claim 1,
The heat generator 200,
A housing 210 having a space formed therein and an opening formed at one side thereof;
A microwave emitter 220 mounted inside the housing to emit microwaves into the opening;
It is formed in the rear of the housing 휀 230 for discharging the heat generated in the microwave emitter to the outside; microwave heat storage boiler comprising a.
The method of claim 2,
The housing, the microwave heat storage boiler, characterized in that the outer membrane is formed with a blocking film (500) for preventing the leakage of microwaves generated during the operation of the microwave emitter (220).
The method of claim 1,
Microwave heat storage boiler, characterized in that the heat storage rod 600 is coupled to the inside of the heat storage material to extend the heat storage heat retention time.
The method of claim 1,
Microwave heat storage boiler, characterized in that the opening and closing valve 700 for controlling the opening and closing of the inlet and outlet of the conduit.
The method of claim 1,
The air circulation means 800,
A central shaft 810 coupled to the motor and rotating through the inner space of the heat storage material;
And a wind vane 820 coupled to the central axis to circulate air in the heat storage material to rapidly heat the cooling water passing through the conduit.
The method of claim 6,
And a gap is formed between the heat storage material and the central shaft passing through the heat storage material, so that the expanded air caused by the wind vane is leaked into the gap.
The method of claim 6,
The central axis and the wind vane are coated with silicon carbide (Sic) to prevent self-heating and reflected waves, the microwave heat storage boiler.

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