KR20120002607U - Regenerative electric boiler - Google Patents

Abstract

The present invention relates to a regenerative electric boiler, and more particularly, the cold water supplied to the inside of the hot water tank is primarily heated by the first heater, and secondly heated by the second heater installed in the heating unit to rapidly heat the high temperature. Regenerative electricity to not only make the hot water available to the room heating and domestic hot water, but also to accumulate the heat storage material inside the heating unit so that heat generated from the second heater can be stored. It's about a boiler.
That is, the present invention is a hot water tank 10 to which the drain pipe 11 for discharging hot water and the water supply pipe 12 for receiving cold water are connected; A heating part 40 provided with a heat storage part 20 inward and a circular coil pipe 30 installed outside of the heat storage part 20; A heating unit 50 including a first heater 51 installed inside the hot water tank 10, a second heater 52 installed between the circular coil pipe 30 and the heat storage unit 20; ; One end is connected to the end of the circular coil pipe 30 and the other end is connected to the front end of the indoor heating pipe 62, between the one end and the other end of the heating water supply pipe is connected to the hot water pipe (61) ( 60); One end is connected to the end of the indoor heating pipe 62, the other end is the heating water discharge pipe 63 is connected to the suction pipe 71 of the drain pipe 11 and the circulation pump 70; One end is connected to the discharge hole 72 of the circulation pump 70, the other end is composed of a reheating tube (73) connected to the front end of the circular coil pipe (30).

Description

Regenerative Electric Boiler {REGENERATIVE ELECTRIC BOILER}

The present invention relates to a regenerative electric boiler, and more particularly, the cold water supplied to the inside of the hot water tank is primarily heated by the first heater, and secondly heated by the second heater installed in the heating unit to rapidly heat the high temperature. In addition to the hot water can be used as indoor heating and domestic hot water, as well as to the heat accumulating material inside the heating unit to accumulate heat generated from the second heater to the heat storage electric boiler to promote thermal efficiency. It is about.

In general, boilers can raise the indoor temperature to the desired heating temperature by raising the cold water circulating through the flow path to a predetermined temperature by supplying energy generated by using energy such as oil, gas, electricity, etc. It is common to be able to receive warm water through the pipe as needed.

However, these boilers have a problem of polluting the environment due to the large amount of heat energy, which is caused by the generation of combustion gas because the indoor heating temperature and hot water temperature can be maintained at an appropriate level only by direct use of thermal energy. .

In addition, farmers need to operate a boiler for a long time to grow crops in a plastic house facility, but unlike cities, farmers must use electricity or oil as a heat energy source because city gas is not supplied. There was a problem that the greater the economic burden as it increases.

In particular, when the boiler is stopped, the water temperature in the hot water pipes and the heating pipes drops rapidly over time, and as a result, no more room heating or hot water can be expected. There was a problem that it takes a considerable time to increase the temperature and hot water temperature.

The present invention was devised to solve the above problems, and an object of the present invention is to allow the cold water supplied to the inside of the hot water tank to be firstly heated by the first heater, and secondly by the second heater installed in the heating unit. By heating the hot water to quickly use the hot water as indoor heating and domestic hot water, as well as to accumulate heat storage material inside the heating unit to promote heat efficiency so that the heat generated from the second heater can be accumulated. It is to provide a regenerative electric boiler.

Another object of the present invention is to maintain the high temperature inside the heating unit by the latent heat accumulated in the heat storage unit even if power is not supplied to the heating unit, as well as being able to use indoor heating and high temperature hot water without consuming energy for a long time. The present invention provides a regenerative electric boiler for rapidly increasing hot water to the original heating temperature and hot water temperature by the latent heat accumulated in the heat storage unit when the power is re-supplied to the heating unit.

In order to achieve the above object, the present invention is an electric boiler which is installed inside the casing portion to supply hot water and heating water of high temperature by heating the low temperature heating water and cold water circulating in the room,

A hot water tank to which a drain pipe for discharging hot water and a water pipe for receiving cold water are connected; A heating unit in which a heat storage unit is installed and a circular coil pipe is installed outside the heat storage unit; A heating unit including a first heater installed inside the hot water tank, and a second heater installed between the circular coil pipe and the heat storage unit; A heating water supply pipe having one end connected to an end of the circular coil pipe and the other end connected to a front end of an indoor heating pipe, wherein a hot water pipe is branched and connected between the one end and the other end; A heating water discharge pipe connected to one end of the indoor heating pipe and connected to a suction hole of the drain pipe and the circulation pump; One end is connected to the discharge hole of the circulation pump, the other end is provided with a heat storage electric boiler, characterized in that consisting of a reheating tube connected to the front end of the circular coil pipe.

At this time, the heating unit is characterized in that the heat storage tank for accommodating the heat storage unit in the inner center is installed.

In addition, the heat storage portion is characterized in that it is configured in the form of powder or pieces.

In particular, the hot water tank is characterized in that the water level control valve connected to the end of the water supply pipe is installed therein.

At this time, the hot water tank is installed inside the water level sensor, characterized in that the water supply pipe is provided with a solenoid valve is installed.

In addition, the heat storage portion is characterized in that composed of any one of the heat storage material of stone, metal, ceramic material.

On the other hand, the circular coil pipe is formed in the form of a circulating structure superimposed in a double or triple, the second heater is characterized in that it is installed between the outside and the inside of the overlapping circular coil pipe.

In addition, the heating unit is characterized in that the temperature sensor for detecting the internal temperature of the heating unit is installed inside or outside.

According to the present invention, the cold water supplied to the inside of the hot water tank is first heated by the first heater, and the second heating by the second heater installed in the heating unit to quickly use the high temperature hot water as indoor heating and hot water It will be effective.

In addition, the heat generated in the second heater is stored in the heat storage unit, it is possible to promote thermal efficiency even with a small amount of electrical energy consumption.

In particular, even if power is not supplied to the heating unit, the inside of the heating unit maintains a high temperature due to latent heat accumulated in the heat storage unit, so that indoor heating and high temperature hot water can be used without consuming electric energy for a long time, as well as the heating. When the power is re-supplied to the unit by the latent heat accumulated in the heat storage unit is an effect that can quickly increase the hot water to the original heating temperature and hot water temperature.

1a and 1b are a front view and a side view of a heat storage electric boiler according to the present invention.
Figure 2 is a central longitudinal cross-sectional view showing a heating unit in the heat storage electric boiler according to the present invention.
3 is a use state diagram showing an operating state for the heat storage electric boiler according to the present invention.
Figure 4a, 4b is a central longitudinal cross-sectional view showing the heat accumulator in the heat storage electric boiler according to the present invention.
5 is a front view showing another example of the water level control valve in the electric boiler according to the present invention.

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

1a, 1b is a front view and a side view of a heat storage electric boiler according to the present invention, Figure 2 is a central longitudinal cross-sectional view showing a heating unit in a heat storage electric boiler according to the present invention, Figure 3 is a heat storage electric boiler according to the present invention. Figure 4a, 4b is a central longitudinal cross-sectional view showing the heat accumulator in the regenerative electric boiler according to the present invention, Figure 5 is another example of a water level control valve in a regenerative electric boiler according to the present invention It is a front view showing.

1A to 5, the electric boiler 1 includes a hot water tank 10 to which a drain pipe 11 for discharging hot water, a water supply pipe 12 for receiving cold water, and an inner heat storage part are connected to each other. A heating unit 40 is installed and the circular coil pipe 30 is installed to the outside of the heat storage unit 20, the first heater 51 installed in the hot water tank 10, and The heating part 50 which consists of the 2nd heater 52 installed between the circular coil pipe 30 and the said heat storage part 20, One end is connected to the end part of the circular coil pipe 30, and the other end is indoors. Is connected to the front end of the heating pipe 62, the heating water supply pipe 60 is branched and connected between one end and the other end, and one end is connected to the end of the indoor heating pipe 62 The other end is the heating water discharge pipe 63 is connected to the suction hole 71 of the drain pipe 11 and the circulation pump 70, and one end is connected to the discharge hole 72 of the circulation pump 70 The other end is composed of a reheating tube (73) connected to the front end of the circular coil pipe (30).

In this case, the electric boiler 1 is formed with a casing part 2 in which the heating part 40, the circulation pump 70, and the hot water tank 10 are fixedly installed therein, and the casing part 2. The heating unit 40 is fixedly installed on one side of the lower side, and the circulation pump 70 is fixedly installed on the other side, and the hot water tank 10 is fixedly installed on the upper side of the heating unit 40. Do.

In addition, one end of the water supply pipe 12 is connected to one upper surface of the hot water tank 10 and the other end is fixedly installed on the outer circumferential surface of the casing portion 2, one end of the heating water supply pipe 60 is Connected to the end of the circular coil pipe 30, the other end is preferably fixed to the outer peripheral surface of the casing (2).

In addition, one end of the hot water pipe 61 is connected by the heating water supply pipe 60 and the T-shaped joint pipe and the other end is fixedly installed on the outer circumferential surface of the casing portion 2, the heating water discharge pipe 63 One end is fixedly installed on the outer peripheral surface of the casing portion 2, the other end is preferably connected to the suction hole 71 of the drain pipe 11 and the circulation pump 70 by a T-shaped joint pipe.

In particular, the T-shaped joint pipe connected to the end of the heating water discharge pipe 63 is preferably made of a three-way valve to prevent the hot water flowing into the heating water discharge pipe does not flow into the drain pipe (11).

Accordingly, the electric boiler 1 has the heating unit, the circulation pump 70 and the hot water tank 10 fixedly installed inside the casing unit 2, and an outer circumferential surface of the casing unit 2. The water supply pipe 12, the heating water supply pipe 60, the hot water pipe 61 and the heating water discharge pipe 63 is to be fixedly installed.

At this time, the water supply pipe 12 is connected to the water pipe coming into the kitchen or bathroom from the outside, the hot water pipe 61 is connected to the hot water valve installed in the kitchen or bathroom, the first and second heaters (51, 52) It is preferable that the electric heater is configured to generate high temperature heat by receiving power from the outside.

In addition, the first and second heaters 51 and 52 may be formed in a pair, respectively, and the first heater 51 may be disposed on one side of the inner circumferential surface of the hot water tank 10 as shown in FIG. 1B. It is installed to face down or left and right, it is preferable that the second heater 52 is installed to face the left, right or front, rear of the upper surface of the heating unit 40.

That is, in the electric boiler 1 configured as described above, as shown in FIG. 3, the cold water supplied into the hot water tank 10 through the water supply pipe 12 is primarily formed by the first heater 51. After being heated and warmed, the circular coil pipe 30 is introduced along the drain pipe 11 by driving the circulation pump 70.

At this time, the first heated hot water is circulated along the inside of the circular coil pipe 30 adjacent to the second heater 52 and is secondly heated by the second heater 52 to quickly warm it with high temperature hot water. You lose.

For this reason, the user using the electric boiler 1 is to adjust the hot water valve of the kitchen or bathroom to which the hot water pipe 61 is connected, if necessary, can be easily supplied with high temperature hot water.

In addition, secondary hot water is introduced into the indoor heating pipe 62 through the heating water supply pipe 60 to circulate along the indoor heating pipe 62, and the room is warmly heated.

In particular, the hot water circulated in the indoor heating pipe 62 is combined with the primary heated hot water flowing into the drain pipe 11 and then supplied to the circular coil pipe 30 by driving the circulation pump 70. Since the heating is secondary to the heating unit 40 has the effect that can be restored to high temperature hot water in a short time.

In this case, the electric boiler 1 preferably further includes a control unit (not shown) for controlling the heating unit 50 and the circulation pump 70.

In addition, the control unit may further include a power switch for supplying power to the heating unit 50 and the circulation pump 70, and a temperature control switch for adjusting the indoor heating temperature.

That is, the electric boiler 1 is driven when the power switch of the control unit (On) is supplied to the heating unit 50 and the circulation pump 70 is driven, according to the adjustment of the temperature control switch The power supplied to the heating unit 50 repeats application / blocking to generate heat or maintain a stopped state.

For this reason, the temperature of indoor heating and hot water can be kept constant.

At this time, the heating unit 40 is preferably provided with a temperature sensor 90 for detecting the internal temperature of the heating unit 40 inward or outward.

That is, when the internal temperature of the heating unit 40 is overheated above the temperature set in the temperature sensor 90, the power applied to the heating unit 50 is cut off by the detection of the temperature sensor 90. Will be.

As a result, the internal temperature of the heating unit 40 is increased to prevent explosion and failure of the electric boiler 1 due to overheating of the heating unit 40.

In addition, the heating part 40 is made of a heat insulating material, the circular coil pipe 30 is formed in the form of a circulating structure overlapping in double or triple as shown in FIG. 2, the second heater ( 52 is preferably installed between the outer and the inner side of the overlapping circular coil pipe (30).

That is, when the circular coil pipe 30 is formed in the form of a double overlapping circulation structure, the second heater 52 is installed between the outer and the inner coil pipe, the circular coil pipe 30 is 3 When formed in the form of a circulating structure overlapped in the middle, the second heater 52 is to be installed between the outer coil pipe and the middle coil pipe or between the middle coil pipe and the inner coil pipe.

Due to this, the hot water circulating the circular coil pipe 30 can be heated quickly while the area in contact with the second heater 52 is widened, as well as the high temperature heat generated from the heating unit 40 This is not to be conducted to the outside, it is effective to maintain safety and thermal insulation at the same time.

In addition, the heat storage unit 20 is preferably made of any one heat storage material of tourmaline, germanium, stone including amethyst, metal, ceramic material.

As a result, the heat generated from the second heater 52 is stored while being transferred to the heat storage unit 20, and the heating unit 40 can raise heat therein more quickly while the circular coil pipe ( The first heated hot water flowing into the inside of 30) can be quickly heated to high temperature hot water.

In addition, due to the latent heat accumulated in the heat storage unit 20 it is possible to obtain hot water at a desired temperature even with a small amount of electrical energy consumption, as well as to reduce the use of electrical energy to reduce the economic burden. will be.

In particular, even if power is not supplied to the heating unit 50 according to the temperature set in the controller (not shown), the inside of the heating unit 40 is maintained at a high temperature by the latent heat accumulated in the heat storage unit 20. While being able to use indoor heating and high temperature hot water without consuming energy for a long time, as well as the desired heating by the latent heat accumulated in the heat storage unit 20 when power is supplied to the heating unit 50 again. There is an effect that can quickly rise to temperature and hot water temperature.

In the electric boiler 1 configured as described above, the heat storage unit 20 is preferably made of any heat storage material of stone, metal, or ceramic material, but is not limited thereto. The heat storage unit is shown in FIG. 4A. A heat storage tank 21 having a space portion formed therein so as to accommodate 20 may be installed at an inner center of the heating portion 40, and one or more heat storage materials may be mixed and filled into the space portion of the heat storage tank 21. Do.

At this time, the heat storage tank 21 is the center is opened as shown in Figure 4b, the space portion is preferably formed between the outer peripheral surface and the inner peripheral surface.

In addition, the heat storage tank 21 is made of a metal material containing aluminum, copper, or iron having excellent thermal conductivity, and the heat storage unit 20 is more preferably in the form of powder or flakes.

As a result, the electric boiler 1 is easy to handle the heat storage unit 20 and is not only convenient to manufacture, but also to increase the density of the heat storage unit 20 filled in the heat storage tank 21. The high temperature heat generated by the second heater 52 will be effective to accumulate for a long time.

The hot water tank 10 is preferably a water level control valve 80 is connected to the end of the water supply pipe 12 as shown in Figure 1a, 1b.

At this time, the water level control valve 80 is more preferably made of a general floating valve connected to the ball top (80a).

That is, when water is reduced in the hot water tank 10 due to the hot water discarded while taking a shower or washing the ball top 80a connected to the water level control valve 80, the water pipe 12 connected to the water pipe is gradually lowered. The cold water is supplied through.

In addition, when the water supplied into the hot water tank 10 reaches a certain level, the ball tower 80a connected to the water level control valve 80 is raised and the water supply pipe 12 is closed so that the water supply is no longer supplied. will be.

Thus, it is possible to prevent the circulation is not properly made due to the use of hot water, as well as to prevent damage to the hot water tank (10) generated by being supplied with an excessive amount of water into the hot water tank (10). Will be.

The electric boiler 1 configured as described above is preferably provided with a water level control valve 80 connected to the end of the water supply pipe 12 in the hot water tank 10, but is not limited thereto. As shown, the solenoid valve 81 is installed in the water supply pipe 12, and the water level sensor 82 may be installed in the hot water tank 10.

That is, the solenoid valve 81 is opened and operated according to the hot water shortage signal generated from the water level sensor 82, and the cold water is supplied into the hot water tank 10.

At this time, when the water level detection sensor 82 is in contact with the hot water accommodated in the hot water tank 10, the solenoid valve 81 stops driving and is shut off, so that the cold water flows into the hot water tank 10. The supply is to be cut off, and thus, an appropriate amount of hot water can be maintained in the hot water tank 10.

What has been described above is merely an embodiment for carrying out a regenerative electric boiler according to the present invention, the present invention is not limited to the above embodiment, the subject matter of the present invention as claimed in the utility model registration claims below Without departing, anyone with ordinary knowledge in the field to which the present invention belongs will have a technical spirit of the present invention to the extent that various modifications can be made.

Description of the Related Art [0002]
1: electric boiler 2: casing part
10: hot water tank 11: drain pipe
12: water supply pipe 20: heat storage unit
21: heat storage tank 30: circular coil pipe
40: heating section 50: heating section
51: first heater 52: second heater
60: heating water supply pipe 61: hot water pipe
62: indoor heating pipe 63: heating water discharge pipe
70: circulation pump 71: suction hole
72: discharge hole 73: reheating tube
80: level control valve 81: solenoid valve
82: water level sensor 90: temperature sensor

Claims (8)

In the electric boiler which is installed inside the casing to heat the low-temperature heating water and cold water circulated in the room to supply the hot water and the heating water of high temperature,
A hot water tank 10 to which a drain pipe 11 for discharging hot water and a water supply pipe 12 for receiving cold water are connected;
A heating part 40 provided with a heat storage part 20 inward and a circular coil pipe 30 installed outside of the heat storage part 20;
A heating unit 50 including a first heater 51 installed inside the hot water tank 10, a second heater 52 installed between the circular coil pipe 30 and the heat storage unit 20; ;
One end is connected to the end of the circular coil pipe 30 and the other end is connected to the front end of the indoor heating pipe 62, between the one end and the other end of the heating water supply pipe is connected to the hot water pipe (61) ( 60);
One end is connected to the end of the indoor heating pipe 62, the other end is the heating water discharge pipe 63 is connected to the suction pipe 71 of the drain pipe 11 and the circulation pump 70;
One end is connected to the discharge hole 72 of the circulation pump 70, the other end is a regenerative electric boiler, characterized in that consisting of a reheating tube (73) connected to the front end of the circular coil pipe (30). The method of claim 1,
The heating unit 40 is a heat storage electric boiler, characterized in that the heat storage tank 21 for receiving the heat storage unit 20 is installed in the inner center. The method of claim 2,
The heat storage unit 20 is a heat storage electric boiler, characterized in that consisting of powder or flakes. The method of claim 3, wherein
The hot water tank 10 is a heat storage electric boiler, characterized in that the water level control valve 80 is connected to the end of the water supply pipe 12 is installed therein. The method of claim 3, wherein
The hot water tank 10 has a water level sensor 82 is installed therein, the water supply pipe 12 is a heat storage type electric boiler, characterized in that the solenoid valve 81 is installed. The method according to any one of claims 1 to 5,
The heat storage unit 20 is a heat storage electric boiler, characterized in that composed of any one of the heat storage material of stone, metal, ceramic material. The method according to claim 6,
The circular coil pipe 30 is formed in a double or triple overlapping circulation structure, the second heater 52 is installed between the outer and the inner side of the overlapping circular coil pipe 30 is configured Regenerative electric boiler, characterized in that. The method according to claim 6,
The heating unit 40 is a heat storage electric boiler characterized in that the temperature sensor (90) for detecting the internal temperature of the heating unit 40 is installed in or out.

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