RU44373U1 - ELECTRIC HEATER - Google Patents

Abstract

Usage: in devices for electric heating of water for domestic and technical needs. Essence: a utility model is aimed at reducing energy consumption, improving the usability of the device and simplifying the design. The specified technical result is achieved due to the fact that the electric heater contains two parallel vertical tanks connected by two connecting pipes, a first heating element installed in one of the tanks, an inlet pipe for supplying cold water located in the lower part of one of the tanks, and an outlet pipe for exhausting hot water located at the top of another tank. Tanks of an electric heater are located inside the protective case filled with thermal insulation. The heating element is mounted on a flange sealed in the lower end part of one of the tanks and is equipped with a thermostat. The inlet pipe for supplying cold water is equipped with a check valve and the connecting pipes connect the adjacent walls of the tanks in their upper and lower parts. To implement the mode of accelerated heating of water, the electric heater can be equipped with a second heating element. For the convenience of using an electric heater, a control panel can be installed on its protective case, and to protect it from shock and other damage, the lower part of the protective case can be equipped with a safety cover.

Description

The utility model relates to the electric power industry and can be used in devices for electric heating of water for domestic and technical needs.

Two types of electric water heaters are known - flow and storage. Flowing electric water heaters, known, for example, from the literature [1] and [2], are designed for instantaneous heating of water continuously coming from the water supply network. They are characterized by high performance with high power consumption. Accumulative electric water heaters, designed, as a rule, for the gradual heating of large volumes of water, are more economical than flow-through. From the technical and patent literature, two main types of storage electric water heaters are known: with one tank (tank) and with two tanks. At the same time, for storage heaters, the problem of saving power costs is very relevant. Attempts to solve this problem are found in a number of domestic and foreign publications. As analogues of the proposed utility model, we consider both varieties of designs of electric water heaters.

Known electric water heater [3], which contains: one tank with water, the lower part of which is connected to the circulation pump, and heat the pump, and heating the water circulating between the lower and upper parts of the tank, accumulated in the tank with the formation of a layer with a given temperature in the upper part tank.

A distinctive feature of the known water heater [3] is that it contains an electronic control system consisting of a sensor of the residual amount of water in the tank; a unit for calculating the duration of an electric heater corresponding to the amount of residual water and the amount of water used; a memory unit for storing information obtained in the unit for calculating the duration of the electric heater; a time calculation unit for boiling water according to information from a memory unit; the control unit for the operation of the circulation pump and heater according to the output signal of the time calculation unit for boiling water.

Also known is an electric water heater [4], containing two tanks filled with water; two autonomous heaters designed to heat water in tanks and maintain a given temperature of water; pipelines with pumps connecting the bottom of one tank to the top of another tank. If the water level in one tank drops below the set value and the water boils in the other tank, the pumps pump water between the tanks until the water level in the first tank rises to the set value.

Both well-known electric water heaters, both [3] containing one tank and [4] consisting of two tanks, make it possible to obtain hot water of a given temperature in the quantity required by the consumer. However, the known electric water heaters are energy-intensive, because to ensure the circulation of heated water they include electric pumps.

Also known is an electric water heater, described in the literature [5], designed to heat water for hot autonomous

water supply of residential, public and industrial buildings, cottages and garages. The electric heater contains two tanks located one above the other, connected by two pipes. The upper tank is equipped with a cold water supply pipe and a valve, and the lower one is equipped with a hot water discharge pipe, a valve and a heating element located in the lower part of the tank cavity. The hot water outlet pipe is located in the bottom of the lower tank, and its inlet end is brought into the upper part of the cavity of this tank. The output end of the connecting pipe is brought into the lower cavity of the lower tank in the area of the heating element, and the second connecting pipe is a pipe equipped with a valve located between the bottom of the upper tank and the top of the lower tank. In the electric heater [5], due to the new arrangement of the elements of the device, the heat loss of the heated water is reduced and, therefore, the time for heating the water to a predetermined temperature is reduced. However, despite its undoubted advantages, it should be noted the disadvantages inherent in the analyzed technical solution. In the known electric water heater [5], significant heat losses occur, which arise as a result of the fact that cold water enters the upper tank, and water heating occurs in the lower tank. This design counteracts natural convection of water, which complicates the heat exchange processes of water masses. In addition, only one of the tanks is insulated in an electric water heater [5], namely, the lower one, which has a lower capacity, which leads to additional heat losses, and, consequently, to an increase in energy consumption. The disadvantages of the known electric heater [5] should also

attribute the presence of three gates that ensure the operation of the device, which are controlled manually.

The closest in its design and technical nature to the proposed utility model is a hot water system with a heat pump, described in the literature [6], selected as a prototype. The known hot water supply system [6] contains several, for example, two parallel mounted hot water tanks, a water heater with a heat pump, a circulation circuit in which water circulates between the water heater and the tanks and is heated to a boil. The known system [6] also contains an inlet pipe for cold water connected to the bottom of the tanks; a hot water pipe connected to the top of the tanks; electric water heaters built into the tanks, as well as multi-way valves. One of the valves selectively connects the tanks to the circulation circuit, and the other selectively connects the corresponding tank to the cold water pipeline.

However, it should be noted the disadvantages inherent in the technical solution selected as a prototype. In the known electric water heater [6], significant heat losses occur that arise as a result of the lack of insulation of the tanks in the design of the device, which leads to additional heat losses, and, consequently, to an increase in energy consumption. In addition, the design of the electric heater has a high energy intensity due to the presence of a heat pump in the water circuit, and

also a complex system for switching tanks to the circulation circuit and to the cold water pipeline.

The objective of the proposed utility model is to reduce the energy consumption of an electric heater by reducing the heat loss of heated water while simplifying the design of the device and increasing its reliability.

To achieve this objective, an electric water heater is proposed, which, like the one closest to it, selected as a prototype, contains two parallel vertical tanks connected by two connecting pipes, the first heating element installed in one of the tanks, an inlet pipe for supplying cold water, located in the lower part of one of the tanks, and the outlet pipe for the release of hot water located in the upper part of the other tank. A feature of the proposed proposed utility model that distinguishes it from the well-known adopted as a prototype of the device is that the tanks are located inside the protective housing filled with thermal insulation. The heating element of the electric heater is mounted on a flange sealed in the lower end part of one of the tanks and equipped with a thermostat. The inlet pipe for supplying cold water is equipped with a check valve and the connecting pipes connect the adjacent walls of the tanks in their upper and lower parts. To implement the mode of accelerated heating of water, the electric heater can be equipped with a second heating element. For the convenience of using an electric heater, a control panel can be installed on its protective case, and for

protection against shock and other damage the lower part of the protective housing can be equipped with a safety cover.

The most important of the tasks posed when creating the proposed utility model is to reduce the energy consumption of an electric heater. The implementation of this task was made possible thanks to the following.

The inventive utility model is a thermally insulated structure, the reduction of energy consumption of which is ensured by placing the tanks in a single sealed protective case filled with thermal insulation. This made it possible to significantly reduce the heat loss of the electric heater to the external environment. In addition, in the inventive electric heater, the heat exchange process itself is optimized due to the proposed location of the connecting pipes of the electric heater connecting the adjacent (adjacent) walls of the device. This feature ensures that mixing of hot and incoming cold water is minimized, which allows maximum temperature water to be taken from the electric heater.

It should also be noted that the introduction of such an essential feature as a non-return valve ensures the operation of an electric heater in automatic mode, while simplifying its entire design extremely, and, therefore, increasing its reliability. The signs included in the dependent claims (second additional heating element, control panel, protective cover) provide such consumer-friendly qualities as the possibility of large consumption of hot water without lowering its temperature (additional heating element),

ease of use of the device and its reliability (control panel and protective cover).

Thus, the combination of the above features allows us to solve the tasks.

The proposed utility model is illustrated in the drawing, which shows one of the specific examples of the implementation of the proposed electric heater.

In FIG. shows the proposed electric heater in the context of a fragment of the front panel.

The electric heater consists of a sealed protective housing 1, inside of which the first tank 2 (on the right) and the second tank 3 (on the left) are mounted. To communicate the first 2 and second 3 tanks, they are interconnected by pipes 4 and 5. Connecting pipes 4 and 5 are located between adjacent walls of tanks 2 and 3 in their upper and lower parts. Tanks 2 and 3 are in the form of cylinders elongated in a vertical direction (the so-called vertical arrangement of tanks). In the lower part of the first tank 2 is mounted an inlet pipe 6 for supplying cold water, equipped with a check valve 7, designed to prevent the emptying of tanks 2 and 3 in the event of a pressure drop in the water supply network. In the lower part of the second tank 3, a drain pipe 8 is mounted, which serves to flush the tanks 2 and 3, and a magnesium anode 9, designed to protect steel structural elements of the heater from electrochemical corrosion. In the upper part of the second tank 3 is mounted an outlet pipe 10, designed to release hot water. The protective housing 1 of the electric heater can be made, for example, of special structural plastic, or of mirror

polished stainless steel. Tanks 2 and 3 are made of corrosion resistant austenitic (non-magnetic) stainless steel. The connecting seams of the tanks 2 and 3 are welded by electron beam welding in a vacuum field. This technology provides high corrosion resistance of welds. All pipes of the electric heater are connecting 4 and 5, the inlet pipe 6 for supplying cold water, the drain pipe 8, the outlet pipe 10 for the release of hot water are made of stainless steel. The anode 9 is made of magnesium alloy. At the lower end of the first tank 2, a flange 11 is tightly mounted, on which a heating element (TEN) 12 with a thermostat 13 is located. The electric heater can be equipped with a second heating element 14, designed to provide accelerated heating of the water and installed in the second tank 3 similarly to the first heating element on flange 15. On the front panel 16 of the electric heater there are controls for power and temperature of water heating:

- power setting regulator 17;

- controller 18 for setting the water temperature;

- Scale 19 of an electric thermometer.

The volume between the protective housing 1 and the tanks 2, 3 is filled with thermal insulation 20 made of environmentally friendly polyurethane foam. Polyurethane foam has the lowest coefficient of thermal conductivity and is the most effective heat-insulating material. The lower part of the protective housing 1 is closed by a sealed cover 21, which protects the tanks from damage.

The proposed electric heater operates as follows.

Before connecting to the electric network, the electric heater is filled with cold water. Cold water through the check valve 7 and the inlet pipe 6 enters the first (right) tank 2, while cold water first fills the first tank 2 and then the second (left) tank 3, forcing air out of the tank 3 through the outlet pipe 10. How only water in the tank 3 will reach the upper level of the outlet pipe 10, it will begin to pour out through the pipe 10, which is a sign of a full filling of the tanks of the electric heater. After that, the outlet valve (not shown in Fig.) Is closed at the outlet pipe 10, and the electric heater is connected to the electric network. As the water is heated in the first tank 2, it enters the second tank 3 through pipes 4 and 5, gradually heating and replacing cold water in it. The consumption of hot water occurs from the upper part of the second tank 3, while due to the maximum distance of the hot water intake point from the point of entry of cold water and minimal mixing due to the separation of the tanks, as well as the small cross section of the connecting pipes 4 and 5, maximum temperature water is taken from which the thermostat is set to. On the front panel 16, using the power setting controller 17 and the water temperature setting controller 18, the user sets the desired temperature mode, which is maintained by the thermostat 13. If the set heating temperature is exceeded, the thermostat 13 automatically turns off the power to the device. Water is heated by an electric heating element 12. When the water temperature decreases, the thermostat 13 automatically connects power,

thus maintaining the temperature set. On the scale 19 of the electric thermometer reflects the actual level of water temperature. When the flow of hot water from the second tank 3, its volume is continuously replaced by an equal amount of heated water from the tank 2 due to the back pressure of the water supply. Thus, the operation of the device is carried out in automatic mode. At high water flow rates, a second electric heating element 14 is connected, due to which there is a continuous supply of hot water to the consumer.

Thus, the proposed electric heater having the design described above provides, in comparison with the prototype, a significant reduction in heat loss and, consequently, a reduction in the time of heating the water and energy savings. In addition, unlike the prototype, the design of the electric heater is simple, reliable and compact.

USED SOURCES:

1. RF patent 2008570, cl. F 24 H 1/20 publ. 1994.

2. RF patent 2172900, cl. F 24 H 1/20 publ. 2001.

3. Japanese application 3-297543, cl. F 24 H 1/18 publ. 2002.

4. Application of Japan 3-168360, cl. F 24 H 1/18 publ. 2001.

5. RF patent 2116580, cl. F 24 H 1/20 publ. 1998.

6. Application of Japan 3-173204, cl. F 24 H 1/18 publ. 2001 - prototype.

Claims (4)

1. An electric heater comprising two parallel vertical tanks connected in parallel by two connecting pipes, a first heating element installed in one of the tanks, an inlet pipe for supplying cold water located at the bottom of one of the tanks, and an outlet pipe for releasing hot water located at the top parts of another tank, characterized in that the tanks are located inside a protective housing filled with thermal insulation, the heating element is mounted on a flange sealed in the bottom second end portion of one of the tanks and provided with a thermostat inlet pipe supplying cold water is provided with a reflux safety valve and connecting pipes connect the adjacent walls of tanks in their upper and lower parts. 2. The electric heater according to claim 1, characterized in that it is equipped with a second heating element. 3. An electric heater according to claim 2, characterized in that a control panel is installed on the protective case. 4. The electric heater according to claim 1, or 2, or 3, characterized in that the lower part of the protective housing is equipped with a safety cover.