RU44798U1 - FLOWING 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 improving the operational reliability of an electric heater, safety, comfort during use and simplifying the design. The specified technical result is achieved due to the fact that the flowing electric water heater contains a tank with pipelines for supplying and discharging water, a heating element and a pressure sensor located in the tank cavity. The pressure sensor of the electric heater is mounted on the cold water supply pipe. In addition, the instantaneous water heater is equipped with a temperature sensor, which is electrically connected to the heating element. To evenly distribute the incoming cold water, a divider can be installed in the lower part of the tank on the water supply pipe, while the tank has the shape of a cylinder elongated in the vertical direction. To create additional resistance to the flow of cold water, providing an increase in hydraulic pressure on the membrane of the pressure sensor, a nozzle can be installed in it at the entrance to the tank of the water supply pipeline. For its use of an electric heater in the shower, it can be equipped with a second heating element connected similarly to the first.

Description

The utility model relates to the electric power industry and can be used in electric water heating devices designed to provide the consumer with an autonomous source of hot water during periodic or emergency shutdowns from the centralized hot water supply, as well as in cases where there is no hot water supply.

Two types of electric water heaters are known - storage and flow-through. Accumulative electric water heaters are designed, as a rule, for the gradual heating of large volumes of water, and flow-through heaters are used for instantaneous heating of water continuously coming from the water supply network. The main advantage of instantaneous electric water heaters compared to storage heaters is that the heating of water in the device begins immediately at the moment of opening the tap. This allows you to get hot water at any time and in unlimited volume.

Known instantaneous high-pressure electric water heater [1], intended for use in electrical installations of residential buildings, which consists of a pipe with a valve at its output end. A water heating element is placed in the cavity of the electric heater, and an actuator is installed on the nozzle, consisting of a cylinder with a piston, the rod of which, if necessary, acts on the limit switch. The limit switch has the ability to move along a special bar. By moving the limit switch along the bar and closing the valve,

adjust the temperature of heating the water heater. A disadvantage of the known electric heater [1] is the horizontal location of the pipe, in the cavity of which is placed a water heating element. With this arrangement, the movement of the water flow occurs in the horizontal direction, which creates turbulence in the flow due to the difference in temperature, pressure, speed and density. As a result of this, there is a constant wave-like mixing of cold and hot water throughout the volume of the nozzle, which leads to the same wave-like changes in the water temperature at the outlet of the device. This, of course, is a negative factor.

Also known is a flow-type electric water heater [2], intended for use in hot water supply systems. An electric water heater consists of a body equipped with pipelines for supplying and discharging water with shut-off valves installed on them. In its upper part, the body is made with profiled walls. A heating element is located in the body of the electric heater. A distinctive feature of the known electric heater [2] is that part of the wall of the housing is made in the form of a membrane mechanically connected to a shut-off valve installed on the cold water supply pipe. The upper profiled part of the body is made in the form of a bellows and is mechanically connected to the circuit breaker. The upper part of the body is equipped with a nozzle with an explosive valve. During operation, in the event of an emergency, when the pressure is higher than the calculated one, raising the nozzle upward will puncture the diaphragm of the explosive emergency valve, which will protect the heater body from breaking. The presence in the design of a known electric heater [2] means to ensure

emergency protection at a pressure exceeding the permissible is an important advantage of an electric heater, however, the following disadvantages of the known electric heater [2] should be noted. This is, first of all, the complexity of the design and regulation of the processes of turning on and off the electric heater. In addition, the process of heating water in an electric heater [2] does not begin immediately after the cold water enters the electric heater body, but only after filling a significant volume of the electric heater body and creating working pressure inside it.

From the literature [3], an electric water heater is known for instant heating of water continuously supplied from a water supply network, for example, for domestic needs. A water supply pipe and a water drain pipe are connected to the body of the electric heater. A spring-loaded valve with a hole is installed on the water drain pipe. Part of the housing wall is made in the form of a disk with a rod interacting with the power switch of the electric heater. A disk of variable thickness is installed between the rod and the power switch, which together with the handle, shaft and spring forms a device that blocks the interaction of the moving wall with the power switch. The presence of a blocking device in the electric heater allows both hot and cold water to be obtained from it. In addition, if there is no iodine in the water supply network, the electric heater is automatically turned off, and the handle is set to the blocking position, which eliminates the spontaneous shutdown of the electric heater's power. A disadvantage of the known electric heater [3] is the complexity and, consequently, the low reliability of the blocking system of the electric heater, which consists of many mechanical

parts, both moving and stationary. In addition, the proposed locking system is cumbersome, it occupies a significant part of the total volume of the electric heater. At the same time, the heating element itself occupies only a small part of the cavity of the tank of the electric heater, which is not optimal from the point of view of mixing water layers with different temperatures.

The closest in its design and technical nature to the proposed utility model is a flow-through electric heater described in the literature [4], selected as a prototype. Known electric water heater [4] is intended for instant heating of water continuously coming from the water supply network. The electric heater contains a tank with a water supply pipe and a water drain pipe connected to it. Inside the tank is an electric heater connected to a switch. Part of the tank body is made in the form of a membrane, which is a pressure sensor with which the switch contacts. A spring-loaded valve is installed on the water drainage pipe, which has a through hole, the passage area of which is 0.002 ... 0.004 of the membrane area. The water supply pipeline is equipped with a tap, when opened, cold tap water enters the tank, gradually filling it. When the water flow is below the minimum capacity of the electric heater, all water passes through the through hole of the valve. With increasing water flow, the valve hole does not have time to let the entire water flow through, the pressure in the housing increases and is perceived by the membrane, which includes a switch and an electric heater. In this case, the valve also opens and the flow of heated water is diverted through the pipeline to the consumer. Thus, from the description of the operation of the known electric heater [4],

selected as a prototype, it follows that the electric heater does not provide instant heating of water to a predetermined temperature, which is usually ~ 60 °. The heating element is connected only after creating a pressure in the filled cavity of the tank, sufficient to bend the membrane, which ensures the operation of the heater switch. This creates for the consumer insufficiently comfortable conditions for using an electric heater. In addition, the system of turning on and off the electric heater, as well as the design of the spring-loaded valve, are quite complicated and are unlikely to be able to ensure reliable uninterrupted operation of the device in the conditions of our water supply system. The well-known electric heater [4] also does not solve the problem of protection by temperature, which is a very significant drawback of the technical solution chosen as a prototype.

The objective of the proposed utility model is to increase the operational reliability of the electric heater, safety and comfort when using it, as well as a significant simplification of the design.

To achieve this, a flow-through electric heater is proposed, which, like the one closest to it, selected as a prototype, contains a tank with water supply and drain pipes, a heating element and a pressure sensor located in the tank cavity. A feature of the proposed utility model that distinguishes it from the well-known adopted as a prototype device is that the flow-through electric water heater is additionally equipped with a temperature sensor electrically connected to the heating element. Moreover, the pressure sensor

The electric water heater is mounted on a cold water supply pipe.

To create additional resistance to the flow of cold water, providing an increase in hydraulic pressure on the membrane of the pressure sensor, a nozzle can be installed in it at the entrance to the tank of the water supply pipeline.

To evenly distribute the incoming cold water, a divider can be installed in the lower part of the tank on the water supply pipe. For the same purpose, it is preferable that the tank has the shape of a cylinder elongated in the vertical direction.

To expand the operational capabilities of an electric heater, for example, for use in a shower cabin, it can be equipped with a second heating element connected similarly to the first.

The temperature sensor of the electric heater can be made in the form of a thermal relay.

The most important tasks posed during the creation of the proposed utility model are: increasing the reliability and safety of the electric heater, as well as simplifying its design. The implementation of these tasks was made possible thanks to the following.

A significant simplification of the design compared to the prototype was achieved by installing a pressure sensor on the cold water supply pipe. Thereby:

• it became possible to create a tank of technological cylindrical shape, in contrast to the prototype, in which part of the housing wall is made in the form of a membrane in contact with a switch connected to a heating element;

• there is no need to install a spring-loaded valve on the hot water discharge pipe;

• since the heating element is switched on from the operation of the pressure sensor installed on the inlet pipe, the water in the proposed utility model is heated to a stable temperature (~ 60 ° C) at the outlet of the electric heater within (15-20) seconds. In the prototype, heating begins only after the tank is completely filled with cold water and the necessary pressure is created in the entire volume of the tank of the electric heater.

An urgent problem in the design of new modern models of instantaneous electric water heaters along with reliability remains ensuring the safety of the device. This problem was successfully solved in the proposed utility model as follows. In addition to one protection circuit, namely, a water pressure sensor at the inlet of an electric heater electrically connected to a heating element, a second protection circuit is introduced in the claimed utility model - by temperature. This is accomplished by introducing a new distinguishing feature that is absent in the prototype of the temperature sensor, made in a specific example of the implementation of the utility model in the form of a thermal relay. If the set water temperature is exceeded, for example, 60 ° C, the thermal relay is activated and the heating element is disconnected from the network.

It should also be noted the signs included in the dependent claims:

• the presence of a nozzle in the cold water supply pipeline ensures stable operation of the pressure sensor;

• the divider and the vertical shape of the cylindrical tank of the electric heater contribute to uniform

water distribution in the lower zone of the tank and its smooth movement from inlet to outlet, ensuring the efficiency of the electric heater and comfortable conditions for the consumer;

• the introduction of an additional heating element allows the use of an electric heater for a shower cabin, providing the installation of three different operating modes using a power switch: 2, 3 or 5 kW.

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

Figure 1 shows a General view of the proposed flow-through electric heater (longitudinal section);

figure 2 presents the electrical diagram of the electric heater.

The electric heater consists of a housing 1, inside of which a tank 2 is mounted. A pipe 3 for supplying cold water and a pipe 4 for removing hot water are connected to the tank 2. A heating element (TEN) 5 is mounted in the inner cavity of the tank 2, and a pressure sensor 6 is installed on the cold water supply pipe 3, which is a membrane device that, when the minimum allowable pressure of about 0.5 bar is reached at the inlet of the electric heater, turns on the power to the heating element 5 At the entrance to the tank 2 of the pipeline 3 for supplying cold water, a nozzle 7 with a calibrated hole is installed, which creates additional resistance to the flow of water, increasing the hydraulic pressure by pressure sensor membrane 6. The electric heater is equipped with a temperature sensor 8 mounted on the upper surface of the tank 2 and representing a protective (thermal) relay, connected in series through a pressure sensor 6 and a switch 9

with a light indicator 10c by the heating element 5 (see figure 2). In the lower part of the tank 2, on the cold water supply pipe 3, a divider 11 is installed, which is designed to evenly distribute the incoming cold water in the lower zone of the tank 2. The shape of the tank 2, which is a cylindrical flask, also contributes to the uniform distribution of heated water and its vertical upward movement. elongated in the vertical direction. The dimensions of the heating element 5, optimally selected in relation to the shape of the tank 2, maximally filling the volume of the tank 2, also guarantee a stable temperature at the outlet of the device. The tank body 2, as well as all the parts of the electric heater in contact with water, are preferably made of copper, which is characterized by high anticorrosion properties and resistance to thermal destruction. As heating elements 5, closed heating elements are used, which are a copper tube with a heating coil pressed into it and a ceramic filler.

The proposed instantaneous water heater operates as follows.

When opening the tap installed on the cold water supply pipe 3 (not shown in Fig.), Water enters the tank 2 through the pressure sensor 6, jet 7 and divider 11. When the pressure sensor reaches the minimum allowable pressure at the inlet of the electric heater 6 will automatically connect the heating element 5. If the inlet water pressure decreases below the minimum allowable, and also when the water supply from the water main is stopped, the pressure sensor 6 will automatically turn off the power heating element 5. When the temperature of the water in tank 2 exceeds the maximum operating

temperature (~ 60 ° C), thermal relay 8 automatically disconnects the heating element 5 from the network. This shutdown is a means of protecting the device from overheating. After cooling, the electric heater will automatically turn on.

Thus, the proposed utility model having the design described above provides, in comparison with the prototype, an increase in operational reliability, safety and comfort during its use. In addition, unlike the prototype, the design of the electric heater is simple and compact.

USED SOURCES:

1. RF patent 2042892, cl. F 24 H 9/20, F 24 H 1/20, publ. 1995.

2. Auth. testimonial. USSR 1679152, class F 24 H 1/20 publ. 1991.

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

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

Claims (4)

1. A flowing electric heater containing a tank with pipelines for supplying and discharging water, a heating element and a pressure sensor located in the tank cavity, characterized in that it is additionally equipped with a temperature sensor electrically connected to the heating element, and the pressure sensor is mounted on the water supply pipe. 2. The flowing electric heater according to claim 1, characterized in that a divider is installed in the lower part of the tank on the water supply pipe, and the tank has the shape of a cylinder elongated in the vertical direction. 3. The flowing electric heater according to claim 1 or 2, characterized in that a nozzle is installed at the inlet to the tank of the water supply pipeline. 4. Flowing electric heater according to claim 1 or 2, characterized in that it is equipped with a second heating element connected similarly to the first.