RU109949U1 - INDUCTION ELECTRIC BOILER - Google Patents

Abstract

 1. The electric boiler of the induction principle of heating liquid media, containing at least one flow tank for passing through it a heated liquid medium, an inductor, an inlet pipe for a heated liquid medium and an outlet pipe for a heated liquid medium, characterized in that each of the flow tanks is isolated from another using bushing ceramic insulators, which are supplied with voltage, and at least three stainless steel electrodes installed inside each flowing vertical are used as an inductor set tank but so that their connection is provided between the center point through the coolant, wherein the ends of electrodes are located outside the tank, and the electrodes are adapted to dive into the tank at different depths. ! 2. The electric boiler according to claim 1, characterized in that the immersion of the electrodes at different depths is ensured by screwing them in or out of the tank body. ! 3. The electric boiler according to claim 1, characterized in that the screwing or unscrewing of the electrodes from the tank body is ensured by electric drives with stuffing box seals. ! 4. The electric boiler according to claim 1, characterized in that water is used as a heat carrier. ! 5. The electric boiler according to claim 1, characterized in that the inductor is made on the basis of a magnetic system and a primary winding consisting of coils, with insulation per voltage class. ! 6. The electric boiler according to claim 5, characterized in that the coils are fixed in the frame using pressure elements consisting of insulators (on the top and bottom of each coil) and pressure bolts. ! 7. The electric boiler according to claim 5 or 6, characterized in that the output ends of the coils you

Description

The utility model relates to electric boilers and can be used for heating industrial and auxiliary buildings.

The prior art electric boilers [1, 2, 3, 4], containing a water tank, inside which are installed TENy.

The disadvantage of such boilers is a special requirement for the quality of the chemical composition of water. Water containing lime forms scale on the surface of the heating elements and renders them unusable. Replacing heating elements is expensive and difficult technically. It requires a complete analysis of the tank. The closest solution is induction boilers [6]. The solution is also patented by the utility model of the Russian Federation No. 87856 and describes a device for induction heating of liquid media, comprising a cylindrical body with a cover and a bottom, an inner ring mounted above the bottom, and having through holes for the passage of a heated liquid medium, an inductor, an inlet pipe for a heated liquid medium and outlet pipe for a heated liquid medium, characterized in that it further comprises a central inner cylindrical channel mounted coaxially with the housing, with the upper part cent the inner cylindrical channel is connected to the housing cover and through holes are made on its surface for the passage of the heated liquid medium, and the lower part is connected to the outlet pipe for the heated liquid medium, the inductor is made in the form of a cylindrical cavity mounted between the body and the central inner cylindrical channel with the formation annular channels for the passage of a heated liquid medium, while inside the cylindrical cavity a winding is installed, hermetically pressed by a binder die ctric material, its upper part is connected to the housing cover, and the lower part to the inner ring. Induction electric boilers are intended for use in autonomous heating systems, hot water supply in technological processes associated with the heating of an intermediate coolant. The lack of direct heating, unlike heating elements and gas heaters, allows boilers to work much longer (over 30 years) without losing their technical indicators.

The disadvantage of this type of boiler is the use of a closed flow tank. As a result, such a device cannot be controlled by heat generation power. The boiler works constantly, which does not allow saving energy. One boiler is installed on a certain area of the heated premises.

The device cannot provide efficient operation when organizing an operational backup heating system or, if necessary, urgently increase the heating power with a significant decrease in ambient temperature.

The technical result of the claimed utility model is an induction electric boiler that allows you to adjust the heating power and which can be used quickly and quickly to install a heating system, for example, in emergency situations; The electric boiler is not picky about the choice of electrodes, which can be any steel pipes.

The claimed technical result is achieved due to the fact that the electric boiler of the induction principle of heating liquid media, containing at least one flow tank for passing through it a heated liquid medium, an inductor, an inlet pipe for a heated liquid medium and an outlet pipe for a heated liquid medium, characterized in that each of the flow tanks is isolated from the other by means of continuous ceramic insulators, which are supplied with voltage, and at least three stainless electrodes are used as an inductor steel installed inside each flowing vertically mounted tank so that their connection to each other is ensured at a central point through the coolant, the ends of the electrodes being outside the tank, and the electrodes are made to be immersed inside the tank at different depths.

In addition, the immersion of the electrodes at different depths is ensured by screwing them in or out of the tank body.

In addition, screwing or unscrewing the electrodes from the tank body is ensured by electric drives with stuffing box seals.

Water is used as a heat carrier.

The inductor can be made on the basis of a magnetic system and a primary winding, consisting of coils, with insulation to the voltage class. The coils are fixed in the frame using pressure elements consisting of insulators (above and below each coil) and pressure bolts. The output ends of the coils are displayed on the insulators of the input device.

On the outer surface of the inlet and outlet pipes, temperature sensors for the inlet and outlet water are installed. In addition, thermal switches are installed on the surface of the pipes of the water heater. A flow sensor is installed near the inlet (bottom) flange.

The electric boiler (see Figure 1) is an indirect heating electric boiler in which the heat generated during the flow of induced electric current in the walls of the pipes (1) of the water heater made of corrosion-resistant austenitic steel is used to produce hot water, and heated water passes inside the pipes. Electric current does not pass through heated water; therefore, no specific electrical resistance requirements are imposed on water. For inlet and outlet of water, inlet (2) and outlet (3) flanges are installed respectively.

The inductor can be made on the basis of the magnetic system (4) and the primary winding, consisting of coils (5), with insulation to the voltage class. The coils are fixed in the frame using pressure elements consisting of insulators (above and below each coil) and pressure bolts. The output ends of the coils are displayed on the insulators of the input device (6). The input device is made for cable connection. The magnetic circuit, the winding and the input device of the electric boiler are similar in design to the corresponding nodes of the dry transformer with air cooling. To intensify the cooling of the high-voltage winding, centrifugal fans are installed in the lower part of the electric boiler (7). Outside, the electric boiler is covered with a protective cover that protects the active and current-carrying parts from access to them and foreign objects from the side and top.

The water heater connected to the grounded case of the electric boiler acts as a secondary, short-circuited, transformer winding. The water heater is separated from the mains by insulation to a voltage class. In any operating mode, the voltage on the water heater relative to the ground, and also between the input and output flanges, is zero. In this regard, the electric boiler can be connected to a common electrical network without an isolation transformer, and connect the water supply pipelines to the electric boiler without insulating inserts. To control the thermal parameters on the outer surface of the inlet and outlet pipes, temperature sensors (8) for the inlet and outlet water are installed. In addition, thermal switches (9) are installed on the surface of the pipes of the water heater, designed for emergency shutdown of the electric boiler in case of unacceptable overheating of the water heater. Near the inlet (lower) flange, a flow sensor (15) is installed, designed for emergency shutdown of the electric boiler in case of violation of water circulation.

Lead wires from cooling fans, as well as from temperature, flow sensors, and thermal switches are connected to the terminal block clamps in the connection box (10) located in the side of the electric boiler and covered by a panel of the protective cover.

To control the operation of the electric boiler and protect it from abnormal operating modes, a control cabinet (SHU) with control and protection equipment is supplied with it. Communication wires are connected to the control cabinet, which should be connected to the terminals of the electric boiler connection box.

The operation of the electric boiler is controlled automatically using control equipment located in the control cabinet. In emergency conditions, the protection equipment turns off the electric boiler.

Before switching on, it is necessary to fill the fully hydraulic system, to bleed air from the air exhaust devices in the system and on the electric boiler. To release air from the electric boiler water heater, a tap with a drain pipe (11) is installed, which must be opened when filling and closed after water appears in the pipe. Turn on the circulation pump, make sure that there is normal water circulation. Reopen the air vents again, making sure there is no air in the system.

If it is necessary to empty the electric boiler water heater (for example, if there is a danger of freezing), it is necessary to drain the water from the water supply system. For this purpose, plugs (14) may be provided at the lower ends of the collectors, the opening of which will allow to drain the remaining water from the water heater.

The principle of operation of the device

The heating system (see Figure 2) in which the electric boiler operates is a closed system with an expansion tank and constant forced circulation of the coolant.

Circulation may be provided by circulation pumps.

In addition to heating, the thermal energy generated by the electric boiler can be used to heat water for household needs.

The electric boiler allows on its basis to provide a make-up system from an external water supply system that automatically maintains the required amount of water in the system by opening the make-up valve and (at an external water supply pressure below the system pressure), turn on the make-up pump. From operating experience, in the absence of leaks in the pipelines, the need to recharge the system occurs 2-3 times a month, due to the evaporation of water from the expansion tank.

As a coolant in the heating system, water is used from an external water supply, without additional treatment (cleaning, adding substances that improve electrical conductivity, etc.). Thus, the properties of water when used in the system do not change and constant periodic replacement (to exclude the destructive effect on pipelines and on the operation of an electric boiler) is not required.

The electric boiler (see Figure 2) operates on the principle of the flow of current through the coolant (water) having a certain resistance of the water column. The electrodes (13) connected to the “star” of the boiler close the electric circuit through water, which is thus both a heat carrier and a heating element. To supply electric energy to the coolant, insulated from each other by means of ceramic insulators (12), vertically mounted tanks (16), which are supplied with voltage and, preferably, at least three electrodes (13) in each stainless steel, immersed in the coolant, are used (water), inside the tanks in the center and interconnected at a central point through the water into a "star".

The electrodes are held inside the tank by means of supporting devices (15) resting on the edges of the tank.

The thermal power of the boiler in this way depends on the immersion depth of the electrodes (the contact area of the power supply elements and the coolant and the distance from the rods to the grounded structures (second pole)). A deeper immersion of the electrodes (13) in the tanks (16) causes an increase in current, and, accordingly, power, rise of the electrodes causes a decrease. Cold water is supplied from below, hot water is supplied from above. To ensure the necessary power of the electric boiler, the electrodes are immersed inside the tanks to a predetermined depth. Lowering (raising) of the electrodes is carried out by screwing (unscrewing) from the boiler body.

In order to ensure power regulation of the electric boiler without shutting it off, it is possible to upgrade by installing electric drives with stuffing box seals, which will allow changing the position of the electrodes even when the boiler is running.

It should be noted that when using a boiler of a similar design at high voltage (10 kV), it may be necessary to increase the diameter and height of the tanks to increase the breakdown distance and the liquid column. Also, with an increase in boiler power, it will be necessary to change the flow rate of the flowing liquid (to avoid overheating), by replacing the circulation pumps with units of higher performance and working pressure.

Maximum current protection can be provided on the basis of ET-521 relays, powered by current transformers of extreme phases through test blocks. When these relays are triggered, the output protection relay will trip, which closes its contacts to self-holding and supplies a plus to the trip coil, and an alarm is triggered, and opening the normally closed contact removes the operational current from the thermal protection.

It also provides for the shutdown of the electric boiler when the coolant reaches the specified maximum temperature and the subsequent automatic inclusion when the coolant is cooled. This can be implemented on an electric contact thermometer TKP-160Сr-M1-UHL2, which allows you to change the on-off temperature, if necessary, depending on the temperature in the street. Thus, the operation mode of the boiler is intermittent (only the circulation pump remains in operation). Due to the thermal inertia of the coolant, the temperature inside the heated rooms remains constant, but there is a saving in electricity, because the boiler does not work continuously, as is the case with the prototype.

For comparative characteristics of the electric boiler according to the utility model with a power of 6 kV and industrially produced electric boilers of 0.4 kV, control measurements of the time and frequency of operation and consumption of electricity by these electric boilers were carried out.

Results:

Providing a normal, comfortable temperature (20-25 ° С (according to SanPiN2.2.4.548-96 "Hygienic requirements for the microclimate of industrial premises" and GOST 12.1.005-88 "General sanitary and hygienic requirements for the air of the working area") in the premises heated by an electric boiler of 6 kV (total volume - 10140 m ³ ), the electricity consumption per month was 63,000 kW / hr. The specific energy consumption per 1 m ³ was 6.21 kW / h per month.

During the operation of the 0.4 kV electric boiler, to ensure the same temperature in the premises of a heated building with an area of 728 m ² (the volume of heated rooms is 1820 m ³ ), the electricity consumption per month was 12960 kW / h. The specific energy consumption per 1 m ³ is 7.12 kW / h per month.

Thus, the inventive electric boiler provides the opportunity to save electricity by regulating the load.

Information sources:

1. http://www.mk-termo.ru/catalog/90/

2.http: //sogrevaem.narod.ru/kotli2_2.htm

3. http://www.narodcom.ru/catalog/?cat_id=22

4.http: //www.sadovodu.ru/catalog/price55/

5. http://www.ekonomkotel.ru/

Claims (10)

1. The electric boiler of the induction principle of heating liquid media, containing at least one flow tank for passing through it a heated liquid medium, an inductor, an inlet pipe for a heated liquid medium and an outlet pipe for a heated liquid medium, characterized in that each of the flow tanks is isolated from another using bushing ceramic insulators, which are supplied with voltage, and at least three stainless steel electrodes installed inside each flowing vertical are used as an inductor set tank but so that their connection is provided between the center point through the coolant, wherein the ends of electrodes are located outside the tank, and the electrodes are adapted to dive into the tank at different depths. 2. The electric boiler according to claim 1, characterized in that the immersion of the electrodes at different depths is ensured by screwing them in or out of the tank body. 3. The electric boiler according to claim 1, characterized in that the screwing or unscrewing of the electrodes from the tank body is ensured by electric drives with stuffing box seals. 4. The electric boiler according to claim 1, characterized in that water is used as a heat carrier. 5. The electric boiler according to claim 1, characterized in that the inductor is made on the basis of a magnetic system and a primary winding consisting of coils, with insulation per voltage class. 6. The electric boiler according to claim 5, characterized in that the coils are fixed in the frame using pressure elements consisting of insulators (on the top and bottom of each coil) and pressure bolts. 7. The electric boiler according to claim 5 or 6, characterized in that the output ends of the coils are displayed on the insulators of the input device. 8. The electric boiler according to claim 1, characterized in that on the outer surface of the inlet and outlet nozzles installed temperature sensors of the incoming and outgoing water. 9. The electric boiler according to claim 1, characterized in that thermal switches are installed on the surface of the pipes of the water heater. 10. The electric boiler according to claim 1, characterized in that a flow sensor is installed next to the input (lower) flange.