RU2044415C1 - Electric water heater - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: invention relates to design of electric appliances for local water heating. Electric water heater has combination of different numbers of identical water heating sections which heating elements are placed inside water-tight case and are manufactured in the form of conductive band corrugated along two coordinate axes and roiled spiral electric insulation coat with additional metal layer with anticorrosion coat applied on it. Heater is provided with thermal control. EFFECT: enhanced operational efficiency and reliability. 4 dwg

Description

 The invention relates to the construction of electrical appliances of local hot water supply and can be used in air-heating units.

 Known electric heater containing a sealed enclosure with water inlet and outlet pipes, inside of which are placed the electrodes isolated from the housing, to which the mains voltage is supplied. Water is heated in it due to the flow of current through the water.

The disadvantages of such an electric heater are the large mass, dimensions, and the dependence of the power of the electric heater on the electrical conductivity of water, which can vary by 1-2 orders of magnitude (electrical resistance of river water ρ = 10-100 Ohm, m, distilled -10 ³ -10 ⁴ Ohm ˙ m). In addition, the time for heating water in such an electric water heater is long and amounts to 10-15 minutes.

Also known is a flow-type electric heater containing an insulating casing with water inlet and outlet pipes at its ends, made in the form of a combination of spherical shells annularly connected together by annular bridges, on the outer surface of which an electrically conductive film is applied [1]
The disadvantages of such an electric heater are low electrical safety due to the placement of a film heating element on the outer surface of the housing, large dimensions and low speed associated with a large volume of the sealed cavity of the housing with a power flowing electric heater 18-21 kW [2] In addition, with a small flow of water and large power overheating of the heater and failure, which reduces the reliability of its operation.

 As a prototype, a gas flow heater [3] was selected that contains an insulated sealed housing with inlet and outlet pipes and an electric heating section located inside it with a heating element made in the form of a conductive tape corrugated along two coordinate axes with an electrically insulating coating on the surface, tape ends designed to connect to a power source.

 However, due to the large heating surface, severe temperature conditions caused by sharp temperature changes during repeated switching on, there is always the possibility of local insulation coating failures due to peeling, cracking, peeling and aging of the material over time, as well as mechanical wear or damage to the insulation due to the possible presence of small but solid particles in water. Therefore, in this form, the device has low reliability and electrical safety when used for heating water.

 The aim of the invention is to increase the electrical safety and reliability of the electric heater.

The goal is achieved in that the electric heater containing a sealed housing with inlet and outlet pipes and an electric heating section located inside it with a heating element made in the form of a conductive tape corrugated along two coordinate axes with an electrically insulating coating on the surface, the ends of the tape are designed to be connected to the power source is provided with at least one additional electric heating section, made identical to the specified, while the conductive tapes of the sections are interconnected in series, a metal layer with an anti-corrosion coating is applied to their electrical insulation coating, the metal layer being grounded, and the tapes are connected to the power source so that its zero phase is connected to the end of the spiral located at the outlet pipe, and the phase voltage through the contacts of the inputted first relay and the contacts of the second relay connected in series to them is connected to the end of the spiral located at the inlet pipe, the winding ervogo relay is connected to input sensor head of water established in the inlet pipe formed on the basis of an electromagnetic flowmeter comprising a conduit electromagnet with poles around the conduit and the electrodes are disposed in one cross-section with poles of the electromagnet and at 90 ^on to the direction of magnetic lines of force, and the winding of the second relay is connected to the entered temperature sensor installed in front of the outlet pipe.

 The novelty and inventive step of the proposed electric heater due to the fact that the listed significant distinguishing features as follows affect the solution of the problem.

 In the proposed electric heater, a set of different numbers of the same type of heating sections can be used, while it provides separation of the phases of the voltage of the power source and their output from opposite sides of the housing to the first and last sections so that a voltage phase is connected to the end of the spiral at the inlet pipe, and towards the end of the spiral, the outlet pipe has a zero phase of the voltage of the power source. Since the outlet pipe always has the most severe temperature conditions, a gradual decrease in voltage along the spiral and bringing to the end of the coil at the outlet pipe of the zero phase reduce the risk of insulation failure, and therefore increase electrical safety and reliability. At the same time, by choosing one or another number of electric heating sections, it is possible to change the power of the electric heater and choose the most optimal power and electrical safety mode required in certain operating conditions of the electric heater.

 Drawing on the electrical insulation coating of the electrically conductive tape a heating element of a metal layer that is protected from corrosion by any anti-corrosion coating, and its grounding (also metal protective nets on the pipes are grounded) allows any breakdown of insulation to be closed to a metal grounded layer, and not through water, which also increases the electrical safety of the device .

Performing water pressure sensor based on the electromagnetic flowmeter comprising a conduit electromagnet with poles around the conduit and the electrodes are disposed in one cross-section with poles of the electromagnet and at 90 ^on to the direction of magnetic force lines and the connection electrodes to the relay winding (rather than to the counter , as in a conventional electromagnetic flowmeter), through the contacts of which the phase of the voltage of the power source is brought to the end of the spiral located at the inlet pipe, which leads to the flow of water I through conduit intersects the magnetic field lines, and in water as a moving conductor induced emf, proportional to the square of the magnetic field and the velocity of intersection, i.e. the flow of water and its speed. This EMF is removed from the electrodes and fed to the relay coil. In this case, the sensor practically does not affect the water pressure, and the sensor is controlled separately from the water, i.e. simplified heater control, and hence the electrical safety of its operation.

 The risk of overheating is reduced by a simple temperature sensor in design. It prevents the possibility of breakdown of insulation during overheating of the water, and therefore increases the electrical safety and reliability of the proposed electric heater.

 In FIG. 1 shows the design of an electric heater, a general view showing, for simplicity, two electric heating sections and their connection to each other; in FIG. 2 section of a tape corrugated heating element in isometry; in FIG. 3 is a schematic illustration of a water pressure sensor, the electrodes of which are connected to the winding of the first relay; in FIG. 4 shows the connection of an electric heater to a power source.

In accordance with FIG. 1, the proposed electric heater may contain several identical electric heating sections 5 _1-n , the connection of which in series forms a single module having a housing 1 with a water supply pipe 2, which can be located, for example, at one of the ends of the housing, a cover 3 with a discharge pipe 4, in front of one of the nozzles, for example, a supply one, a water pressure sensor 6 is installed, while on the nozzles on the outside there are metal grids 7.8, and on the case 1 and on the cover 3 from opposite sides the electric Cylinder bolts 9, 10 mounted with sealing gaskets 11, 12 for supplying a power supply voltage to the heating elements of the first and last sections. As the material of the housing 1 and the cover 3, for example, heat-resistant plastics such as AG-4C can be used.

The electric heating sections 5 _1-n are placed along the axis of the housing along its entire length, with each section consisting of two spirals made of thin corrugated along two coordinate axes with the formation of beads of an electrically conductive tape with a double-sided electrical insulation coating, on which an additional metal layer is applied, for example by spraying, and an anticorrosive coating on it (Fig. 2).

As the material of the tape, as well as an additional metal layer, stainless steel, heat-resistant steel, type 1 x 18H9T, 0.01-0.05 mm thick, allowing deep stretching of the corrugations, coated on both sides with an elastic insulating coating, for example, a 4 MD fluoroplastic suspension, can be taken 10-15 microns thick with a working temperature of 200 ^о С and electric resistance ρ 10 ¹² -10 ¹³ Ohm˙ m.

 As a corrosion-resistant coating, a dielectric material can be used. Between the turns of the spiral heating element of the sections, an insulating pad is placed, for example, of a fiberglass mesh (fabric) with high heat resistance and low hydraulic resistance.

The corrugations in the form of bullets of adjacent layers of the electrically conductive tape of the heating elements of the sections, arranged in a checkerboard pattern, form flow channels of large cross section with small hydraulic resistance between the coils of the spiral with turbulators of the water flow, intensifying the heat transfer process between the electric heating elements of the sections and running water. In each electric heating section, the inner ends of each of the two spirals are attached (for example, welded) to metal axial rods 13, 14 having screw threads on both sides. The outer ends of the spirals are attached (also, for example, by welding) to the rod 15, mounted on a dielectric strip 16 with through holes. Between the spirals, the axial rods of both spirals are interconnected by a dielectric coupling 17. The spiral rods of the first electric heating section 5 _{1 are} connected to the output of the bolt 9 through the metal coupling 18, and to the next section through the metal coupling 19, and the spiral rods of the last section 5 _{n are} connected to the output of the bolt 10 through a metal coupling 20. The surfaces of the rods and metal couplings are insulated from water by a heat-resistant dielectric layer. The cover 3 is connected to the housing 1 by screws 21 through a sealing gasket 22. The screws 21 are grounded and connected to a metal layer deposited on a spiral.

A water pressure sensor made in accordance with FIG. 3 and based on a flowmeter of the IR, RI Induction series, for example, IR-51, IR-61, contains a pipe 24, which, like a sleeve, is screwed onto one of the nozzles (in FIG. 1 to the inlet) between the first section of the electric heating element and the protective metal mesh 7. The conduit 24 (sleeve) is arranged between the poles of the electromagnet 25. in the conduit 24 are arranged in one cross-section with poles of the electromagnet, but at an angle of ⁹⁰ ° to the direction of magnetic force lines of the electrodes 26 connected to the first winding of the polarized relay 27. to provide For normal operation, the electrodes are isolated from the walls of the sleeve 24, and the inner surface of the sleeve 24 is isolated from water at a sufficient distance (up to three diameters of the sleeve) on both sides of the electrodes. The armature of the relay 28, retracting, closes the contacts of the relay 29, including the phase of the voltage of the power source to the heating element (figure 4).

 The temperature sensor 23 is installed in front of the outlet pipe and is connected to the winding 30 of the second relay. The sensor can be made, for example, based on a thermistor included in the base circuit of a transistor switch, the collector load of which is the winding of the second relay. The contacts 31 of the second relay are connected in series with the contacts 29 of the first relay to the voltage phase of the power source of the electric heater.

 Electric heater operates as follows.

When the water pressure entering through the inlet pipe 2 reaches a threshold value, the emf induced in the water is removed by two electrodes 26 of the water pressure sensor 6. The current from electrode to electrode is closed through the winding of the polarized relay 27. The armature of the relay 28 is drawn in and closes the contacts of the relay 29, including the voltage phase of the power source to supply it to the end of the spiral of the first electric heating section 5 ₁ . The flow of water passing between the coils of a heated heating element uniformly over the entire surface of the spiral heating element becomes turbulent due to the presence of bubbles, which leads to an intensification of the process of heat transfer from the heating element to running water, and the temperature of the heating element decreases at a given electric power of the electric heater. If the water flow in the electric heater decreases to a threshold value, the contacts of the water pressure sensor relay open and disconnect the voltage of the power source.

 The water temperature sensor 23 operates as follows.

 When the water temperature rises above a threshold value, the resistance of the thermistor included in the base circuit of the transistor switch changes, the latter trips and opens the contacts of the second relay 31, the winding 30 of which is included in the collector circuit of the transistor key. The contacts of the second relay, opening, disconnect the phase of the voltage of the power source from the heating element, and the heating of the water stops until its temperature drops below the threshold value.

Claims (1)

ELECTRIC WATER HEATER, comprising a sealed housing with inlet and outlet pipes and an electric heating section placed in it with a heating element made in the form of a corrugated along two coordinate axes, rolled into a spiral of an electrically conductive tape with a coating on the surface, the ends of the tape are designed to connect to a power source, characterized the fact that it is equipped with at least one additional electric heating section, identical to the main, while electrically conductive These sections are interconnected in series, a metal layer with a corrosion-resistant coating is applied to their electrical insulation coating, the metal layer being grounded, and the tapes are connected to the power source so that its zero phase is connected to the end of the spiral located at the outlet pipe, and the voltage phase is the contacts of the introduced first relay and the contacts of the input of the second relay connected in series are connected to the end of the spiral located at the inlet pipe, the winding of the first relay keys to input transducer water pressure established in the supply pipe and adapted on the basis of an electromagnetic flowmeter comprising a conduit electromagnet with poles around the conduit and the electrodes are disposed in one cross-section with poles of the electromagnet and at 90 ^o to the direction of magnetic lines of force, and the winding the second relay is connected to the entered temperature sensor installed in front of the outlet pipe.

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