UA23333U - Electrolytic heater for liquid - Google Patents

Abstract

The proposed electrolytic heater for liquid contains a metallic tubular casing, which is used as the first electrode, the second metallic electrode, which is installed in the hole of the casing cover and insulated from the cover, and additionally, an expansion vessel. The casing is filled with electrolyte. As the electrolyte, low-concentrated aqueous solution of ion-forming chemical substance. The lower parts of the casing and the expansion vessel are coupled by a tube. The upper part of the expansion vessel is open to the atmosphere.

Description

Description of the invention

The useful model refers to the design of electrolytic heaters, which are intended for the equipment of 2 flow-through small-sized water heating boilers and/or water heat accumulators, which are used in hot water supply and heating systems mainly in detached residential and public buildings and production premises of small enterprises. In addition, these heaters can be used as part of arbitrary heaters of various technological liquids (in particular, dye solutions and washing solutions during dyeing of textile materials, acidic environments for pickling the surfaces of 70 metal products, etc.), as well as part of flow devices for pasteurization of such food products , such as milk, cream, milkshakes, fruit and/or vegetable juices.

It is now common knowledge that in countries with developed thermal and/or nuclear power, there are at least double tariffs for electricity and that the so-called "night" tariff is significantly lower than the daytime tariff. Therefore, in many houses, water accumulators equipped with electric heaters are used, which accumulate heat 72 at night, and give it away during the day during the circulation of water as a heat carrier through a closed heating system.

To heat water or another liquid, resistive electric heaters are most often used (See, for example, "Polytechnic Dictionary". - M.: "Sovetskaya Zncyclopedia", 1976, article "Zlectricheskii nagrev", p. 575).

Indeed, the direct conversion of electrical energy into heat provides almost 10095 k.k.d. But the most common in modern technology electric heaters with solid resistive elements, which are usually made of expensive nichrome, are increasingly replaced by heaters with liquid resistive elements, which are served by low-concentrated aqueous solutions of cheap and widely available ion-forming chemical compounds (for example, salts).

The electrolytic heater closest in technical essence to the one proposed below is known from the technical description and operating instructions for devices of the type "Heat accumulators, boilers, water heaters AT-VK", which were developed in

by the Western Regional Association "ECOBUTECH" (Novodnistrovsk, Ukraine). Such a heater (called a "steam-electric cartridge" in the mentioned Instructions) has: - a hermetic metallic tubular body, which serves as the first electrode and has a cover with a through hole, o - a second rod metal electrode, which is fixed in the hole of the specified cover of the body and electrically "95 isolated from it, and - a liquid resistor in the form of a low-concentration aqueous solution of at least one ion-forming chemical compound, which is poured into the specified hermetic housing (which will be abbreviated as "liquid resistor" in the future if necessary). 3o In the known design of the electrolytic heater, the liquid resistor fills the tubular body by approximately 1/10 of its volume. This allows you to create a cyclic process of evaporation of water in the lower part of the case and condensation of water vapor in its upper part inside the hermetic case with heating of water or other liquid medium that fills the boiler or other closed or flow-through heating device. "

However, during such heating (especially in the case of violations of heat removal from the liquid resistor), supercritical increases in the pressure of water vapor inside the sealed housing and, sometimes, even electrolysis of water with the formation of explosive hydrogen are possible. Partial filling of the specified case with a liquid resistor is not

"Iz" gives a full guarantee of safe operation of electrolytic heaters. This forces the manufacturers of the equipment in which these heaters are used to equip their products with complex and expensive temperature control systems and regulation of the operating current.

Therefore, the basis of a useful model is the task of creating such an electrolytic liquid heater, which would be safe in operation by itself, by relieving the cavity of the sealed housing from excess pressure.

This problem is solved by the fact that the electrolytic liquid heater, which has: o - a sealed metallic tubular body that serves as the first electrode and has a cover with a hole,

Ge) 20 - the second rod metal electrode fixed in the opening of the specified cover of the housing and electrically isolated from it, and c" - a liquid resistor in the form of a low-concentration aqueous solution of at least one ion-forming chemical compound poured into the specified hermetic housing, according to the inventive concept, additionally equipped with an expansion vessel, the bottom part of which is connected by a branch pipe to the cavity 25 of the specified housing, filled with the specified liquid resistor, and the upper part is connected to the atmosphere. c Even in cases where the sealed body of such an electrolytic heater will be completely filled with a liquid resistor in the initial position, the increase in the volume of this conductive liquid due to heating is automatically compensated by the flow of part of the liquid to the expansion vessel. If the heating of the liquid resistor will be accompanied by excessive evaporation of water (and even more so, its slow partial electrolysis), the gaseous products of these undesirable processes will be able to freely escape to the atmosphere through the expansion vessel, which will work as a bubbling liquid valve.

The first additional difference is that said hermetic housing is completely filled with a liquid resistor, and the discharge pipe is connected to the cavity of this housing in its upper part. This is desirable from the point of view of rapid and uniform heating of the tubular body after supplying power to the heater. for A second additional difference is that said hermetic housing is partially filled with a liquid resistor, and the outlet pipe is connected to the cavity of this housing in its lower part. This is desirable from the point of view of saving costs of the liquid resistor and creating a reserve volume directly in the tubular housing.

A third additional difference is that said rod electrode has an electrical insulating coating on top. This is desirable from the point of view of using relatively cheap easily replaceable aluminum wires for the manufacture of rod electrodes.

The fourth additional difference is that the specified sealed housing is equipped with a filling nozzle with a closing element. This makes it easy to initially fill the case with liquid resistor, empty the 7/0 Case, or add liquid to it.

Next, the essence of the useful model is explained by a detailed description of the design and operation of the proposed device with references to the drawings, which are shown in Fig. 1 - the proposed electrolytic liquid heater, completely filled with a liquid resistor (longitudinal section); Fig. 2 - dependence of the current flowing through the electrolytic heater on the temperature; Fig. 3 - the proposed electrolytic liquid heater, partially filled with a liquid resistor (longitudinal section).

An electrolytic liquid heater in any form of execution (see figures 1 and 3) has: - a hermetic metallic tubular body 1, which serves as the first electrode and has a cover 2 with a specially marked through hole, not 2o, - a second rod (mostly solid, but a thin tubular) metal electrode 3, fixed in the opening of the cover 2 of the housing 1 and electrically isolated from it, is a liquid resistor 4, namely a low-concentration aqueous solution of at least one ion-forming, predominantly alkaline chemical compound (for example, hydrogen carbonate or sodium carbonate), which is filled in the body 1, - and the expansion vessel 5, the bottom part of which is connected by a branch pipe 6 to the cavity of the body 1, filled with a liquid resistor 4, and the upper part is connected to the atmosphere (usually through a droplet filter, not shown).

As a rule (Fig. 1), the housing 1 is completely filled with a liquid resistor 4, and the outlet pipe 6 is connected to the cavity of this housing 1 in its upper part. But the specified hermetic housing 1 can be filled (U with a liquid resistor 4 only partially (Fig. 3). Then it is advisable to connect the outlet pipe 6 to the cavity of the housing 1 in its lower part. o

Rod metal electrode C can have an electrical insulating coating 7 in the upper part (Fig. 1). It is also advisable that the housing 1 is equipped with a filling nozzle 8 with a closing element 9.

A person skilled in the art will understand that both of the above electrodes are equipped with not particularly suitable means, not shown, for connection to a suitable power source, which is usually served by a domestic or industrial alternating current network as such or with an intermediate step-down transformer, and that for fixing in the cover 2 of the housing 1 or the coating of the rod electrode C can be used well-known fluoroplastic, high molecular weight polyvinyl chloride, polycarbonate or other suitable electrical insulating materials.

The described heater works as follows. "

The electric current flowing in the circuit "rod metal electrode C - liquid resistor 4 tv) c - tubular housing 1, heats the liquid resistor, the electrical resistance of which increases with increasing temperature with a corresponding drop in current and power consumption (Fig. 2). ;" Next, the heat from the heated liquid resistor 4 heats the tubular body 1 and from its outer wall heats either water (for example, in a heat accumulator included in a closed circuit for heating domestic or industrial premises, or in a flow water boiler), or another liquid medium.

GI The excess of the liquid resistor 4, which is formed due to its thermal expansion in the heaters according to Fig. 1 or due to the partial evaporation of water, flows from the cavity of the housing 1 through the outlet pipe 6 o to the expansion vessel 5. At the same time, the excess of water vapor, not absorbed in this vessel 5, can go out to the atmosphere without any additional regulation.

If the volume of the liquid resistor 4 and/or the pressure in the cavity of the housing 1 decreases as a result of cooling, a part of the liquid returns from the bottom part of the expansion vessel 5 to the housing 1. 4) It is natural that the given examples of the constructive implementation of the inventive idea and the specified technological possibilities are not exhaust all aspects of industrial application of the proposed heater.

Claims (1)

The formula of the invention p 1. An electrolytic liquid heater, which has a hermetic metallic tubular body, which serves as the first electrode and has a cover with a hole, a second rod metal electrode, which is fixed in the hole of the specified body cover and is electrically isolated from it, and a liquid resistor in the form of poured into the specified a hermetic housing of a low-concentration aqueous solution of at least one ion-forming chemical compound, which is characterized by the fact that it is additionally equipped with an expansion vessel, the bottom part of which is connected by a discharge pipe to the cavity of the specified housing filled with the specified liquid resistor, and the upper part is connected to the atmosphere. 65 2. An electrolytic heater according to claim 1, which is characterized by the fact that said hermetic housing is completely filled with a liquid resistor, and the outlet pipe is connected to the cavity of this housing in its upper part. C. An electrolytic heater according to claim 1, characterized in that said hermetic housing is partially filled with a liquid resistor, and the discharge pipe is connected to the cavity of this housing in its lower part. 4. Electrolytic heater according to claim 2 or claim 3, which is characterized by the fact that the specified rod electrode has an electrical insulating coating in the upper part. 5. An electrolytic heater according to claim 2 or claim 3 or claim 4, which is characterized by the fact that the specified hermetic housing is equipped with a filling nozzle with a closing element. that 2 (ze) (ze) (ze) (ze) p - and? name) (95) (95) (95) syu" 60 b5