RU135475U1 - CARBON ELECTRIC HEATING DEVICE - Google Patents

Abstract

1. A carbon electric heating device comprising an electric heating unit with an electrically conductive carbon element, located in the housing of the heating device between its inlet and outlet, an electric current source connected to the carbon element, and a means for preventing its overheating and destruction is installed in the electric circuit of the carbon element, made in the form of a posistor, characterized in that the electric heating unit includes end stops, between which are located depending on the type of electrical parallel, serial or parallel-serial connection in alternating order of conductive and dielectric plates, between which there is a specified conductive carbon element made in the form of pieces of carbon material interconnected by conductors, these pieces of carbon material, conductive and dielectric plates, and end stops are arranged in an electric heating unit by means of fixation, moreover, in contact with said dielectric plates are installed with end stops, wherein said carbon element is coated with insulating materials, and its specific resistance of the carbon element depending on the passing mass of the heated liquid or air medium is set to limit the temperature of the carbon element to the operating parameters of its insulating coating material, moreover, the contact point of the carbon element and the supply voltage conductor is coated with a layer of waterproof dielectric

Description

The utility model relates to electrical engineering, in particular to electrical devices with a hydrocarbon resistor for heating liquid and gaseous media, and can be used both independently for heating greenhouses, residential and industrial premises, and as part of other devices and air heaters.

Carbon (carbon heaters appeared more than half a century ago, the technology was constantly improving: at first the filaments were carbon, they were insulated with polymers to achieve reliability and durability of the heater. Mass production of carbon heaters began after the introduction of an electrically conductive fabric (tape) instead of a carbon filament. Further efforts of the developers were directed to improving the quality of the carbon heater and its fire safety.

The main advantages of a carbon heater: profitability; long terms of operation; high heat dissipation; reliability; low heat capacity; high efficiency; ease of installation; compactness; fast heating; lack of additional service. Carbon heater provides 25% energy savings compared to other types of heating

In addition, a carbon heater has commercial value - carbon as an electric heater is much more efficient than a metal electric heater, because in metals, the resistance of the crystal lattice (a quantum-mechanical quantity directly proportional to the mass of the atom of the lattice) to the motion of thermal electrons is much higher than the resistance of graphite cells.

Therefore, in metal heaters, thermal electrons (the very ones that heat the material) lose a lot of energy to overcome the lattice resistance. Consequently, to heat carbon with electric current, it is necessary at times less energy than would be required for heating the metal. Or, when consuming 1 kWh of energy, a carbon heater will produce 3-6 times more heat than a heater with a metal resistor.

However, the use of a carbon tape as a heater also has drawbacks due to the fact that: the tape ignites at temperatures of about 300-400 degrees, and at temperatures below 300 (starting from 100) it partially breaks down due to the interaction of the tape material (100% carbon ) with atmospheric oxygen, the tape is unsafe during operation, as being energized, can cause electric shock, the tape is mechanically unstable, is destroyed by the slightest mechanical impact.

A carbon electric heating device is known, comprising an electric heating unit with an electrically conductive carbon element located in the housing of the heating device between its input and output, an electric current source connected to the carbon element, and a means for preventing its overheating and destruction established in the electric circuit of the carbon element in the form of a posistor (patent RU2007609, C1, IPC 5 F02M 31/12, 12/26/1990).

This technical solution is the closest to the invention, therefore, taken as a prototype.

The disadvantages of the prototype are the low operational and functional capabilities due to the use of body parts as conductors and the inability to heat gaseous media, as well as the complexity of maintenance and repair.

The technical result of the utility model is the expansion of operational and functional capabilities due to the electrical insulation of the current-carrying elements of the electric heating unit from the body parts of the device and the possibility of heating gaseous media, as well as simplifying maintenance and repair.

Below are the general and particular essential features characterizing the causal relationship of the utility model with the specified technical result.

Carbon The electric heating device comprises an electric heating unit with an electrically conductive carbon element located in the housing of the heating device between its input and output from it, an electric current source connected to the carbon element. A means of preventing its overheating and destruction, made in the form of a posistor, is installed in the electrical circuit of the carbon element. The electric heating unit includes end stops, between which, depending on the type of electrical parallel, serial or parallel-serial connection, conductive and dielectric plates are alternately arranged, between which is placed the electrically conductive element made in the form of pieces of carbon material interconnected by conductors . The indicated segments of carbon material, conductive and dielectric plates, and end stops are arranged in an electric heating block by fixing means. In contact with said end stops, dielectric plates are installed, said carbon element is coated with insulating materials, and its specific resistance of the carbon element depending on the passing mass of the heated liquid or air flow is set to limit the temperature of the carbon element to the limits of the operating parameters of its insulating coating material. The contact point of the carbon element and the supply voltage conductor is coated with a layer of waterproof dielectric. Means for fixing the electric heating block are made in the form of longitudinal rods with riveted ends, passed through a dielectric sleeve passing through coaxial holes in pieces of carbon material, conductive and dielectric plates, and end stops. Means for fixing the electric heating block are made in the form of longitudinal threaded rods with nuts, inserted inside a dielectric sleeve passing through coaxial holes in segments of carbon material, conductive and dielectric plates, and end stops. Means for fixing the components of the electric heating block are made in the form of adhesive joints. The conductors of these conductive plates are made in the form of conductive jumpers connected to the ends of these segments of carbon material. These conductive plates have at one end a split grip mating with the end of a piece of carbon material having a corresponding shape placed in respective holes of the dielectric plates located in contact with each other., And the other ends of the conductive plates are interconnected by conductors in the form of jumpers, depending on the type of connection. As the carbon element, a flat ribbon or a tow is used, or the carbon element is made of threads. To heat the air, the device is equipped with a fan for its supply. To heat the air, the device is made in the form of a mounted, wall or floor type convector, with the supply holes located in its lower side of the housing, and the exhaust holes made in its upper part. The segments of the carbon element are electrically connected to each other in parallel, in series or in parallel-in series with the connection of the end segments with a power source. As the insulation of the carbon element can be used; fluoroplastic impregnation; ceramic coating; silicone materials; thermo-electrical insulating varnishes and paints or polymer compositions.

The utility model is illustrated by drawings, where in Fig.1 shows a diagram of a device for heating a liquid; figure 2 in figure 1 presents a diagram of a device for heating air with forced supply; figure 3 presents a diagram of a device for heating air by convection; figure 4 is a longitudinal section of the device of figure 1; figure 5 is a view aa in figure 4; figure 6 is a front view of figure 5; Fig.7 is a view aa in Fig.4, an embodiment; Fig.8 is a top view of Fig.5; figure 9 is a top view of figure 7; figure 10 is a plate with holes in figure 5, a longitudinal section; figure 11 is a plate of figure 10, front view; in Fig.12 is a view bB in Fig.11 and Fig.12; in Fig.13 - a plate without holes in Fig.7, a longitudinal section; on Fig - plate Fig, front view; in Fig.15 is a longitudinal section of the device of Fig.3; in Fig.16 is a longitudinal section in Fig.5 with plates connected by conductors; on Fig - view BB in Fig; on Fig.18 view GG in Fig.17, top with side rods in Fig.17, top and bottom with a Central rod lower projection in Fig.17; in Fig.19 is a view of GG in Fig.17, a variant of the plates without holes; in Fig.20 - electric heating unit, an option for connecting conductors; in Fig.21 is a variant of the carbon element in Fig.20; in Fig.22 is a variant of the conductor of Fig.20; on Fig - parallel connection of carbon elements; in Fig.24 is the same circuit diagram; on Fig - serial connection of carbon elements; Fig.26 is the same circuit diagram; on Fig - parallel-serial connection of carbon elements; in Fig.28 is the same circuit diagram.

The carbon electric heating device comprises an electric heating unit 1 with an electrically conductive carbon element 2, located in the housing 3 of the heating device between its input 4 and output 5 from it, an electric current source 6 with a control unit 7 connected to the carbon element 2.

In the electrical circuit of the carbon element 2 there is installed a means of preventing its overheating and destruction, made in the form of a posistor 8. The electric heating unit 1 includes end stops 9 between which, depending on the type of electrical parallel, serial or parallel-serial connection, conductive 10 and dielectric 11 plates, between which the indicated conductive carbon element 2 is placed, made in the form of segments 12 of carbon mater ala interconnected by conductors 13.

These segments 12 of carbon material, conductive 10 and dielectric 11 plates, and end stops 9 are arranged in an electric heating unit by means of fixation.

In contact with the specified end stops 9 are installed dielectric 11 plates.

The specified carbon element 2 is made with a coating of insulating materials, and its specific resistance of the carbon element depending on the passing mass of the heated liquid or air medium is set to limit the temperature of the carbon element by the operating parameters of its insulating coating material. The contact point of the carbon element 2 and the conductor 14 for supplying voltage is covered with a layer of waterproof dielectric.

Means for fixing the electric heating block can be made in the form of longitudinal rods 15 with riveted ends, passed through a dielectric sleeve 17 passing through coaxial holes in segments 12 of carbon material, conductive 10 and dielectric 11 plates, and end stops 9.

Means for fixing the electric heating block can also be made in the form of longitudinal threaded rods 18 with nuts 19, passed inside the dielectric sleeve 17 passing through the coaxial holes in the segments 12 of the carbon material, conductive 10 and dielectric 11 plates, and end stops 9.

Means for fixing the components of the electric heating block are made in the form of adhesive joints.

The conductors of these conductive plates can be made in the form of conductive jumpers 13 connected to the ends of these segments 12 of carbon material.

Said conductive plates 10 may have a split grip 20 at one end that is conjugated to the end 22 of a carbon material segment having a corresponding shape placed in respective holes of the dielectric 11 plates located in contact with each other., And the other ends of the conductive 10 plates are interconnected conductors in the form of jumpers 13 depending on the type of connection.

As the carbon element 2 can be used: a flat tape or bundle, or the carbon element is made of threads.

To heat the air, the device is equipped with a fan 23 for its supply. To heat the air, the device can be made in the form of a mounted, wall or floor type convector on supports 24, with the supply holes 25 located in its lower side of the housing 26, and the exhaust holes 27 made in its upper part.

The segments 12 of the carbon element 2 are electrically interconnected in parallel (FIG. 23, FIG. 24), in series (FIG. 25, FIG. 26) or in parallel-series (FIG. 27, FIG. 28) with connecting the end segments to a power source .

A carbon electric heating device can be inserted into the section of the pipeline and tightly connected by the electric heating unit 1 in sections 4 and 5 of the pipeline, while the joint between them can be sealed with couplings 28.

As the insulation of the carbon element can be used; fluoroplastic impregnation; ceramic coating; silicone materials; thermo-electrical insulating varnishes and paints or polymer compositions.

Comparison of the claimed technical solution with the prior art known from the scientific, technical and patent documentation as of the priority date in the main and related sections did not reveal a tool that has features identical to all the features contained in the utility model proposed by the applicant, including the purpose of use. That is, the set of essential features of the claimed solution was not previously known and is not identical to any known technical solutions, therefore, it meets the patentability condition of “novelty”.

This technical solution is industrially applicable, since its purpose is indicated in the description of the application and the name of the utility model, it can be manufactured industrially and used as a heater for liquid and gaseous media.

The technical solution is workable, feasible and reproducible, and the distinctive features of the device allow to obtain the desired technical result - the expansion of the functional and therapeutic capabilities by spreading the induction effect of current pulses on the mass volume of the biological object due to the closed cycle, i.e. are significant. The utility model in the form as described in each of the claims can be implemented using the tools and methods described in the prototype, which became public until the priority date of the utility model.

Therefore, the claimed technical solution meets the condition of patentability "industrial applicability".

The device is implemented as follows.

The carbon electric heating device is assembled manually or automatically, and the simplicity of the design provides low-cost assembly in a fully automatic way,

During assembly, constant compliance with any parameters is not required - tension, distance; or some kind of adjustment - tuning operations (expensive, using artificial intelligence).

The assembled device can be of any geometric size and have any specified physical parameters - power supply parameters, resistance, power, specific power per unit area, operating environment parameters, without violating the integrity of the idea in the framework of this description.

The assembled heating block is subjected to processing (processes of applying electrical insulating and other coatings).

It is mounted in the device designed according to the assembly task.

It is used in any device for heating liquids or gases (including air) in accordance with specified parameters - dimensions, power, power supply parameters, etc.

Using the utility model allows:

- unify products for a wide range of applications;

- to establish low-cost production (low-cost products) of heaters with high performance

- receive serial products with constant (in the mass of batches from 10 to 1,000,000 pcs) with predetermined characteristics in a huge range of sizes and operational characteristics with a minimum error due to the design of the product.

Build technology allows.

- unify the assembly line for the manufacture of products of different sizes - no significant change (or no requirement) of the line is required - i.e. line for assembling blocks 6x6 = lines for assembling blocks 60 × 60 = lines for assembling blocks 6 × 600.

- to simplify as much as possible the methods of calculating the physical parameters of the product for the given parameters - due to the simplicity of the design

- to receive a product that is easily integrated into any device - due to the small size and high mechanical strength characteristics of the unit.

- the ability to use this type of heaters in devices of any size and power (microscopic - and heating grains and heating water in the boiler room).

- the reliability of the device is much higher than analogues;

- the service life is much higher than analogues;

- the ratio of energy consumption / energy efficiency in comparison with analogues is currently the highest.

Claims (19)

1. A carbon electric heating device comprising an electric heating unit with an electrically conductive carbon element, located in the housing of the heating device between its inlet and outlet, an electric current source connected to the carbon element, and a means for preventing its overheating and destruction is installed in the electric circuit of the carbon element, made in the form of a posistor, characterized in that the electric heating unit includes end stops, between which are located depending on the type of electrical parallel, serial or parallel-serial connection in alternating order of conductive and dielectric plates, between which there is a specified conductive carbon element made in the form of pieces of carbon material interconnected by conductors, these pieces of carbon material, conductive and dielectric plates, and end stops are arranged in an electric heating unit by means of fixation, moreover, in contact with said dielectric plates are mounted on the end stops, wherein said carbon element is coated with insulating materials, and its specific resistance of the carbon element depending on the passing mass of the heated liquid or air medium is set to limit the temperature of the carbon element to the operating parameters of its insulating coating material, moreover, the contact point of the carbon element and the supply voltage conductor is coated with a layer of waterproof dielectric I trick. 2. The carbon electric heating device according to claim 1, characterized in that the fixing means for the electric heating block are made in the form of longitudinal rods with riveted ends, passed through a dielectric sleeve passing through coaxial holes in pieces of carbon material, conductive and dielectric plates and end stops. 3. The carbon electric heating device according to claim 1, characterized in that the fixing means of the electric heating block are made in the form of longitudinal threaded rods with nuts passed through a dielectric sleeve passing through coaxial holes in pieces of carbon material, conductive and dielectric plates and end stops. 4. The carbon electric heating device according to claim 1, characterized in that the means for fixing the components of the electric heating unit are made in the form of adhesive joints. 5. The carbon electric heating device according to claim 1, characterized in that the conductors of said conductive plates are made in the form of conductive jumpers connected to the ends of said segments of carbon material. 6. The carbon electric heating device according to claim 1, characterized in that said conductive plates have at one end a split grip associated with the end of a piece of carbon material having a corresponding shape, placed in respective holes of the dielectric plates located in contact with each other, and the other ends of the conductive plates are interconnected by conductors in the form of jumpers, depending on the type of connection. 7. The carbon electric heating device according to claim 1, characterized in that a flat strip is used as the carbon element. 8. The carbon electric heating device according to claim 1, characterized in that a tow is used as the carbon element. 9. The carbon electric heating device according to claim 1, characterized in that the carbon element is made of threads. 10. The carbon electric heating device according to claim 1, characterized in that for heating the air, the device is equipped with a fan for supplying it. 11. The carbon electric heating device according to claim 1, characterized in that for heating the air, the device is made in the form of a mounted, wall or floor type convector, and the supply holes are located in its lower side of the housing, and the outlet holes are made in its upper part. 12. The carbon electric heating device according to claim 1, characterized in that the segments of the carbon element are electrically connected to each other in parallel with the connection of the end segments with a power source. 13. The carbon electric heating device according to claim 1, characterized in that the segments of the carbon element are electrically connected to each other in series with the connection of the end segments with a power source. 14. The carbon electric heating device according to claim 1, characterized in that the segments of the carbon element are electrically connected to each other in parallel with the connection of the end segments with a power source. 15. The carbon electric heating device according to claim 1, characterized in that a fluoroplastic impregnation is used as the insulation of the carbon element. 16. The carbon electric heating device according to claim 1, characterized in that a ceramic coating is used as the insulation of the carbon element. 17. The carbon electric heating device according to claim 1, characterized in that silicone materials are used as the insulation of the carbon element. 18. The carbon electric heating device according to claim 1, characterized in that thermoelectrically insulating varnishes and paints are used as the insulation of the carbon element. 19. The carbon electric heating device according to claim 1, characterized in that the polymer composition is used as the insulation of the carbon element.

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