RU189233U1 - THERMAL ACCUMULATOR OF PHASE TRANSITION WITH INDUCTION ELECTRIC HEATING DEVICE - Google Patents

Abstract

The utility model relates to the field of transport engines, in particular, to devices for pre-thermal preparation of an internal combustion engine (ICE) at negative ambient temperatures. The thermal accumulator of a phase transition with an inductive electric heating device consists of an outer case of a dielectric material and an inner case separated from it by thermal insulation of a dielectric material, inside which are placed metal cylindrical TAM capsules, the inlet and outlet are located at the end, and the covers are dielectric the material on which the power supply is located, and the winding of the induction device of electric heating is located equally pno on the surface of the outer casing of a dielectric material. The technical result is achieved by replacing the self-regulating heating elements on the posistor ceramics on an inductive electric heating device, the winding of which is evenly located on the surface of the battery. The technical result of the claimed thermal accumulator of a phase transition with an induction device of electric heating is to reduce energy consumption for the operation of the heating elements and ensure fast and uniform heating of TAM. 1 il.

Description

The proposal relates to the field of transport engine, in particular to devices pre-thermal preparation of an internal combustion engine (ICE) at negative ambient temperatures.

The heat accumulator of phase transition is known (Patent of the Russian Federation 2187049 С1, IPC F24H 7/00, publ. 10.08.2002, Bull. No. 22) consisting of a heat-insulated evacuated cylindrical body, removable cover, inlet and outlet openings. The inlet and exhaust pipes are pressed into these holes. Inside the case there is a heat exchanger consisting of coaxially arranged cylindrical capsules. Capsules are filled with heat storage material (TAM). The heat exchanger is mounted on a removable cover with a bolted connection and welded to the body.

The disadvantage of this thermal accumulator of the phase transition is the inability to maintain the required coolant temperature for a long period of time with the engine inoperative (turned off) at low ambient temperatures.

The closest in technical essence and achievable technical result to the declared thermal phase transition accumulator with induction electric heating device is a thermal phase transition accumulator with self-regulating electric heating device (Patent RU No. 2506503, C1, IPC F24H 7/00, published 10.02.2014, Byul. No. 4.), consisting of outer and inner buildings with thermal insulation between them, cylindrical TAM capsules, inlet and outlet nozzles, covers made of dielectric material, removable covers, self-regulating They are heating elements on the posistor ceramics and the body of the heating element.

The disadvantage of this thermal accumulator of a phase transition with a self-regulating electric heating device is a significant energy cost for the operation of heating elements on posistor ceramics and the low efficiency of the proposed heating design using self-regulating heating elements on posistor ceramics which do not allow for fast and uniform heating of TAM cylindrical capsules.

The technical result of the claimed thermal accumulator of a phase transition with an induction device of electric heating is to reduce energy consumption for the operation of the heating elements and ensure fast and uniform heating of TAM.

The technical result is achieved by replacing the self-regulating heating elements on the posistor ceramics on an inductive electric heating device, the winding of which is evenly located on the surface of the battery.

The proposal is illustrated in the figure, which shows a diagram of a thermal accumulator of a phase transition with an inductive electric heating device.

The claimed heat accumulator of a phase transition with an inductive electric heating device comprises an outer case of dielectric material 1 and an inner case of dielectric material 3 separated from it by thermal insulation 2, inside which are placed metal cylindrical capsules 4 with TAM, separated by slit gaps 5, inlet end pipe 6 and the outlet 7, while the cover of the dielectric material 8, which is the input power supply 9, by means of a bolt connection 10 is attached to the outer case of a dielectric material 1, on the surface of which the winding of the electric induction heating device 11 is evenly positioned.

The claimed thermal battery phase transition with induction electric heating device works as follows.

The accumulation of heat by the phase accumulator by the heat transfer occurs during the operation of the internal combustion engine due to the heat exchange of its coolant with metal cylindrical capsules 4 with TAM.

The coolant is supplied through the inlet 6, passes through the gap gaps 5 and is discharged through the outlet 7. At the same time, the TAM is heated in the solid phase to the melting temperature, melts, and then is heated in the liquid phase to the temperature at which thermal equilibrium occurs between it and the coolant .

When the engine is off, the heat accumulation of the phase transition of heat is due to the short-term supply of current through the input power supply 10 (from batteries or an external source of electrical current) to the winding of the induction electric heating device 11, which creates an alternating electromagnetic field that transfers the energy into the electrically conductive body without contact which uses metallic cylindrical capsules 4 with TAM.

Claims (1)

Thermal accumulator of phase transition with induction electric heating device, consisting of an outer casing of dielectric material and separated from it by thermal insulation of the inner casing of dielectric material, inside which are placed metal cylindrical TAM capsules, inlet part and there are covers the dielectric material on which the power supply is located, characterized in that the winding of the induction device of electric heating Laga uniformly over the surface of the outer housing of dielectric material.

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