RU147510U1 - DEVICE FOR PRODUCING THERMAL ENERGY FROM ELECTRIC - Google Patents

Abstract

1. A device for generating thermal energy from electrical energy, comprising a heat-removing surface with a heat carrier located inside it and an electric heating element with current-carrying leads fixed to the end wall of the heat-removing surface, characterized in that the heat-removing surface is divided into two compartments, an electric heating element is placed in the lower compartment, made in the form of an infrared emitter surrounded by a heat-accumulating substance, and in the upper compartment there is a coolant whose wavelength go chosen equal to the radiated wavelength of the infrared emitter. 2. The device of claim 1, characterized in that the infrared emitter is made in the form of a single or block design. 3. The device according to any one of paragraphs. 1 or 2, characterized in that the infrared emitter is fixed in the middle part of the end wall of the lower compartment of the heat-removing surface by means of a fitting, gaskets or nipple and union nut. 4. The device according to claim 1, characterized in that the heat-removing surface is made of aluminum, cast iron or steel in the form of a pipe or box of a rectangular, triangular or other closed section without ribbing or with external ribbing of the housing surface. The device according to any one of paragraphs. 1 or 4, characterized in that the external finning of the heat-removing surface is made longitudinal or transverse with partial external thermal insulation of the lower compartment of the heat-removing surface.

Description

The utility model relates to a power system, namely, electric heaters that convert electrical energy into heat, and can be used for autonomous heating of premises as an autonomous local heating device, as well as in industrial apparatus and equipment for various purposes.

A known method of producing thermal energy from electrical energy and a device for its implementation. A device for generating thermal energy from electric energy comprises a housing divided into two chambers - an external and an internal one, equipped with inlet and outlet openings, in which at least one heating device is placed, including an electric heating element connected to a power source, and heat storage substance, and inside made in the form of a space isolated from outside. At the same time, a forced circulation device for a coolant, such as air, is placed on the inlet of the housing along the surface of a heating device, such as a fan. Both cameras are made communicating, the inlet in the housing is opposite the inlet to the inner chamber, and the outlet of the inner chamber serves as an inlet to the outer chamber. The heat-accumulating substance of the heating device includes a solid inside the surface of the electric heating element and gaseous (air) outside the surface of the heating element (patent RF 2151346, F24H 7/00, 7/02, 7/04, publ. 06/20/2000, bull. 17).

The disadvantages of the known device are the inability to regulate power consumption and use for domestic hot water.

A known method and device for producing thermal energy from electrical. An electrostatic apparatus containing a set of alternating current capacitors with a connection circuit providing an individual charge of each capacitor and a simultaneous total discharge per load placed in the thermostat is introduced into the device for receiving thermal energy from electrical energy. The inner chamber (heat-generating zone) and the outer chamber (heat-removal zone) are hermetically isolated from each other. The inlet and outlet openings of the external chamber are either closed to each other outside the device with the formation of a single closed circulation system for the coolant, or open using a flow system (RF patent 2201556, 2001, IPC F24H 1/20, published March 27, 2003).

The disadvantage of this device is the impossibility of their use in other liquid environments, except water.

A known method of producing thermal energy from electrical energy and a device for its implementation Peter's coater.

A device for implementing a method of producing thermal energy from electrical energy contains at least one resistive electric heating element, consisting of a ceramic heating pipe with a hydrophobic protective layer connected to a power source, and a heat storage substance, which is used as a ceramic material isolated from outside the volume space. The ceramic heating pipe consists of a carbon filament with a protective hydrophobic coating and zero water absorption, a monolithic ceramic cylinder with an opening to increase the heat exchange surface and the channel for laying the heating element (RF patent 2455579, IPC F24H 1/10, published on July 10, 2012)

The disadvantage of this device is the long period of primary heating (68-75 minutes), as well as more complicated, compared with standard radiators, manufacturing technology of the proposed device.

The closest in technical essence to the claimed utility model is a vapor-drop heater.

The vapor-droplet heater according to this method comprises a sealed hollow metal casing with nozzles forming a heating chamber filled with a heat-transfer fluid, an electric heating element with current-carrying leads located inside the casing. Moreover, the heating chamber is located obliquely, towards the end wall of the casing with the electric heating element, at an angle to the horizontal on different-sized support posts spaced at the ends of the casing, while the electric heating element fixed in the end wall of the heater casing is placed below the surface of the liquid - heat agent in working condition (RF patent 63038, IPC F24H 1/20, F22B 1/22, publ. 10.05.2007).

The disadvantage of this device is the design complexity associated with the need to use the heating chamber in an inclined position, as well as the high cost of electricity for heating the heat agent,

The external finning of the heat-removing surface is made longitudinal or transverse, with partial external thermal insulation of the lower compartment of the heat-removing surface.

The energy efficiency of the device under consideration consists in the use of a heat carrier and an infrared emitter having an equal wavelength, at which a structural volumetric effect occurs, associated with the resonant response of the heat carrier molecules to the monochromatic infrared radiation of the infrared emitter with the subsequent participation of heterogeneous structuring of the internal state of the coolant.

In this case, the actual release of additional heat due to intermolecular interactions (the effect of the appearance of microclusters) is observed with the preservation of the acquired heterogeneous structure after the device is completely turned off. The value of this additional heat reaches a value of up to ¾ of the total amount of thermal energy generated by the application of the proposed method, which allows to achieve a high level of energy efficiency of the devices.

Since the infrared emitter is surrounded by a heat-accumulating substance in the lower compartment, which maintains a given temperature of the coolant, after it is turned off, the set temperature of the coolant continues to be maintained for a certain time, and after the coolant temperature is reduced to a set value, the time for restarting the infrared emitter is reduced, which leads to savings in energy consumption, leading to increased energy efficiency of the device.

The proposed device is illustrated in the drawing, where in FIG. 1 - schematically presents a General diagram (section) of the device.

A device for generating thermal energy from electric energy comprises a heat-removing surface 1 divided into two vertical compartments. A coolant with a heating chamber (2-6) is placed inside the upper compartment. In the lower compartment 7 there is an electric heating element 8 with current-carrying leads 9 fixed in the end wall 10 of the heat-removing surface 1, the filler and drain pipe, with a plug 11. The electric heating element 8 is fixed on the end wall 10 of the lower compartment 7 with a fitting, gasket or nipple and union nut with an emphasis (not shown in the drawing) The electric heating element 8 is made in the form of an infrared emitter surrounded by a heat-accumulating substance. The wavelength of the coolant is chosen equal to the radiated wavelength of the infrared emitter 8.

The external finning of the heat-removing surface is made longitudinal or transverse, with partial external thermal insulation of the lower compartment of the heat-removing surface.

The energy efficiency of the device under consideration consists in the use of a heat carrier and an infrared emitter having an equal wavelength, at which a structural volumetric effect occurs, associated with the resonant response of the heat carrier molecules to the monochromatic infrared radiation of the infrared emitter with the subsequent participation of heterogeneous structuring of the internal state of the coolant.

In this case, the actual release of additional heat due to intermolecular interactions (the effect of the appearance of microclusters) is observed with the preservation of the acquired heterogeneous structure after the device is completely turned off. The value of this additional heat reaches a value of up to ¾ of the total amount of thermal energy generated by the application of the proposed method, which allows to achieve a high level of energy efficiency of the devices.

Since the infrared emitter is surrounded by a heat-accumulating substance in the lower compartment, which maintains a given temperature of the coolant, after it is turned off, the set temperature of the coolant continues to be maintained for a certain time, and after the coolant temperature is reduced to a set value, the time for restarting the infrared emitter is reduced, which leads to savings in energy consumption, leading to increased energy efficiency of the device.

The proposed device for its implementation is illustrated in the drawing, where in FIG. 1 - schematically presents a General diagram (section) of the device.

A device for implementing the method of producing thermal energy from electrical energy includes a heat-removing surface 1, divided into two vertical compartments. A coolant with a heating chamber (2-6) is placed inside the upper compartment. In the lower compartment 7 there is an electric heating element 8 with current-carrying leads 9 fixed in the end wall 10 of the heat-removing surface 1, a filler and drain pipe with a plug 11. The electric heating element 8 is fixed on the end wall 10 of the lower compartment 7 with a fitting, gasket or nipple and union a nut with a stop (not shown in the drawing) The electric heating element 8 is made in the form of an infrared emitter surrounded by a heat-accumulating substance. The wavelength of the coolant is chosen equal to the radiated wavelength of the infrared emitter 8.

Infrared emitter 8 can be made in the form of a single, or block design. The heat-removing surface 1 can be made of aluminum, cast iron or steel in the form of a pipe or box of a rectangular, triangular or other closed section, without ribbing or with an external ribbing of the surface of the housing. The external finning of the heat-removing surface 1 can be made longitudinal or transverse, with partial external thermal insulation of the lower compartment of the heat-removing surface.

A device for generating thermal energy from electrical energy is as follows.

The heating chamber (2-6) of the housing 1 through the filling and drain pipe with a plug 11 is filled with the estimated amount of coolant.

When you turn on the device in the network, the infrared emitter 8 under the influence of an electric current begins to generate quanta of a given frequency. The quanta obtained from the infrared emitter lead to heating of the heat-removing surface 1 with heating chambers (2-6), as well as the heat carrier. If a gas is chosen as the heat carrier, then since the radiated wavelength of the infrared emitter is equal to the wavelength of the selected gas, a resonance phenomenon begins to form in the gas molecules, which leads to a breakdown of the molecules of the gaseous medium. This gap generates additional heat, which is transferred to the walls of the heat-removing surface 1 with heating chambers (2-6), which is heated to a predetermined temperature in an accelerated mode, which leads to savings in energy consumption. Also, this process leads to an increase in pressure inside the heating chambers 2-6 to the calculated value. Then, the infrared emitter 8 is turned off, but since the infrared emitter 8 is surrounded by a heat-accumulating substance, it continues to maintain a predetermined temperature of the heat carrier after a certain time. Under the influence of the temperature of the air surrounding the heat-removing surface 1 with heating chambers (2-6), the outer surface of the heating chambers begins to cool, which leads to cooling of the gas medium inside the heating chambers 2-6. As a result, the process of reducing the internal pressure in the heating chambers 2-6 begins, to the value of its initial value, thus forming a circuit of the selected coolant in the heating chamber. Then, the infrared emitter 8 is again connected to a current source, but since the heat storage substance maintains a predetermined temperature of the heat carrier after it is turned off for a certain time, the time for repeated activation of the infrared emitter is reduced, which leads to additional savings in energy consumption, leading to an increase in the energy efficiency of the device.

If a liquid is chosen as the heat carrier, then after turning on the infrared emitter in the electric network, the infrared emitter 8 under the influence of an electric current starts to generate quanta of a given frequency. The quanta obtained from the infrared emitter lead to heating of the heat-removing surface 1 with heating chambers (2-6), as well as the heat carrier. When the liquid reaches the boiling point, a liquid-gas medium begins to form. In the formed zone of a liquid-gas medium, quanta from an infrared emitter enter the molecules of this medium. Since the radiated wavelength of the infrared emitter is equal to the wavelength of the liquid, as a result of this, a resonance phenomenon occurs in the liquid-gas medium, which leads to the breaking of the liquid-gas medium molecules. This gap generates additional heat, which is transferred to the walls of the heat-removing surface 1 with heating chambers (2-6), which is heated to a predetermined temperature in an accelerated mode, which leads to savings in energy consumption. Then, the infrared emitter 8 is turned off, but since the infrared emitter is surrounded by a heat-accumulating substance, this substance continues to maintain a given temperature of the heat carrier after it is turned off for a certain time. Under the influence of the temperature of the air surrounding the heat-removing surface 1 with heating chambers (2-6), the outer surface of the heating chambers begins to cool, which leads to cooling of the liquid-gas medium inside the heating chambers, as a result of which the process of its condensation and transition to the liquid medium begins which flows down the walls of the inner surface of the heating chamber to its lower part under the influence of gravitational forces, thus forming a circuit of the selected heat carrier in the heating chamber. Then the infrared emitter is again connected to the current source, but since the heat-accumulating substance maintains the set temperature of the heat carrier after it is turned off for a certain time, the time for the infrared emitter to turn on again is reduced, which leads to additional savings in energy consumption, leading to an increase in the energy efficiency of the device.

The amount of heat storage material placed in the lower compartment 7 depends on the size and diameter of the lower compartment. The electric heating element is an infrared emitter, the wavelength of which should be in the range (0.78-3.2) microns, depending on the intrinsic wavelength of the coolant used.

A device for receiving thermal energy from electric energy, like a local heating device, is installed at the place of need, in the room. For its operation, a conventional 220-volt alternating current power supply, connected by a conventional (standard) plug-in connection, is sufficient.

Such a device, when used for heating residential premises, provides the equipment with a pressure of not more than 2.1 bar and a heating surface temperature of not more than 70 degrees Celsius, which allows, in accordance with regulatory and technical legal acts of the state in the field of heat supply for residential and industrial premises, assign it to non-hazardous facilities working under pressure.

The device can be equipped with sensors, means and systems for measuring and regulating temperature, changing the current strength or the time of supplying voltage to the electric heating element.

The device is simply based on a hydraulic circuit and can be manufactured using standard components: a metal pipe, a coolant, an electric heating element.

The proposed device can be used:

- for heating technical, technological and residential premises on sea and river transport. The introduction of such a device will reduce the consumption of fuel for power plants of sea and river vessels, due to a significant reduction in the power required to generate electricity used for heat supply.

- for heating cars in railway transport. The use of such a device in railway transport for passenger traffic will allow abandoning the existing carriage stoves operating on wood and coal. This is due to the fact that such devices are not dependent on temperature differences; they do not defrost; during long-term car parking

- to create a family of devices in various industries that use thermal energy and steam energy in their technological cycles. At the same time, savings are achieved in the costs required to receive and transport thermal energy through the application of the principle of heat generation at the place of its consumption based on the use of the quantum resonance method, which reduces the cost of industrial production.

Claims (5)

1. A device for generating thermal energy from electrical energy, comprising a heat-removing surface with a heat carrier located inside it and an electric heating element with current-carrying leads fixed to the end wall of the heat-removing surface, characterized in that the heat-removing surface is divided into two compartments, an electric heating element is placed in the lower compartment, made in the form of an infrared emitter surrounded by a heat-accumulating substance, and in the upper compartment there is a coolant whose wavelength th choose equal to the emitted wavelength of the infrared emitter. 2. The device of claim 1, characterized in that the infrared emitter is made in the form of a single or block design. 3. The device according to any one of paragraphs. 1 or 2, characterized in that the infrared emitter is fixed in the middle part of the end wall of the lower compartment of the heat-removing surface by means of a fitting, gaskets or nipple and union nut. 4. The device according to claim 1, characterized in that the heat-removing surface is made of aluminum, cast iron or steel in the form of a pipe or box of a rectangular, triangular or other closed section without ribbing or with an external finning of the body surface. 5. The device according to any one of paragraphs. 1 or 4, characterized in that the external finning of the heat-removing surface is made longitudinal or transverse with partial external thermal insulation of the lower compartment of the heat-removing surface.

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