RU183122U1 - Station for generating electric energy on any type of heat using convection - Google Patents

Abstract

The proposed utility model relates to the field of energy, in particular, to devices that use natural air draft to generate energy in principle, which occurs when the elevation in the pipes or when moving through air pipes with different temperatures. To solve the problem in the station for generating electric energy on any type of heat using convection containing a body in the form of a vertically oriented pipe, equipped with an air duct for warm air and at least two electric According to the utility model, the casing is equipped with additional air ducts with heating air from steam and gas ducts for exhaust gases, and the ducts with heating air from steam and gas ducts are connected to the housing through the tambours in which are installed heat exchangers. Electric generators are located below air ducts and gas ducts. Flaps are installed in the vestibules. The case is made of heat-insulating material. Each row of blades consists of several blades located on the same axis, and is installed with a horizontal shift relative to the other row by 45 degrees. Each row of blades is mounted on the shaft at an angle of 20 to 60 degrees. The number of rows of blades depends on the height of the station casing. The number of blades in a row depends on the diameter of the station building. The area of the blades is less than half the area of the horizontal section of the station building. The number of ducts and gas ducts can be increased in proportion to the diameter of the housing. The number of generators can be increased in proportion to the diameter of the housing.

Description

The proposed utility model relates to the field of energy, in particular, to devices that use natural air draft for the generation of energy in principle, which occurs when there is a difference in elevation in the pipes or when moving through air pipes with different temperatures.

At thermal power plants, almost two-thirds of the heat received from the combustion of fuel leaves with waste heated water. At the same time, every enterprise makes great efforts to utilize large thermal secondary energy resources. Thermal secondary energy resources are the physical heat of exhaust gases, the main and by-products of production; the heat of hot water and steam spent in process plants; the heat of the working fluid cooling systems of technological plants. Thermal secondary energy resources can be used both directly in the form of heat, and for separate or combined generation of heat, cold, electricity, as well as in recycling plants. Boiler houses also have not less reserves of thermal secondary energy resources, the number of which in our country is quite large. To the boiler rooms you can add hundreds of thousands of small boilers for gas, liquid and solid fuels for heating small rooms, shops, in the private sector, cottages, baths, canteens.

Known "Solar-convective power plant" according to the patent for invention No. 2583210, in which the solar-convective power plant contains one or more ducts, one or more electric generators, a collector in which the air heating system is installed or not installed, the heat pump system is installed or not installed , one or more turbines, a cable system, a hose system and a gas system. Moreover, at least one of the ducts is a balloon and is a vertical inner tube open for air movement, located inside a vertical, outer tube. The inner and outer pipes are round or different from the round section, and the volume between the pipes is isolated from the ends and filled with gas lighter than air. As the material of at least one part of one of the pipes, a transparent or opaque elastic airgel or any other material having a Young's modulus less than or equal to 15 GPa is used. The invention should ensure the creation of an environmentally friendly power plant based on a renewable energy source. The disadvantages of this invention in the first place can be called the dependence of the efficiency of the power plant on solar activity, the use of one type of heat to generate electricity, as well as the complexity of the installation itself, significant costs for its construction and maintenance, which reduces the possibility of widespread use.

Also known is the “Whirlpool power plant” according to the application for invention No. 94028398, which includes a pipe with primary and secondary vortex generators, a deflector, a “tent” with an air heating system or a “bunker” with pipes supplying warm air, an electric generator with a shaft at the maximum possible height, and to create traction, excess heat from enterprises, a deflector and an auxiliary vortex generator are used, and to increase the power of the vortex installation, direct exposure to air vortices is used about the flow to the wind wheels directly in the pipe, the wings of which are placed in the zone of the vortex air flow created by the main and supported by auxiliary vortex generators. The present invention proposes the use of a vortex air flow, as well as a stream created by an additional vortex generator, which requires additional costs for construction and maintenance, and operates on only one heat source, in other words, it is not widely used. This technical solution is the closest to the proposed utility model and is accepted by the applicant for the closest analogue.

The technical task is to create such a station to generate electricity on any type of heat using convection, which would make it possible to use any heat source (secondary energy resources) coming from a wide range of sources, ranging from industrial plants (TPPs, thermal power plants and boiler houses) to small heat points , as well as warm air heated by the sun, which ensures the versatility of the station and will allow the use of the proposed device both in industrial conditions and in small farms.

To solve the problem in the station for generating electric energy on any type of heat using convection, containing a casing in the form of a vertically oriented pipe, equipped with an air duct for warm air and at least two electric generators, as well as a shaft with blades and a flywheel mounted on it, according to a utility model, the casing is equipped with additional air ducts with heating of air from steam and gas ducts for exhaust gases, and air ducts with heating of air from steam and gas ducts are connected to the building mustache through tambours in which heat exchangers are installed;

Electric generators are located below air ducts and gas ducts;

In the vestibules are installed dampers;

The case is made of heat-insulating material;

Each row of blades consists of several blades located on one axis and is installed with a horizontal shift relative to the other row by 45 degrees;

Each row of blades is mounted on the shaft at an angle of 20 to 60 degrees;

The number of rows of blades depends on the height of the station;

The number of blades in a row depends on the diameter of the station body;

The area of the blades is less than half the area of the horizontal section of the station building;

The number of ducts and gas ducts can be increased in proportion to the diameter of the housing;

The number of generators can be increased in proportion to the diameter of the housing.

A station can simultaneously receive several types of heat through air ducts and gas ducts, namely: steam, exhaust gases or air heated by the sun. The waste products of combustion from the gas path of the heat generators passing through heat exchangers containing, for example, water give part of the heat to the water, and passing through the station body create air draft. Heated water, in turn, can be used for heating or hot water supply of nearby consumers. It is also possible to use exhaust steam to create draft in the station casing, which is sent not to the cooling tower for condensation, but to heat exchangers located in the vestibule. Steam passing through the heat exchanger heats it, and the air mass located outside - cools, and thereby being heated, is sent to the station building, creating air draft. Ducts supplying air from the atmosphere are metal pipes painted primarily in black for maximum efficiency. To control the draft in the vestibules, the installation of dampers is possible.

This arrangement of the structural elements of the station makes it possible to use several types of heat in creating an upward flow of air in the station building, thereby confirming the solution to the technical problem - the creation of a universal station for generating electricity using thermal secondary energy resources, as well as solar energy, and generating electricity of any kind heat using convection.

The location of the generators below the air ducts and gas ducts allows to extend their service life and perform the necessary maintenance without shutting down the station. The flaps in the vestibules are installed to regulate the draft, and the housing made of heat-insulating material allows to obtain the maximum temperature difference and increase the draft.

Each row of blades consists of several blades located on one axis and is installed with a horizontal shift by 45 degrees relative to the other row, and with the possibility of adjusting the angle of inclination to the horizontal axis in the range from 20 to 60 degrees, and the number of rows of blades depends on the height of the station building, and the number of blades in a row depends on the diameter of its body. The area of the blades is less than half the area of the horizontal section of the station building. This allows you to use the optimal amount of secondary energy resources and maintain the power of the station in optimal mode.

The number of ducts, gas ducts and the number of electric generators can be increased in proportion to the diameter of the housing, for the station to generate the maximum possible amount of energy, thereby increasing its efficiency.

Patent studies did not reveal technical solutions characterized by the claimed combination of essential features, therefore, we can assume that this utility model meets the criterion of "novelty."

In addition, the proposed technical solution can be manufactured on an industrial scale using standard equipment and will find application in the energy sector, i.e. characterized by the criterion of "industrial applicability"

Brief Description of the Drawings:

FIG. 1 is a general view of the station (vertical section, shown duct for warm air and gas duct for exhaust gas);

FIG. 2 is a top view (version with two air ducts and two air ducts with air heating from steam).

The station for generating electric energy comprises a housing 1 in the form of a vertically oriented pipe, a shaft 2 is installed along the central axis of the housing 1, blades 3 are fixed on the shaft 2, and a flywheel 4 interacting with electric generators 5. The housing 1 is equipped with an air duct for warm air 6 and a gas duct 7 for exhaust gases and air duct 8 with air heating from steam (not shown in FIG. 1), and the number of air ducts depends on the diameter of the casing and can be changed depending on the installation area and operation mode of the station . Electric generators 5 and a flywheel 4 are located below the air ducts, and the gas duct 7 for exhaust gases and the air duct 8 with air heating from steam are connected to the housing 1 through tambours 9 in which heat exchangers 10 are installed. Tambours 9 contain dampers 11 for regulating draft. The station building 1 is made of a heat-insulating material, for example expanded clay concrete or brick. Each row of blades 3 mounted on the shaft 2 consists of several blades located on the same axis and mounted with a horizontal shift of 45 degrees relative to the other row, while the blades have the ability to adjust the inclination to the horizontal axis in the range from 20 to 60 degrees. The area of the blades is less than half the area of the horizontal section of the station building. The number of generators 5 can be increased in proportion to the diameter of the housing.

The electric power generation station operates as follows: through a gas duct 7 for exhaust gases, the exhaust gases are fed into the vestibule 9 and, with the damper 11 open, bypassing the heat exchanger 10, for example, filled with water, rush into the station building 1, in the housing 1 the exhaust gas rises up creating air draft, the blades 3 are rotated, thereby creating a rotation of the shaft 2 and through the flywheel 4 the rotation is transmitted to the electric generators 5. The water contained in the heat exchanger 10 can be used for hot water supply me or boiler feed. In another case, through the air duct 8 with air heating from steam, non-pressure exhaust steam is sent to the heat exchanger 10 located in the vestibule 9, the steam passing through the heat exchanger heats it, and the air mass from the outside cools, and thereby heats up, sent to the station building 1, creating air draft. In the third case, the duct for warm air 6, which is a metal pipe painted mainly in black for maximum efficiency, brings the air heated by the sun's rays from the atmosphere directly into the station building 1 and creates air draft. To regulate the draft in the tambours 9, it is possible to install dampers 11. To organize the air flow in the building 1 of the station, so many air ducts and gas ducts are connected to it that their total cross section corresponds to the cross section of the housing.

Claims (11)

1. A station for generating electrical energy from any type of heat using convection, comprising a housing in the form of a vertically oriented pipe, equipped with an air duct for warm air and at least two electric generators, as well as a shaft with blades and a flywheel mounted on it, characterized in that the casing is equipped with additional air ducts with heating of air from steam and gas ducts for exhaust gases, and air ducts with heating of air from steam and gas ducts are connected to the housing through tambours, in which enes heat exchangers. 2. A station for generating electric energy according to claim 1, characterized in that the electric generators are located below the air ducts and gas ducts. 3. A station for generating electric energy according to claim 1, characterized in that dampers are installed in the vestibules. 4. A station for generating electric energy according to claim 1, characterized in that the housing is made of heat-insulating material. 5. A station for generating electric energy according to claim 1, characterized in that each row of blades consists of several blades located on one axis and is installed with a horizontal shift of 45 degrees relative to the other row. 6. A station for generating electric energy according to claim 1, characterized in that each row of blades is mounted on the shaft at an angle of 20 to 60 degrees. 7. A station for generating electric energy according to claim 1, characterized in that the number of rows of blades depends on the height of the station building. 8. A station for generating electric energy according to claim 1, characterized in that the number of blades in a row depends on the diameter of the station body. 9. A station for generating electric energy according to claim 1, characterized in that the area of the blades is less than half the area of the horizontal section of the station building. 10. A station for generating electric energy according to claim 1, characterized in that the number of ducts and gas ducts can be increased in proportion to the diameter of the housing. 11. A station for generating electric energy according to claim 1, characterized in that the number of electric generators can be increased in proportion to the diameter of the housing.

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