UA134731U - STEP SYSTEM OF EXTRACTION OF THERMAL ENERGY FROM THE EXTERNAL ENVIRONMENT AND INJECTING IT INTO THE SOIL - Google Patents

Abstract

The step system of extracting thermal energy from the environment and injecting it into the soil contains a closed circuit, inside which circulates intrasystem substance in accordance with a given direction of circulation, engine-generator, heat exchangers, contains at least one external evaporator, capable of extracting heat from the environment one internal condenser having at least one or more heat transfer chambers to the heat exchanger, which directs heat to the ground, at least one motor connected to an electric current generator, configured to operate in a closed system at a pressure difference between the evaporating intrasystem material and condensed at least one pump that supplies condensate from the condenser to the evaporator, a heat exchanger that directs heat to the ground. The intrasystem substance is freon. The pump that supplies condensate from the condenser to the evaporator is made in the form of a gear mechanism. The motor-generator is a gear or rotor-plate mechanism. The generator motor has at least one working area, each of which has at least one working chamber.

Description

The utility model belongs to the field of thermal energy, in particular to installations that use external heat from an available source, for example, an internal combustion engine, solar collectors, a ground battery, etc., for autonomous energy supply of premises, in particular, electricity and heat supply, and can be used as an alternative for residential sectors, cities and localities, including remote from existing power lines.

There is only one source of energy in the world - it is the energy released during nuclear reactions. All other energies available to us are its consequence. A nuclear reaction has many processes and consequences that have a negative impact on living beings, so its use is subject to careful control.

Until now, people have not been able to find an ideal way of obtaining energy from atomic reactions, and the constantly developing world requires more and more of it. An alternative to the atom in our world is hydroelectric power plants, wind power plants, and power plants based on solar batteries and collectors. Hydrocarbon power plants cannot be an alternative, being rather a forced and temporary method, which must naturally become a thing of the past.

Considering the existing methods of extraction and conservation of energy, you can find both significant advantages and disadvantages in them. The advantage of river energy can be considered stability and the absence of the need to release harmful substances into the environment. The main disadvantage is the blocking of channels and quantitative limitation. Almost everywhere in our world, where it was possible to build hydroelectric plants, they did not globally destroy nature, they were already built. Wind farms are stable in steady winds, they are well suited for open areas with constant wind and no nearby residential areas. The disadvantage of wind generators is their noise, high cost of acquisition, maintenance and dependence on the presence of wind. Both hydroelectric power plants and wind power plants can hardly afford living in private residential sectors. Solar panels and collectors are a good alternative for residential areas. Solar batteries are environmentally safe, do not take up much space and do not make noise. The disadvantage of solar batteries is low efficiency, dependence on the presence of sunlight, high cost and the need for batteries, which are expensive and short-lived. Solar collectors have good efficiency, like batteries, are compact, but their operation also depends on the presence of the sun. The main problem in the use of solar energy by batteries and collectors in

Because when the sun is active, we have the least need for thermal energy, and when it is most needed, we have the minimum number of sunny days and hours.

It is known that to extract the mechanical potential from the thermal potential, a difference in temperatures is necessary, and the greater the temperature difference, the more efficient the conversion of thermal energy into mechanical and then into electrical energy. There is a known method of obtaining mechanical energy from thermal energy by means of the transition of substances from liquid to gaseous form as a result of heating and condensation, as a result of cooling. There is a known method of storing thermal energy in the soil, as a natural battery, with the location of the highest temperature in the center of the battery.

A known closed-loop installation, designed for the production of electrical energy, containing a closed circuit, inside which at least one working fluid circulates, in accordance with the given direction of circulation, at least one volume expander, made with the possibility of accepting the working fluid at the inlet in a gaseous state, in this case, the volume expander contains at least one casing having at least one inlet and one outlet, designed respectively for the introduction and release of the working fluid, an active element placed in the casing and intended to form, together with the casing, an expansion chamber of variable volume, a main shaft connected to the active element and made with the possibility of rotational movement around an axis, at least one distributor that operates on the inlet and on the outlet of the casing and made with the possibility of selective opening and closing of said inlet and outlet to provide at least one input state, one expansion state and one ejection state supply of the working fluid from the expansion chamber, at least one generator of electrical energy connected to the main shaft, at least one pump placed in the circuit and made with the possibility of giving the working fluid a given direction of circulation, at least one first heat exchanger operating in the circuit and located after of the pump relative to the direction of circulation of the working fluid, and the first heat exchanger is made with the possibility of receiving the working fluid at the inlet and receiving heat from a hot source and ensuring the heating of this working fluid until its transition from the liquid state to the gaseous state is caused, in this case, the volume expander is connected after the first heat exchanger relative to the direction of circulation of the working fluid inside the circuit and is made with the possibility of accepting the working fluid at the inlet in a gaseous state formed in the first heat exchanger, and the distributor of there is at least one regulating device made with the possibility of changing at least one of the following parameters: the duration of the input state of the maximum cross-section of the intake passage |НО Me 2633321 С2, ROTK 13/02, 20061И.

This analog has low efficiency and low efficiency.

The basis of the useful model is the task of creating a step-by-step system for extracting thermal energy from the external environment and injecting it into the soil with the simultaneous production of electrical energy when heating the soil to increase the efficiency of heat pumps in winter.

The problem is solved by the fact that the step system of extracting thermal energy from the external environment and injecting it into the ground, which contains a closed circuit, inside which the internal system substance circulates, according to the given direction of circulation, engine-generator, heat exchangers, according to the useful model, contains: at least one external evaporator is made with the possibility of extracting heat from the environment; at least one internal condenser that has at least one or more chambers that gives heat to a heat exchanger that directs heat into the ground; at least one engine connected to an electric current generator, made with the possibility of working in a closed system on the pressure difference between the internal system substance that evaporates and condenses; at least one pump supplying condensate from the condenser to the evaporator; a heat exchanger that directs heat into the ground;

The intrasystemic substance is freon.

The pump that supplies condensate from the condenser to the evaporator is made in the form of a gear mechanism.

The engine-generator is a gear or rotor-plate mechanism.

The engine-generator has at least one working zone, each of which has at least one working chamber.

The proposed system will allow to receive from the external environment, transport, accumulate and use the heat of the environment with further use for heating the premises with heat pumps, as well as to produce electricity during laying

From thermal energy to the ground battery and its extraction from the ground battery.

The system will work, due to the boiling of the substance in the evaporator from heating by the environment and condensation in the condenser, being cooled by the soil, thereby heating the soil and producing electricity at the same time with the help of a rotor-plate, gear, cam or piston engine.

The proposed system is independent and effective, capable in the future, by joining local networks and interacting with solar power plants, wind power plants and hydroelectric power plants, to displace the need to burn hydrocarbons. The system also allows for the use of any available sources of thermal energy, the accompanying heat release in internal combustion engines, electrical transformers, the difference in thermal potential between the daytime heat and the nighttime cold of deserts, the temperature difference in the seas and the atmosphere, and wherever there is a stable difference starting from 10 "C and above.

The system has a completely closed liquid-gas system, which allows the use of aggressive refrigerants without harming the environment and human health.

A useful model is explained with a drawing. The drawing shows the schematic diagram of the system.

As an example, the drawing shows a system with a rotor-plate mechanism, on the basis of which an engine has been developed that allows you to extract mechanical energy from the kinetic potential of superheated steam. The mechanism is a rotary engine combined with a generator in one hermetic housing, which operates on the pressure difference in the evaporator and condenser.

The step-by-step system for extracting thermal energy from the external environment and injecting it into the ground contains a closed circuit 1, inside which the internal system substance circulates, according to the given direction of circulation, an engine-generator 2, at least one external evaporator 3, made with the possibility of extracting heat from the environment, at least one internal condenser 4, having at least one or more chambers 5, which gives heat to the heat exchanger b, which directs heat into the ground, at least one pump 7, which supplies condensate from the condenser 4 to the evaporator 3;

The intrasystemic substance is freon.

The pump 7, which supplies condensate from the condenser 4 to the evaporator 3, is made in the form of a gear mechanism. because Engine-generator 2 is a gear or rotor-plate mechanism.

Engine-generator 2 has at least one working zone 8, each of which has at least one working chamber 9.

The system works in the following way.

External heat from an available source, for example, air masses, solar collectors, soil battery, etc., is supplied to the evaporator 3. In the evaporator 4, the internal system substance is converted into steam and is supplied to the working zone 8 of the engine-generator 2 through the inlet through the closed loop 1 hole 10. The engine-generator has at least one working zone 8, each of which has at least one working chamber 9 within the working zone. The first working chamber 9 of the working zone 8 is connected to the evaporator 3. In the first chamber 9 of the working zone 8, kinetic energy is extracted due to the difference in pressure between the evaporator and the condenser. The second working zone 8 is connected to the first and second chambers 5 of the condenser 4.

In the second working zone 8, the extraction of energy stops and the primary extraction of steam takes place, which slightly lowers the pressure and temperature. From the second zone of the working chamber 8 through the outlet openings 11 and 12, steam is sent to the first chamber 5 of the condenser 4, in which the liquid that is sent to the battery is maximally heated. In the following chambers 9 of the working zone 8, the next selection of steam takes place for intermediate heating of the liquid, which is directed to the accumulator in the second chamber 5 of the condenser 4. In the last zone of the engine, the final pressure release occurs, from where the steam goes to the third chamber 5 of the condenser 4 through the outlet 12, which serves to create the maximum pressure difference between the evaporator and the condenser, while the pressure difference allows the maximum amount of energy to be extracted. The steam that entered the condenser condenses into a liquid, giving heat to the heat exchanger 6, which directs the heat into the ground. Condensed liquid is fed back to the external evaporator C with the help of pumps 7, where it is evaporated, and the cycle of the system is repeated.

During the operation of the system, the pressure between the first and last zones of the working chamber 8 will approach the pressure difference between the evaporator C and the condenser 4. The difference in pressure will cause the engine-generator 2 to rotate and produce electrical energy.

The engine-generator has at least one intermediate chamber, which allows you to receive thermal energy sent to the battery, and at the same time distribute the load on the plates.

Engine-generator 2 must be designed to operate in an oil cushion. At

Due to the performance of the engine in the form of a rotor-plate mechanism, the blades must slide in the oil and be pushed out due to the pressure of the steam from the previous zone of higher pressure for the maximum correspondence between maintaining the density between the working parts and at the same time, without having any excess tension between them.

The step-by-step system of extracting thermal energy from the external environment and injecting it into the soil with the simultaneous production of electrical energy when heating the soil allows to obtain electrical (mechanical) energy with maximum productivity and simultaneously heat the soil for further use of the soil heat by heat pumps.

Claims (1)

USEFUL MODEL FORMULA 1. A step-by-step system for extracting thermal energy from the external environment and injecting it into the ground, containing a closed circuit, inside which the internal system substance circulates, according to the given direction of circulation, an engine-generator, heat exchangers, which is distinguished by the fact that it contains: at least one external evaporator , made with the possibility of extracting heat from the environment; at least one internal condenser, which has at least one or more chambers that give heat to a heat exchanger that directs heat into the ground; at least one engine connected to an electric current generator, made with the possibility of working in a closed system on the pressure difference between the internal system substance that evaporates and condenses; at least one pump supplying condensate from the condenser to the evaporator; a heat exchanger that directs heat into the ground. 2. The system according to claim 1, which differs in that the internal system substance is freon. 3. The system according to claim 1, which differs in that the pump supplying condensate from the condenser to the evaporator is made in the form of a gear mechanism. 4. The system according to claim 1, which differs in that the engine-generator is a gear or rotor-plate mechanism. 5. The system according to claim 1, which is characterized by the fact that the engine-generator has at least one working zone, each of which has at least one working chamber. KU h 12. 8 cha i m Z I . Ak y b h y nya syzhkyu ch ee and Z GE vi y y zosadssny seryuh Ii Na N V still o Zhchenko Y i i - 5 i mon sne v v v N V plen ih z kla 3 pane KU va I Her i U a KK v a V CHE 4 I y Bo an su o g; ke U u NK i Shi z VM oo chu i g i KK 3 . yo V Zh ka I. for their 115 ke Z. Ya m a Z a: 5 sya Ky a Va a a KO me i IZ sl: Yak - i rei y Mykh, Kam o y Z Te B 1: EE ve i sk kopa E i N Z s NK MO MOHZ Z yun E Z Por unya GK rya B her ; E and ; osh ko i NN i VK KU i sen om uk kt ok uh au u UK t Uk tn NU iy, r YA KU OV o U UZ i 1 vshi i V SHI i E N ok : OK sho ruVyuyuyuyuyu 1 a: DI I NN XX t i a Na Ya x Zh - t nKkzhe | A so x : s: t SU : y TK i IV Z y i B 4 Z - a an I ke M She Z 3, NE I. still and EE and their o de EE SHEU eat Y - E, 1 ! N I! che KU she Ii EI x, Z Shiya t: I! Her Y Me 5 N soti t tu zhV VV yuTV pk kl chew vh v NI her V HO KEX EK Z iyi 13 her Z iii - 3515 hm: u x hi 53 x hi E I: -e I hi i z CHE i : shi 4 Ii Her 13 and shi 13 ; ma ne CHI 7 M kuye, x A : i; KU zhit and yi yi shn I ; i Z : 1 Si I: Z E ИZ | i I: Z xx Z M Kai is a V V V V ha avonny Man vann oegodoyu i i iZ zh: i. H se dk KK: KE i : sne V, Ko K- i i Z Y Z z z: I a: Ka i i ZHE zhi Ve g i o MAI 3 zhkkkkkkkk : EN 3 i i p V i E i iii M b i I V V Z Ii her a and Ne X pon chin nin ti 3 yo sm ke det u N Z Xx I I poemez ning NI. in Ku dyna and and In to , and , whether Not: whether: still With ---- 535 5 5 5 5 -4«()::--: 88. 9-9 -9- ..-.-. 7--- 8:98 33333333: :--t-