WO2024047404A2

WO2024047404A2 - Geothermal combined heat and power plant operating on boiling liquid

Info

Publication number: WO2024047404A2
Application number: PCT/IB2023/000708
Authority: WO
Inventors: Реджепмурад ИШАНКУЛИЕВ; Данатар ИШАНКУЛИЕВ
Original assignee: Реджепмурад ИШАНКУЛИЕВ
Priority date: 2022-07-08
Filing date: 2023-07-05
Publication date: 2024-03-07
Also published as: WO2024047404A3

Abstract

A geothermal combined heat and power plant operating on a boiling liquid allows the intensive harvesting of thermal energy from a geothermal source by means of vapour from a boiling liquid without contact with the ground. The geothermal combined heat and power plant operating on a boiling liquid makes direct use of the geothermal energy of the vapour from a boiling liquid to generate electrical and thermal energy independently of the presence or absence, in the geothermal source, of steam, a steam and water mixture or brine and independently of the composition, volume and flow rate thereof. In the geothermal combined heat and power plant, an evaporator is used which is mounted at the bottom of a well that serves as a space for the generation of vapour from a boiling liquid arriving via a return pipe, using the thermal energy of the ground surrounding the body of the evaporator and the gravitational force of the boiling liquid. In the geothermal combined heat and power plant, a liquid and vapour from the boiling liquid circulates through a closed "evaporator – turbine – water heater – pump – evaporator" loop.

Description

GEOTHERMAL COOPERATION POWER PLANT OPERATING ON BOILING LIQUID

TECHNICAL FIELD

The present invention relates to geothermal energy and can be used to generate electrical and thermal energy from the thermal energy of the soil of all types of geothermal sources.

BACKGROUND ART

An analogue and prototype of the geothermal heating power plant proposed in the invention, operating on boiling liquid (GeoTES), has not been found, since until now scientific research, work on the development of inventions and design of GeoTES, operating on the basis of the use of steam from boiling liquid, have not been carried out in a direct way [ 1...6].

DISCLOSURE OF INVENTION

The basis of the invention is the task of creating a new type of geothermal heating power station - GeoTES, which removes the thermal energy of a geothermal source with boiling liquid steam without contact with the ground and generates electrical and thermal energy using in a direct way, the geothermal energy of boiling liquid steam. In a geothermal power plant, steam and liquid from a boiling liquid circulate in a closed loop “evaporator - turbine - compressor - water heater - evaporator”.

GeoTES innovations allow:

- intensively remove the thermal energy of a geothermal source with boiling liquid steam without contact with the ground and effectively use the geothermal energy of boiling liquid steam;

- using the geothermal energy of boiling liquid steam in a direct way to generate electrical and thermal energy, regardless of the presence or absence of water steam, steam-water mixture or brine in the geothermal source, on their composition, volume and flow rate;

BRIEF DESCRIPTION OF THE DRAWINGS

In figure 1. Design and principle of operation of GeoTES.

In Fig.2. Evaporator device.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is described in more detail below with reference to the accompanying drawings illustrating an embodiment.

OPTION FOR IMPLEMENTATION OF THE INVENTION

The geothermal power plant consists of an evaporator I, a return 2, an underwater 4, connecting pipes 10, 12 and 17, a turbine 8, an electric generator 9, a compressor I, a water heater 13, a pump 18, a heating system circulation pump 14, an underwater cold water pipe 16 from the system heating into the water heater and hot water outlet pipe 15 into the heating system from the water heater (Fig. 1).

Evaporator I installed at the bottom of the well serves as a space for vaporization of boiling liquid coming from return pipe 2 at

SUBSTITUTE SHEET (RULE 26) the participation of the thermal energy of the soil covering the evaporator body and the gravitational force of the boiling liquid.

The evaporator consists of a steel cylindrical body 2, lower 1 and upper 5 covers forming a sealed evaporator chamber 3. The upper cover 5 has holes for a return pipe 4 with a choke 8 and an underwater pipe 6. An eyelet of the cable 7 is attached to the top cover 5 for lowering the evaporator into the bottom of the well (Fig. 2).

As a water heater, one of many types of heat exchangers is used, providing the most effective heat exchange between the hot steam of a boiling liquid passing through the pipe and the water filling the internal volume of the water heater 13 (Fig. 1).

After installing the evaporator I, return 2 and underwater 4 pipes in the wellbore 3, its remaining free space is filled with plugging material 5 (Fig. 1).

The full cycle of operation of a geothermal power plant occurs in the following sequence.

Steam of boiling liquid with temperature ti and pressure pi from the evaporator chamber 1 through the underwater pipe 4 enters the turbine 8 and rotates the turbine shaft connected to the generator 9, which generates electrical energy. In this case, the pressure and temperature of the steam of the boiling liquid drops, respectively, to the value gi t2 (Fig. 1).

From the turbine 8, steam of boiling liquid through the connecting pipe 10 is sucked in by the compressor 11 and compressed with pressure that ensures its greatest heating. The temperature and vapor pressure of a boiling liquid increase accordingly

ts (Fig. 1).

Then the steam of the boiling liquid is supplied through the connecting pipe 12 to the water heater 13. There, heat exchange occurs between the steam of the boiling liquid and the cold water of the heating system supplied through the underwater pipe 16 to the water heater 13. The cold water of the heating system is taken absorbs the geothermal energy of boiling liquid steam and heats up to +80°C. After this, the hot water is sucked by the circulation pump 14 through the outlet pipe 15 into the heating system. In this case, the vapor temperature of the boiling liquid drops to t4, and the pressure p3 does not change. There is a phase transformation of boiling liquid vapor into liquid (Fig. 1).

The liquid from the water heater 13 through the connecting pipe 17 is sucked in by the pump 18 and transferred to the return pipe 2 and flows to the evaporator I under pressure p4 and temperature t4. In part of the return pipe 2, the liquid in the wellbore 3 moves under pressure p4 and additional pressure ro created by the gravitational force in the boiling liquid, which increases as it descends into the well, simultaneously removing the thermal energy of the soil. Before the liquid leaves the return pipe 2 into the evaporator chamber 3, the temperature and pressure increase respectively to ts and p4+po (Fig. 1).

The liquid pressure p + po leaving the return pipe 2 into the evaporator chamber 1 must satisfy the following condition:

Р4 +ро > pi OR Р4 + pgh > pi, where pi is the pressure in the evaporator chamber 1; p is the density of the boiling liquid; g - free fall acceleration; h is the length of the return pipe 2 located in the well (Fig. 1).

When the liquid exits the throttle 8 of the return pipe 4 into the evaporator chamber 3 (Fig. 2), its temperature and pressure drops to ts and pi, respectively. A phase transformation of liquid into vapor occurs.

At the bottom of well 3, heat exchange occurs between the steam of the boiling liquid located in the evaporator chamber 3 and the soil surrounding the evaporator body I. As a result, the steam of the boiling liquid is heated to a temperature /7, and the pressure pi does not change (Fig. 1).

In the underwater pipe 4, the pressure pi of the steam of the boiling liquid is maintained until it is supplied to the turbine 8. Due to heat losses in the underwater pipe 4, the temperature of the liquid vapor at the entrance to the turbines 8 is reduced to temperature ti (Fig. 1).

To reduce heat losses from the steam of the boiling liquid in the underwater pipe 4, its entire surface from the evaporator I to the turbine 8 is covered with a thermal insulating coating 6 (Fig. 1).

To reduce the heat loss of the boiling liquid in the return pipe 2, the upper part of the surface of the return pipe 7 to a depth hi is covered with a thermal insulation coating. The value of hi is determined by the depth of the geothermal source soil zone, the temperature of which is equal to the temperature t4 of the boiling liquid in the cold weather period (Fig. 1).

Thus, the GeoPP proposed in the invention makes it possible to intensively remove the thermal energy of a geothermal source with boiling liquid steam without contact with the ground, using the geothermal energy of boiling liquid steam in a direct way to generate electrical and thermal energy, regardless of the presence or absence of water steam, a steam-water mixture or brines in the geothermal source , on their composition, volume and debit.

Bibliography

1 • office@kstuca.kharkov.ua Redko A. A. Rational thermodynamic parameters of cycles of a multi-stage geothermal power plant.

2. Patent RU 2110019С1. Steam turbine plant for a geothermal power plant.

3. Patent RU 2330219С1. Geothermal energy supply plant.

4. Patent RU 2343368С1. Geothermal energy plant.

5. https://rfc.kegoc.kz/media Preliminary review of geothermal resources in Kazakhstan.

6. www.membrana.ru/particle/13739. A cutting-edge geothermal power plant is now online in Utah.

Claims

7 Formula of invention

1. Geothermal heating power station operating on boiling liquid, characterized in that the thermal energy of the geothermal source, regardless of the presence or absence of water steam, steam-water mixture or brine in it, from their composition, volume and flow rate, is intensively removed by boiling liquid steam without contact with soil.

2. Geothermal heating power station operating on boiling liquid, characterized in that in it the geothermal energy of steam from boiling liquid is used in a direct way to generate electrical and thermal energy.

3. Geothermal heating power station, operating characterized by the fact that it uses an evaporator located in the bottom of the wellbore, which serves as a space for the vaporization of boiling liquid coming from the return pipe with the participation of the thermal energy of the soil covering the evaporator body and the gravitational force of the boiling liquid.

4. Geothermal heating power station operating on boiling liquid, characterized in that the steam and liquid of the boiling liquid circulates in a closed circuit “evaporator - turbine - compressor - water heater - evaporator”.