CN110905469A - Sandstone thermal storage geothermal tail water efficient recharge method based on simulation - Google Patents

Abstract

The invention provides a sandstone thermal storage geothermal tail water efficient recharge method based on simulation, wherein the recharge method comprises a well arrangement technology, an innovative well formation technology, an efficient water-gas separation technology, an accurate water quality treatment technology, a well mouth multifunctional conversion technology and a data monitoring and acquisition technology based on simulation; has the advantages that: the invention is comprehensively designed from the aspects of well arrangement, well formation, water-gas separation, water quality treatment, multifunctional well mouth, data monitoring and acquisition, the produced geothermal water is completely recharged to the corresponding recharging well in the same layer after being filtered by the cascade utilization system, the recharging effect is good, and the recharging efficiency is high; the water-gas separation effect is good, and the safety of subsequent engineering is ensured; the filtering precision is high, and the problem of blockage in the process of recharging the sandstone thermal storage geothermal tail water is solved; the well mouth has high sealing performance, prevents pipeline corrosion caused by air suction, and automatically performs exhaust treatment; the system has high automation degree of control and monitoring, realizes remote data transmission and processing, and is safe and stable in operation.

Description

Sandstone thermal storage geothermal tail water efficient recharge method based on simulation

Technical Field

The invention relates to the field of geothermal tail water, in particular to a sandstone thermal storage geothermal tail water efficient recharge method based on simulation.

Background

In recent years, China vigorously promotes ecological civilization construction, energy structures are continuously adjusted and optimized, and deep well geothermal technology becomes a new emerging energy industry. Deep well geothermal heating projects are increasing continuously, but most of geothermal well heating tail water is directly discharged into urban sewers, so that geothermal resources are wasted, the mineralization degree of geothermal water is high, the geothermal water is discharged into surface water, environmental pollution is easily caused, and the geothermal water is only taken for a long time without being filled, so that the ground is easily subjected to overall settlement.

At present, recharging of geothermal tail water is an important problem for restricting development and utilization of geothermal resources in China, and parameters such as porosity and permeability of a reservoir layer can be changed due to the influence of water sensitivity, speed sensitivity and the like in the process of exploitation, so that the seepage capability of the reservoir layer is reduced. How to ensure that the heat production capacity and the exploitation condition of a reservoir are maintained on the premise that the water extraction quantity meets the heat demand is an important ring for ensuring the sustainable development and utilization of geothermal energy at present.

Geothermal tail water recharge is mainly divided into karst fracture type hot stored tail water recharge and clastic rock pore type hot stored tail water recharge in China. The karst fracture type hot storage tail water recharge effect is generally good, and the clastic rock pore type hot storage tail water recharge faces the problems of high formation pressure, hot storage blockage, sand production and the like.

Domestic research on geothermal recharge is only scattered and is not enough for a system. Moreover, most of units mainly develop and apply instruments and equipment, and do not develop system research from underground geothermal geological features, above-ground equipment configuration and geothermal mining and grouting well pattern layout aiming at sandstone thermal storage.

Disclosure of Invention

The invention aims to solve the defects of the prior art and provides a simulation-based sandstone thermal storage geothermal tail water efficient recharge method.

The new technical scheme of the invention is as follows: a sandstone thermal storage geothermal tail water efficient recharge method based on simulation comprises a well arrangement technology, an innovative well forming technology, an efficient water-gas separation technology, an accurate water quality processing technology, a well mouth multifunctional conversion technology and a data monitoring and acquisition technology based on simulation, and the recharge method comprises the following steps:

1) well spacing technology based on simulation: establishing a geothermal geological concept model, determining a model boundary condition, establishing a mathematical model, subdividing space and time, determining a simulation period and a prediction period, and performing simulation verification; analyzing the heat storage seepage capacity by using an actual model according to the heating area and combining the water yield of a single well, and determining the mining and irrigating proportion and the well spacing scheme;

2) the well forming technology is innovated: the whole well adopts a two-opening well-forming structure, the first mining drill bit with the diameter of 444.5mm is drilled to 400m, an oil casing pipe with the diameter of 339.7 multiplied by 9.65mm is put in, and well cementation and waiting are carried out; secondly, drilling a target layer through a 311mm diameter drill bit to form a well; running 244.5 x 8.94mm petroleum casing pipe from 400m to the top of the target reservoir, wherein the petroleum casing pipe comprises a 300m all-welded stainless steel wire-wound screen pipe; installing a hanger at a position of 400m, setting a 244.5mm sleeve, wherein the sleeve comprises two external packers and a blind plate, cementing the position of the sleeve from the upper part of a main thermal reservoir to the position of 400m after the sleeve is set, returning cement to the position of 400m, completing a target thermal reservoir to the bottom of a well by adopting a sieve tube, stopping water between each aquifer by using a rubber umbrella, and leaving a 20m sand-settling pipe at the bottom of the well;

3) the high-efficiency water-gas separation technology comprises the following steps: after geothermal water reaches a ground machine room through a geothermal exploitation well, sand removal and gas separation are carried out through a water-gas separation device, the water-gas separation device comprises an exhaust port, a tank body with a built-in rotary blade, a geothermal water inlet, a pressure transmitter, a frequency converter with a control system, a magnetic column-turning liquid level meter, a sand bag and a sand valve, the magnetic column-turning liquid level meter and a liquid level transmitter are installed outside the tank body, the magnetic column-turning liquid level meter observes the water level inside the tank body, the liquid level transmitter provides a signal for the frequency converter, and the liquid level transmitter adjusts the water quantity of a geothermal water pump through the frequency converter; the gravel stored in the sand bag is periodically removed manually;

4) an accurate water quality treatment technology: the geothermal water enters a diatomite intelligent visual filtering system, the filtering system comprises a precoating tank, a slag discharging tank, a clear liquid tank, a bottom valve, an exhaust valve, an overflow valve, a circulating valve and a residual liquid return valve, the filtering system comprises filtering, precoating filtering, filter cake recycling and filter cake washing, the running state of each program is observed by a sight glass, and particles with the particle size of more than 1 mu m in the geothermal fluid are removed through a filter aid;

5) the well head multifunctional conversion technology comprises the following steps: geothermal water enters a geothermal cascade utilization system, and tail water is utilized by heat exchange and returned to the recharge well; the recharging wellhead is additionally provided with a wellhead sealing device, the wellhead sealing device is a four-way wellhead device, a flange and a ball valve are arranged on the wellhead sealing device around an oil pipe in the middle of the wellhead, and the opening and closing of the flange and the ball valve in different modes realize different functions; an oil pipe is hung at the wellhead, when the recharge quantity is reduced, a high-pressure fan is used for gas lift well washing, and a valve device is arranged on a gas lift drainage pipeline to control the pressure of the wellhead; a bypass pipeline and a valve are arranged at the well mouth, and the recharging pipeline is flushed through the bypass before geothermal tail water is recharged; the closed system prevents corrosion of the pipeline due to air intake;

6) data monitoring and collection technology: the recharging method is controlled and monitored by a PLC cabinet, and comprises the control and monitoring of the water temperature and water quantity of the production well and the recharging well, the control and monitoring of a filtering system, the real-time monitoring of the pressure of a system pipeline, and the remote transmission and processing of data.

The filter aid is diatomite.

The invention has the beneficial effects that: the invention is comprehensively designed from the aspects of well arrangement, well formation, water-gas separation, water quality treatment, multifunctional well mouth, data monitoring and acquisition, the produced geothermal water is completely recharged to the corresponding recharging well in the same layer after being filtered by the cascade utilization system, the recharging effect is good, and the recharging efficiency is high; the water-gas separation effect is good, and the safety of subsequent engineering is ensured; the filtering precision is high, and the problem of blockage in the process of recharging the sandstone thermal storage geothermal tail water is solved; the well mouth has high sealing performance, prevents pipeline corrosion caused by air suction, and automatically performs exhaust treatment; the system has high automation degree of control and monitoring, realizes remote data transmission and processing, and is safe and stable in operation.

Detailed Description

A sandstone thermal storage geothermal tail water efficient recharge method based on simulation comprises a well arrangement technology, an innovative well forming technology, an efficient water-gas separation technology, an accurate water quality processing technology, a well mouth multifunctional conversion technology and a data monitoring and acquisition technology based on simulation, and the recharge method comprises the following steps:

1) well spacing technology based on simulation: establishing a geothermal geological concept model, determining a model boundary condition, establishing a mathematical model, subdividing space and time, determining a simulation period and a prediction period, and performing simulation verification; analyzing the heat storage seepage capacity by using an actual model according to the heating area and combining the water yield of a single well, and determining the mining and irrigating proportion and the well spacing scheme;

2) the well forming technology is innovated: the whole well adopts a two-opening well-forming structure, the first mining drill bit with the diameter of 444.5mm is drilled to 400m, an oil casing pipe with the diameter of 339.7 multiplied by 9.65mm is put in, and well cementation and waiting are carried out; secondly, drilling a target layer through a 311mm diameter drill bit to form a well; running 244.5 x 8.94mm petroleum casing pipe from 400m to the top of the target reservoir, wherein the petroleum casing pipe comprises a 300m all-welded stainless steel wire-wound screen pipe; installing a hanger at a position of 400m, setting a 244.5mm sleeve, wherein the sleeve comprises two external packers and a blind plate, cementing the position of the sleeve from the upper part of a main thermal reservoir to the position of 400m after the sleeve is set, returning cement to the position of 400m, completing a target thermal reservoir to the bottom of a well by adopting a sieve tube, stopping water between each aquifer by using a rubber umbrella, and leaving a 20m sand-settling pipe at the bottom of the well;

3) the high-efficiency water-gas separation technology comprises the following steps: after geothermal water reaches a ground machine room through a geothermal exploitation well, sand removal and gas separation are carried out through a water-gas separation device, the water-gas separation device comprises an exhaust port, a tank body with a built-in rotary blade, a geothermal water inlet, a pressure transmitter, a frequency converter with a control system, a magnetic column-turning liquid level meter, a sand bag and a sand valve, the magnetic column-turning liquid level meter and a liquid level transmitter are installed outside the tank body, the magnetic column-turning liquid level meter observes the water level inside the tank body, the liquid level transmitter provides a signal for the frequency converter, and the liquid level transmitter adjusts the water quantity of a geothermal water pump through the frequency converter; the gravel stored in the sand bag is periodically removed manually;

4) an accurate water quality treatment technology: the geothermal water enters a diatomite intelligent visual filtering system, the filtering system comprises a precoating tank, a slag discharging tank, a clear liquid tank, a bottom valve, an exhaust valve, an overflow valve, a circulating valve and a residual liquid return valve, the filtering system comprises filtering, precoating filtering, filter cake recycling and filter cake washing, the running state of each program is observed by a sight glass, and particles with the particle size of more than 1 mu m in the geothermal fluid are removed through a filter aid;

5) the well head multifunctional conversion technology comprises the following steps: geothermal water enters a geothermal cascade utilization system, and tail water is utilized by heat exchange and returned to the recharge well; the recharging wellhead is additionally provided with a wellhead sealing device, the wellhead sealing device is a four-way wellhead device, a flange and a ball valve are arranged on the wellhead sealing device around an oil pipe in the middle of the wellhead, and the opening and closing of the flange and the ball valve in different modes realize different functions; an oil pipe is hung at the wellhead, when the recharge quantity is reduced, a high-pressure fan is used for gas lift well washing, and a valve device is arranged on a gas lift drainage pipeline to control the pressure of the wellhead; a bypass pipeline and a valve are arranged at the well mouth, and the recharging pipeline is flushed through the bypass before geothermal tail water is recharged; the closed system prevents corrosion of the pipeline due to air intake;

6) data monitoring and collection technology: the recharging method is controlled and monitored by a PLC cabinet, and comprises the control and monitoring of the water temperature and water quantity of the production well and the recharging well, the control and monitoring of a filtering system, the real-time monitoring of the pressure of a system pipeline, and the remote transmission and processing of data.

The filter aid is diatomite.

Claims (2)

1. A sandstone thermal storage geothermal tail water efficient recharge method based on simulation comprises a well arrangement technology, an innovative well formation technology, an efficient water-gas separation technology, an accurate water quality processing technology, a well mouth multifunctional conversion technology and a data monitoring and acquisition technology based on simulation, and is characterized in that:

the recharging method comprises the following steps:

1) well spacing technology based on simulation: establishing a geothermal geological concept model, determining a model boundary condition, establishing a mathematical model, subdividing space and time, determining a simulation period and a prediction period, and performing simulation verification; analyzing the heat storage seepage capacity by using an actual model according to the heating area and combining the water yield of a single well, and determining the mining and irrigating proportion and the well spacing scheme;

2) the well forming technology is innovated: the whole well adopts a two-opening well-forming structure, the first mining drill bit with the diameter of 444.5mm is drilled to 400m, an oil casing pipe with the diameter of 339.7 multiplied by 9.65mm is put in, and well cementation and waiting are carried out; secondly, drilling a target layer through a 311mm diameter drill bit to form a well; running 244.5 x 8.94mm petroleum casing pipe from 400m to the top of the target reservoir, wherein the petroleum casing pipe comprises a 300m all-welded stainless steel wire-wound screen pipe; installing a hanger at a position of 400m, setting a 244.5mm sleeve, wherein the sleeve comprises two external packers and a blind plate, cementing the position of the sleeve from the upper part of a main thermal reservoir to the position of 400m after the sleeve is set, returning cement to the position of 400m, completing a target thermal reservoir to the bottom of a well by adopting a sieve tube, stopping water between each aquifer by using a rubber umbrella, and leaving a 20m sand-settling pipe at the bottom of the well;

3) the high-efficiency water-gas separation technology comprises the following steps: after geothermal water reaches a ground machine room through a geothermal exploitation well, sand removal and gas separation are carried out through a water-gas separation device, the water-gas separation device comprises an exhaust port, a tank body with a built-in rotary blade, a geothermal water inlet, a pressure transmitter, a frequency converter with a control system, a magnetic column-turning liquid level meter, a sand bag and a sand valve, the magnetic column-turning liquid level meter and a liquid level transmitter are installed outside the tank body, the magnetic column-turning liquid level meter observes the water level inside the tank body, the liquid level transmitter provides a signal for the frequency converter, and the liquid level transmitter adjusts the water quantity of a geothermal water pump through the frequency converter; the gravel stored in the sand bag is periodically removed manually;

4) an accurate water quality treatment technology: the geothermal water enters a diatomite intelligent visual filtering system, the filtering system comprises a precoating tank, a slag discharging tank, a clear liquid tank, a bottom valve, an exhaust valve, an overflow valve, a circulating valve and a residual liquid return valve, the filtering system comprises filtering, precoating filtering, filter cake recycling and filter cake washing, the running state of each program is observed by a sight glass, and particles with the particle size of more than 1 mu m in the geothermal fluid are removed through a filter aid;

5) the well head multifunctional conversion technology comprises the following steps: geothermal water enters a geothermal cascade utilization system, and tail water is utilized by heat exchange and returned to the recharge well; the recharging wellhead is additionally provided with a wellhead sealing device, the wellhead sealing device is a four-way wellhead device, a flange and a ball valve are arranged on the wellhead sealing device around an oil pipe in the middle of the wellhead, and the opening and closing of the flange and the ball valve in different modes realize different functions; an oil pipe is hung at the wellhead, when the recharge quantity is reduced, a high-pressure fan is used for gas lift well washing, and a valve device is arranged on a gas lift drainage pipeline to control the pressure of the wellhead; a bypass pipeline and a valve are arranged at the well mouth, and the recharging pipeline is flushed through the bypass before geothermal tail water is recharged; the closed system prevents corrosion of the pipeline due to air intake;

6) data monitoring and collection technology: the recharging method is controlled and monitored by a PLC cabinet, and comprises the control and monitoring of the water temperature and water quantity of the production well and the recharging well, the control and monitoring of a filtering system, the real-time monitoring of the pressure of a system pipeline, and the remote transmission and processing of data.

2. The sandstone heat storage geothermal tail water efficient recharge method based on simulation of claim 1, which is characterized in that: the filter aid is diatomite.