阅读说明：本技术 一种中深层地热能同井均衡采灌换热系统及应用 (Medium-deep geothermal energy same-well balanced mining and irrigating heat exchange system and application ) 是由 魏巍 于 2020-12-31 设计创作，主要内容包括：本发明涉及一种中深层地热能同井均衡采灌换热系统,包括设置在地面的热泵机组及与该热泵机组联通使用的地下换热组件,地下换热组件包括内层套管和外层套管,内层套管安装在地热井中,贯穿浅层低温地热层、中层高温地热层及含水层至地热井底的深层高温地热层的上方,外层套管同轴套装在内层套管外,安装在地热井壁和内层套管之间,贯穿浅层低温地热层至中层高温地热层的上方。将本系统应用于冬季采暖和夏季排热模式中,创新冬季“内注外出”的取热模式,不需对地热井结构进行特殊设计,也不需改变已有地热井的井身结构,总体施工难度低,既适合新建地热井又可对已有地热井进行改造,同时适用于少水或无水的地热干井。(The invention relates to a medium-deep geothermal energy same-well balanced mining and filling heat exchange system which comprises a heat pump unit arranged on the ground and an underground heat exchange assembly communicated with the heat pump unit, wherein the underground heat exchange assembly comprises an inner-layer sleeve and an outer-layer sleeve, the inner-layer sleeve is arranged in a geothermal well and penetrates through a shallow low-temperature geothermal layer, a middle-layer high-temperature geothermal layer and a water-containing layer to the upper part of a deep high-temperature geothermal layer at the bottom of the geothermal well, the outer-layer sleeve is coaxially sleeved outside the inner-layer sleeve and is arranged between a geothermal well wall and the inner-layer sleeve and penetrates through the shallow low-temperature geothermal layer to the upper part of the middle-layer high-. The system is applied to a winter heating mode and a summer heat removal mode, the heat removal mode of 'inside injection and outside injection' in winter is innovated, the structure of the geothermal well is not required to be specially designed, the well body structure of the existing geothermal well is not required to be changed, the overall construction difficulty is low, and the system is suitable for not only newly building the geothermal well but also reforming the existing geothermal well and is also suitable for a geothermal dry well with little water or no water.)

1. The utility model provides a well balanced production and irrigation heat transfer system of middle and deep layer geothermal energy which characterized in that: the underground heat exchange assembly comprises an inner sleeve and an outer sleeve, wherein the inner sleeve is arranged in a geothermal well and penetrates through a shallow low-temperature geothermal layer, a middle-layer high-temperature geothermal layer and a water-containing layer to the position above a deep high-temperature geothermal layer at the bottom of the geothermal well, and the outer sleeve is coaxially sleeved outside the inner sleeve and is arranged between a geothermal well wall and the inner sleeve and penetrates through the position above the shallow low-temperature geothermal layer and the middle-layer high-temperature geothermal layer.

2. The medium-deep geothermal energy same-well balanced production and irrigation heat exchange system according to claim 1, characterized in that: the inner side of the one-way valve is tightly connected with the outer wall of the inner casing, the outer side of the one-way valve is tightly connected with the wall of the geothermal well, the opening and closing direction of the one-way valve is determined by the water flow direction, the water flow is opened from bottom to top, and the water flow is closed from top to bottom.

3. The medium-deep geothermal energy same-well balanced production and irrigation heat exchange system according to claim 1, characterized in that: the aquifer is provided with an aquifer inlet and an aquifer outlet respectively, and a resistance piece is arranged between the aquifer inlet and the aquifer outlet.

4. The medium-deep geothermal energy same-well balanced production and irrigation heat exchange system according to claim 3, characterized in that: the resistance piece is formed by two branch ends formed by reducing the diameter of a central sleeve, convex blocks with grooves are detachably arranged on the side of the two branch ends, and rubber gaskets are arranged between the convex blocks with the grooves and the geothermal well wall.

5. The medium-deep geothermal energy same-well balanced production and irrigation heat exchange system according to claim 1, characterized in that: a submersible water pump is arranged between the outer casing and the inner casing.

6. The medium-deep geothermal energy same-well balanced production and irrigation heat exchange system according to claim 1, characterized in that: a recharging booster pump and a filter are arranged between the heat pump unit and the underground heat exchange assembly.

7. The application of the middle-deep geothermal energy same-well balanced extraction and irrigation heat exchange system is characterized in that: the heat taking mode of 'internal and external injection' in winter, the heat taking mode of 'internal and external injection' in summer and the heat taking mode of 'internal and external injection' in winter comprise a pressurizing recharging mode and a natural recharging mode.

8. The application of the middle-deep geothermal energy same-well balanced production and irrigation heat exchange system as claimed in claim 7, is characterized in that:

the heat taking mode of 'inside-out' in winter and the heat collecting and utilizing process of the pressurizing recharge type are as follows: circulating water after heat release flows out of the heat pump unit, is pressurized by a recharge booster pump and then enters the inner casing to directly reach the bottom of the geothermal well, and conducts heat conduction and exchange with a deep high-temperature geothermal layer at the bottom of the geothermal well to complete the preheating process; circulating water after sufficient heat exchange flows out of the aquifer through the aquifer outlet under the action of the submersible water pump, passes through the one-way valve, enters the outer-layer sleeve, and then enters the heat pump unit through the filter to finish the heat collection process.

9. The application of the middle-deep geothermal energy same-well balanced production and irrigation heat exchange system as claimed in claim 7, is characterized in that:

in winter, in the heat taking mode of 'inside-out' mode, natural recharge type circulating water directly enters the inner-layer casing after flowing out of the heat pump unit, and recharge power of the system is the self gravity of the circulating water, the suction force of the submersible water pump and the pressure between the inner-layer water level and the outer-layer water level.

10. The application of the middle-deep geothermal energy same-well balanced production and irrigation heat exchange system as claimed in claim 7, is characterized in that: in the summer shallow layer heat release mode, circulating water after heat absorption flows out of the heat pump unit, is pressurized by the recharge booster pump and then enters the inner layer sleeve, and because the water flow direction in the one-way valve is from bottom to top, the circulating water cannot continuously flow downwards but enters the outer layer sleeve under the action of the recharge booster pump, heat carried in the circulating water is discharged into the shallow layer low-temperature geothermal layer, and then the circulating water enters the heat pump unit through the filter to complete circulation.

Technical Field

The invention belongs to the field of exploitation and utilization of geothermal resources, relates to an exploitation and utilization technology of geothermal resources in a middle-deep layer, and particularly relates to a middle-deep layer geothermal energy same-well balanced mining and filling heat exchange system and application thereof.

Background

Although geothermal energy is a generally accepted green energy source with environmental protection and economy, some technical problems exist in the application process: under certain stratum conditions, geothermal water is difficult to completely recharge; although the mode of one-mining and multiple-irrigation can solve the problem of recharge, the economy of the geothermal heating system is seriously affected, and the mode is just an expedient design.

The middle-deep geothermal energy has the characteristics of large reserve, wide distribution, stability, reliability, high availability ratio and the like, and becomes the key point of current geothermal development. However, the problems of water level reduction of a heat reservoir, insufficient water of a geothermal well, resource waste, environmental pollution and the like caused by incomplete recharging appear in the long-term traditional development mode of one-mining-one-recharging and one-mining-multiple-recharging, and the biggest bottleneck problem in the development of the geothermal energy in the middle and deep layers of China at present is caused because some places shut down the geothermal well which cannot be recharged completely.

Aiming at the problems, a new development technology of 'heat taking and water non-taking' of a single well is provided in the industry. However, in the existing research on the development of the new technology, a multi-purpose closed or open sleeve heat exchange system is adopted, the closed sleeve heat exchange system is mainly based on a single heat conduction type heat exchange mode, only the heat exchange is carried out by simply utilizing a well wall, the heat exchange area is small, the heat exchange performance of the system is low, and a large number of experiments and engineering cases show that the average stable heat exchange load is 250kW, which is related to the fact that the system adopts the heat exchange mode which mainly conducts heat, and is also related to the fact that the heat exchange is carried out by simply utilizing the well wall, and the heat exchange area is small; although the open sleeve heat exchange system realizes the heat exchange process combining convection and heat conduction and also expands the heat exchange area, the open sleeve heat exchange system has the problems of less time and area of heat exchange action of reinjection water, fluid strata in a water-bearing stratum and the like, small improvement on the heat exchange effect and the like. Therefore, one of the improvement directions of the technology is that the heat exchange process is expected to be developed into an aquifer or a stratum, and is changed into a heat exchange process combining convection and heat conduction, and meanwhile, the heat exchange area is expanded.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, provides a middle-deep geothermal energy same-well balanced mining and filling heat exchange system which is efficient and can not take water, realizes the efficient utilization of the middle-deep geothermal energy, solves the technical problems of poor heat exchange capability, low heat taking amount and the like in the existing single well that water is not taken when heat is taken, can realize 100% recharging, and has the advantages of good heat exchange effect, high heat taking amount, low requirement on well body structure and wide application range.

The technical problem to be solved by the invention is realized by adopting the following technical scheme:

the heat exchange system comprises a heat pump unit arranged on the ground and an underground heat exchange assembly communicated with the heat pump unit, wherein the underground heat exchange assembly comprises an inner sleeve and an outer sleeve, the inner sleeve is arranged in a geothermal well and penetrates through a shallow low-temperature geothermal layer, a middle-layer high-temperature geothermal layer and a water-containing layer to the upper part of a deep high-temperature geothermal layer at the bottom of the geothermal well, the outer sleeve is coaxially sleeved outside the inner sleeve and is arranged between a geothermal well wall and the inner sleeve and penetrates through the shallow low-temperature geothermal layer to the upper part of the middle-layer high-temperature geothermal layer.

And a one-way valve is arranged at the boundary of the shallow low-temperature geothermal layer and the middle high-temperature geothermal layer, the inner side of the one-way valve is tightly connected with the outer wall of the inner sleeve, the outer side of the one-way valve is tightly connected with the wall of the geothermal well, the opening and closing direction of the one-way valve is determined by the water flow direction, the water flow is opened from bottom to top, and the water flow is closed from top to bottom.

The aquifer is provided with an aquifer inlet and an aquifer outlet, and a resistance member is attached between the aquifer inlet and the aquifer outlet.

And the resistance piece is formed into two branch ends by the diameter change of the central sleeve, convex blocks with grooves are detachably arranged on the side of the two branch ends, and a rubber gasket is arranged between the convex blocks with grooves and the geothermal well wall.

And a submersible water pump is arranged between the outer-layer sleeve and the inner-layer sleeve.

And a recharging booster pump and a filter are arranged between the heat pump unit and the underground heat exchange assembly.

The application of the middle-deep layer geothermal energy same-well balanced extraction and injection heat exchange system comprises an internal injection and external extraction mode in winter and a shallow layer heat release mode in summer, wherein the internal injection and external extraction mode in winter comprises a pressurization recharge mode and a natural recharge mode.

Moreover, in winter, the heat taking mode of 'inside-out and outside-out' and the heat collecting and utilizing process of the pressurizing recharging type are as follows: circulating water after heat release flows out of the heat pump unit, is pressurized by a recharge booster pump and then enters the inner casing to directly reach the bottom of the geothermal well, and conducts heat conduction and exchange with a deep high-temperature geothermal layer at the bottom of the geothermal well to complete the preheating process; circulating water after sufficient heat exchange flows out of the aquifer through the aquifer outlet under the action of the submersible water pump, passes through the one-way valve, enters the outer-layer sleeve, and then enters the heat pump unit through the filter to finish the heat collection process.

In addition, in the heat taking mode of 'inside-out' in winter, natural recharging type circulating water directly enters the inner-layer sleeve after flowing out of the heat pump unit, and recharging power of the system is the self gravity of the circulating water, the suction force of the submersible water pump and the pressure between the inner-layer water level and the outer-layer water level.

In the shallow heat release mode in summer, the circulating water after heat absorption flows out of the heat pump unit and enters the inner-layer sleeve after being pressurized by the recharge booster pump, and because the water flow direction in the one-way valve is from bottom to top, the circulating water cannot continuously flow downwards but enters the outer-layer sleeve under the action of the recharge booster pump, heat carried in the circulating water is discharged into the shallow low-temperature geothermal layer, and then the circulating water enters the heat pump unit through the filter to complete circulation.

The invention has the advantages and positive effects that:

1. the outer sleeve is additionally arranged in the middle-deep geothermal energy same-well balanced production and irrigation heat exchange system, water between the outer sleeve and a well wall does not flow when heat is taken in winter, a water area heat insulation layer can be formed, heat loss of circulating water after heat exchange in a water outlet process is reduced, heat taking quantity of the system is improved, and meanwhile, the outer sleeve is additionally arranged to form a new heat taking mode of 'internal injection and external outlet'.

2. The middle-deep geothermal energy same-well balanced extraction and injection heat exchange system breaks through the winter heat extraction mode of the existing closed or open single-well heat extraction system with 'external injection and internal discharge', the 'internal injection and external discharge' is adopted to change the flow direction of the recharge circulating water in the geothermal well, the low-temperature recharge circulating water directly reaches the bottom of the well through the inner casing pipe, is immersed in the aquifer under the action of the recharge pressure and the resistance piece for heat exchange, the flow rate of the recharge circulating water is reduced and the heat exchange area in the aquifer is increased under the influence of gravity and formation pressure, and the heat exchange effect is greatly improved.

3. The middle-deep geothermal energy same-well balanced mining and filling heat exchange system provided by the invention can be transformed into a dual-purpose geothermal heat exchange system for heat mining in winter and heat removal in summer according to the requirements of users by adding the outer sleeve and the one-way valve, so that the requirements of heating in winter and air conditioning in summer can be met, the seasonal heat storage can be realized, and the economy and the stability of the single-well heat exchange system are improved.

4. The resistance part in the system of the invention is formed by reducing the diameter of the central sleeve into two branch ends, the side of the two branch ends is detachably provided with a convex block with a groove, and a rubber gasket is arranged between the convex block with the groove and the geothermal well wall. The resistance piece is installed on the ground before being discharged, welding or other mechanical structure connecting pieces in the central tube and the well wall are not needed, flowing of water in the tube is not affected, feasibility is high, operation cost is effectively saved, and working efficiency is improved.

5. The middle-deep geothermal energy same-well balanced extraction and irrigation heat exchange system provided by the invention does not need to specially design a geothermal well structure or change a well body structure of the existing geothermal well in the implementation process, does not need to completely separate and seal resistance pieces and one-way valves, is connected with an inner-layer sleeve through a simple mechanical structure, has low overall construction difficulty, is suitable for newly building the geothermal well and reforming the existing geothermal well, and is also suitable for a geothermal dry well with little water or no water.

6. The middle-deep geothermal energy same-well balanced mining and filling heat exchange system provided by the invention can select whether to set the recharge booster pump according to the conditions of the geothermal well structure, the recharge pressure, the heat load requirement and the like. For geothermal wells with good recharge conditions and low heat load requirements, a natural recharge type heat exchange system can be selected, and the complexity and the economic cost of the system can be reduced; for geothermal wells with the requirements of conditions such as recharge pressure limitation, high heat load requirements and the like, a pressure-boosting recharge type heat exchange system can be selected, the recharge effect of the system is improved, the heat exchange quantity of the system is further improved, and the method has high applicability.

7. The medium-deep geothermal energy same-well balanced production and irrigation heat exchange system provided by the invention can realize production and irrigation balance in the same geothermal well, meets the environmental protection requirement of the current geothermal development, and can respectively carry out technical transformation on a production well and a recharge well to reuse for the geothermal well which is shut down because of incomplete recharge.

Drawings

FIG. 1 is a diagram of a pressurized recharge type middle-deep geothermal energy balanced production and recharge heat recovery system in the same well;

FIG. 2 is a diagram of a natural recharge type middle-deep geothermal energy balanced production and recharge heat recovery system in the same well;

FIG. 3 is a diagram of a pressurized recharge type middle-deep geothermal energy same-well balanced production, recharge and heat removal system;

FIG. 4 is an enlarged schematic view of one embodiment of a resistance element.

The reference numerals are explained below:

1. the device comprises a heat pump unit 2, a recharge booster pump 3, an inner layer sleeve 4, a water pumping submersible pump 5, an outer layer sleeve 6, a geothermal well wall 7, a one-way valve 8, a middle layer high-temperature geothermal layer 9, a water-containing layer outlet 10, a resistance piece 10-1, a convex block with a groove 10-2, a rubber gasket 11, a water-containing layer 12, a water-containing layer inlet 13, a deep layer high-temperature geothermal layer 14, a shallow layer low-temperature geothermal layer 15, a filter

Detailed Description

The present invention is further illustrated by the following specific examples, which are intended to be illustrative, not limiting and are not intended to limit the scope of the invention.

A middle-deep geothermal energy same-well balanced mining and filling heat exchange system comprises a heat pump unit 1 arranged on the ground and an underground heat exchange assembly communicated with the heat pump unit, wherein the underground heat exchange assembly comprises an inner-layer sleeve 3 and an outer-layer sleeve 5, the inner-layer sleeve is arranged in a geothermal well and penetrates through a shallow low-temperature geothermal layer 14, a middle-layer high-temperature geothermal layer 8 and a water-containing layer 11 to the position above a deep high-temperature geothermal layer 13 at the bottom of the geothermal well, the outer-layer sleeve is coaxially sleeved outside the inner-layer sleeve and is arranged between a geothermal well wall 6 and the inner-layer sleeve and penetrates through the shallow low-temperature geothermal layer to the position above the middle-layer high-temperature geothermal layer.

A one-way valve 7 is arranged at the boundary of the shallow low-temperature geothermal layer and the middle high-temperature geothermal layer, the inner side of the one-way valve is tightly connected with the outer wall of the inner casing, and the outer side of the one-way valve is tightly connected with the wall of a geothermal well.

The aquifer is provided with an aquifer inlet 12 and an aquifer outlet 9 respectively, a resistance piece 10 is arranged between the aquifer inlet and the aquifer outlet, the inner side of the resistance piece is connected with the outer wall of the inner casing pipe, and the outer side of the resistance piece is connected with the geothermal well wall.

A submersible water pump 4 is arranged between the outer casing and the inner casing.

A recharging booster pump 2 and a filter 15 are arranged between the heat pump unit and the underground heat exchange assembly.

Referring to fig. 4, an embodiment structure of the resistance element is that a central sleeve is reduced to form two branch ends, a convex block 10-1 with a groove is detachably arranged at the end side of each branch end, and a rubber gasket 1-2 is arranged between the convex block with the groove and a geothermal well wall.

Example 1

As shown in fig. 1, for a pressurized recharge type middle-deep geothermal energy same-well balanced production, irrigation and heat production cycle, a heat production water inlet channel is arranged inside an inner casing, a heat production water outlet channel is arranged in an annular space between the inner casing and an outer casing, and a water area heat insulation layer is arranged in an annular space between the outer casing and a geothermal well wall; the submersible water pump is arranged at the outlet of the hot water collecting and discharging channel and is immersed under the still water level in the hot water collecting and discharging channel; the one-way valve is arranged at the boundary of the shallow low-temperature geothermal layer and the middle-layer high-temperature geothermal layer, the inner side of the one-way valve is tightly connected with the outer wall of the inner casing, the outer side of the one-way valve is tightly connected with the wall of a geothermal well, and the flow direction of circulating water in the one-way valve is from bottom to top; the resistance piece is installed between aquifer entry and aquifer export, and the resistance piece inboard links to each other with inlayer sheathed tube outer wall, and the outside links to each other with the geothermol power wall of a well.

The booster recharging pump is arranged on a recharging trunk of a heat collecting water inlet channel connected with the heat pump unit and the inner layer sleeve, and the filter is arranged on a trunk of a heat pump unit water inlet channel.

Specifically, for a pressurized recharge type middle-deep layer geothermal energy same-well balanced production and recharge heat recovery system, the heat recovery and utilization processes are as follows: circulating water after heat release flows out of a heat pump unit, is pressurized by a recharge booster pump and then enters a heat collecting water inlet channel in an inner sleeve to reach the bottom of a geothermal well to conduct heat conduction and heat exchange with a deep high-temperature geothermal layer at the bottom of the geothermal well to complete the preheating process, because a resistance piece is arranged between the lower part of the inner sleeve and a geothermal well wall, the circulating water cannot flow upwards through a channel between the lower part of the inner sleeve and the geothermal well wall through the resistance piece, but enters a water-bearing layer from an inlet of the water-bearing layer under the suction action of a submersible water pump, and flows by overcoming the self gravity and the internal resistance of a stratum due to the fact that the flowing direction of the circulating water in the water-bearing layer is from bottom to top, the flowing speed of the circulating water is slow, and the transverse expansion area of the circulating water in the water-bearing layer is increased under the influence of the recharge booster pump, the submersible water pump and the difference between the, the heat is taken out and increased; circulating water after sufficient heat exchange flows out of an aquifer through an aquifer outlet under the action of a submersible water pump, passes through a one-way valve and then enters a heat collection water outlet channel, the submersible water pump is arranged at the outlet of the heat collection water outlet channel, so under the condition that the water level pressure difference is kept constant, the circulating water entering an overground heating unit from the submersible water pump comes from the one-way valve, a water area between an outer casing and a geothermal well wall is kept static and does not flow to form a stable water area heat insulation layer, further, the direct heat exchange between the circulating water and a shallow low-temperature geothermal layer is blocked, the heat loss in the heat collection process is reduced, the circulating water leaves the heat collection water outlet channel and enters the heat pump unit through a filter, the heat collection process is completed, and the filter is used for preventing impurities from entering the.

For the natural recharge type middle-deep geothermal energy same-well balanced production and irrigation heat recovery cycle shown in fig. 2, compared with an overground heating unit of a pressurized recharge type middle-deep geothermal energy same-well balanced production and irrigation heat recovery system, a recharge booster pump is omitted, circulating water directly enters a heat recovery water inlet channel after flowing out from a heat pump unit, the recharge power of the system is the self gravity of the circulating water, the suction force of a submersible water pump and the pressure between an inner layer water level and an outer layer water level, and the heat recovery process is similar to the pressurized recharge type middle-deep geothermal energy same-well balanced production and irrigation heat recovery system, and the details are not repeated here.

Example 2

As shown in fig. 3, the heat extraction cycle is a pressure-boosting recharge type middle-deep geothermal energy same-well balanced production and irrigation heat extraction cycle, and the heat extraction cycle process is as follows: circulating water after heat absorption flows out of a heat pump unit, the circulating water is pressurized by a recharge booster pump and then enters a heat extraction water inlet channel formed by an outer sleeve and an inner sleeve, the circulating water cannot continuously flow downwards due to the fact that the water flow direction in a one-way valve is from bottom to top, the circulating water enters the heat extraction water outlet channel formed by the outer sleeve and a geothermal well wall under the action of the recharge booster pump, heat carried in the circulating water is discharged to a shallow low-temperature geothermal layer, then the circulating water enters the heat pump unit through a filter to complete circulation, the temperature of the shallow low-temperature geothermal layer rises at the moment, the summer heat storage process of the system is achieved, the stored heat can be used for reducing heat exchange with a water area heat insulation layer when heat is collected in winter, and further the heat collection quantity is improved.

In view of the above technical solution, the following expected effects will be achieved:

1. the production and irrigation balance is realized in the same geothermal well, and the environmental protection requirement of the current geothermal development is met. For geothermal wells which cannot be completely recharged, the production wells and the recharging wells can be respectively technically transformed, so that the geothermal wells which are possibly closed can be reused. For the newly-built geothermal well adopting the technology, the requirement on the well body structure is reduced, and a recharging well does not need to be specially arranged.

2. High-efficiency heat exchange is realized in the same geothermal well, and the whole heat exchange coefficient and heat exchange area are improved through heat exchange in the water-containing layer. The conservative estimated heat exchange capacity is improved by more than 50% compared with a closed sleeve type heat exchange system, the stable heat exchange power of a single well is more than 240kW, and if the water yield and the temperature of the original well are higher, the heat exchange power is higher.

3. Can realize getting heat in winter and summer heat extraction in same geothermal well, satisfy winter heating and summer air conditioner demand, can realize striding season heat-retaining simultaneously, improve single well heat transfer system's economic nature and stability.

Although the embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that: various substitutions, changes and modifications are possible without departing from the spirit and scope of the invention and the appended claims, and therefore the scope of the invention is not limited to the embodiments disclosed.