CN214172590U - Intelligent recharge control system for geothermal well group - Google Patents

Abstract

The invention provides an intelligent recharge control system for a geothermal well group, which comprises a plurality of geothermal wells, a water collector, a plate heat exchanger, a water separator and a heat pump host, wherein a water taking pump is arranged in each geothermal well, the water outlet ends of the water taking pumps are respectively communicated with the water inlet end of the water collector through pipelines, the water outlet end of the water collector is communicated with the water inlet end of the water separator through the plate heat exchanger, and the plate heat exchanger is connected with the heat pump host; a plurality of recharge pumps are arranged at the water outlet end of the water separator, the recharge pumps are arranged in one-to-one correspondence with the geothermal wells, and a balance pipe is arranged between the water separator and the water collector; the water outlet end of each recharge pump is communicated with the corresponding geothermal well through a pipeline; the water outlet end of each water taking pump is provided with a first flow meter and a conductivity meter; the water outlet end of each recharge pump is provided with a pressure gauge and a second flow meter; and a third flow meter is arranged on the balance pipe.

Description

Intelligent recharge control system for geothermal well group

Technical Field

The invention belongs to the technical field of geothermal energy utilization in a ground source heat pump system, and particularly relates to an intelligent recharge control system for a geothermal well group.

Background

As the largest developing countries in the world, china faces a series of problems such as environmental pollution, resource shortage, climate change and the like while the economy is developing at a high speed. Among them, the problem of resource shortage is particularly prominent.

The ground source heat pump system is characterized in that the geothermal energy is transferred from low-grade heat energy to high-grade heat energy by inputting a small amount of high-grade energy (such as electric energy). The geothermal energy is a pollution-free and renewable clean energy, the river, the lake and the sea belong to the category of shallow geothermal energy, and compared with traditional fossil energy such as coal, petroleum, natural gas and the like, the geothermal energy has the advantages of being huge in quantity, renewable, low in carbon, environment-friendly, available on site and the like. Geothermal energy development and utilization belong to the fifth 10 th 'ocean energy and geothermal energy utilization technology development and equipment manufacturing' encouragement in the industry structure adjustment instruction catalogue (2011) of the national development and improvement committee, are widely used in many fields of life heating, power generation, refrigeration, drying, chemical industry, planting and breeding industry, real estate development, tourism, recuperation and health care and the like, show increasingly wide application prospects, and are listed in the middle-long term development and planning of national renewable energy.

In the design of the existing geothermal well system, the arrangement that a water taking pump simultaneously has a recharging function is mostly adopted, and in the operation process of a geothermal well group, if the recharging amount of a part of geothermal wells is reduced due to blockage or other reasons, the pump consumption of the system is increased, and the operation stability of the whole geothermal well group system is finally influenced.

Disclosure of Invention

The invention aims to solve the defects in the background technology and provide an intelligent recharge control system for a geothermal well group.

The technical scheme adopted by the invention is as follows: the utility model provides a geothermal well crowd intelligence recharge control system which characterized in that: the system comprises a plurality of geothermal wells, a water collector, plate type heat exchangers, a water separator and a heat pump host, wherein a water taking pump is arranged in each geothermal well, the water outlet ends of the water taking pumps are respectively communicated with the water inlet end of the water collector through pipelines, the water outlet end of the water collector is communicated with the water inlet end of the water separator through the plate type heat exchangers, and the plate type heat exchangers are connected with the heat pump host; the water outlet end of the water separator is provided with a plurality of recharge pumps, the recharge pumps are arranged in one-to-one correspondence with the plurality of geothermal wells, and the water outlet end of each recharge pump is communicated with the corresponding geothermal well through a pipeline; a balance pipe is arranged between the water separator and the water collector; the outlet water of the geothermal water of each water taking pump is respectively collected to a water collector, the geothermal water entering the water collector exchanges heat through a plate heat exchanger to provide a cold and heat source for a heat pump host, and the geothermal water after heat exchange enters a water separator and is respectively refilled to corresponding geothermal wells by refilling pumps; the water outlet end of each water taking pump is provided with a first flow meter and a conductivity meter; the water outlet end of each recharge pump is provided with a pressure gauge and a second flow meter; a third flow meter is arranged on the balance pipe; and the controller drives the working states of each water taking pump and each recharging pump according to the required water taking amount and the measurement data of the first flowmeter, the conductivity meter pressure gauge, the second flowmeter and the third flowmeter.

In the technical scheme, the total water intake amount is calculated according to the energy consumption load, so that the number of the starting water intake pumps is selected; and selecting the number of the start-up recharging pumps according to the total water intake amount.

In the technical scheme, n geothermal wells are arranged, n water taking pumps are arranged, n recharge pumps are arranged, and the geothermal wells, the water taking pumps and the recharge pumps are all arranged in one-to-one correspondence; if the 1 st to i th water taking pumps are selected to be started according to the total water taking amount to pump geothermal water in the 1 st to i th geothermal wells, the (i +1) th to k th recharge pumps are selected to recharge the geothermal water to the (j +1) th to k th geothermal wells respectively; wherein n, j, k are integers greater than 0, and j, k < n.

In the technical scheme, the controller determines the total water intake quantity on the ground source side according to the running energy load, and calculates the quantity of water intake pumps and the quantity of recharging pumps which need to run in the initial state according to the total water intake quantity; calculating the number of water taking pumps and the number of recharging pumps which need to operate in an initial state; acquiring initial flow and actual flow of outlet pipes of a water taking pump and a recharging pump which operate in the ith station, and operating frequency of the water taking pump and the recharging pump which operate in the ith station correspondingly; acquiring actual values, minimum values and maximum values of the operating frequencies of an ith water taking pump and a recharging pump which are in operation; setting delay time after the outlet pressure of the ith recharging pump exceeds a set value, delay time after the running frequency is too high or too low, and delay time after the total flow of the outlet pipes of the water taking pump and the recharging pump which run is lower than the total flow of water taking; acquiring a set value and an actual value of the initial conductivity of an outlet pipe of an ith water taking pump, and a set value and an actual value of the initial pressure of an outlet pipe of an ith recharging pump; and calculating the flow rate increased by other running water taking pumps or recharging pumps after the jth water taking pump operates in a frequency reduction mode due to overlarge sediment content of the geothermal well water or the recharging pump operates in a frequency reduction mode due to well blockage, and obtaining the initial flow rate and the actual flow rate of outlet pipes of the jth water taking pump and the recharging pump.

A control method based on an intelligent recharge control system of a geothermal well group is characterized by comprising the following steps:

a. the controller judges that the conductivity of the outlet pipe of the water taking pump operated in the jth station is lower and the pressure of the outlet pipe of the recharging pump is too high to alarm;

b. the controller judges whether the actual value of the initial conductivity of the outlet pipe of the ith water taking pump is less than or equal to a set value or not and the delay time after the outlet pressure of the ith water taking pump exceeds the set value or not;

c. if the controller judges that the water intake pump is in the step b, adjusting the operation frequency of the ith water intake pump according to the actual value and the set value of the initial conductivity of the outlet pipe of the ith water intake pump, and selecting whether to stop the ith water intake pump and start the standby water intake pump or not based on the actual operation frequency of the ith water intake pump and the actual total flow rate of the running water intake pump;

d. if the controller judges no in the step b, adjusting the operation frequency of the ith water taking pump according to the actual value of the initial flow of the outlet pipe of the ith water taking pump, the initial flow of the outlet pipe of the jth water taking pump and the actual flow, and selecting whether to start the maximum frequency state of the ith water taking pump and start a standby water taking pump based on the actual operation frequency of the ith water taking pump and the actual total flow of the running water taking pumps;

e. the controller judges whether the actual value of the initial pressure of the outlet pipe of the ith recharging pump is larger than a set value or not and the delay time after the outlet pressure of the ith recharging pump exceeds the set value;

f. if the controller judges that the pressure value of the outlet pipe of the ith recharging pump is positive, the operation frequency of the ith recharging pump is adjusted according to the actual value and the set value of the initial pressure of the outlet pipe of the ith recharging pump, and whether the ith recharging pump is stopped or not and a standby recharging pump is started is selected based on the actual operation frequency of the ith recharging pump and the actual total flow of the running water taking pump;

g. and e, if the controller judges that the current flow rate of the outlet pipe of the ith recharging pump is not the same as the current flow rate of the outlet pipe of the jth recharging pump, adjusting the operation frequency of the ith recharging pump according to the initial flow rate of the outlet pipe of the ith recharging pump and the initial flow rate and the actual flow rate of the outlet pipe of the jth recharging pump, and selecting whether to start the maximum frequency state of the ith recharging pump and start a standby recharging pump based on the actual operation frequency of the ith recharging pump and the actual total flow rate of the running water taking pump.

In the above technical solution, step c specifically includes the following steps:

c1, the controller adjusts the actual operation frequency of the ith water pump according to the difference value between the set value and the actual value of the initial conductivity of the outlet pipe of the ith water pump, and receives the actual value of the initial conductivity of the outlet pipe of the ith water pump in real time after adjustment;

c2, if the actual value of the operation frequency of the ith water taking pump is less than or equal to the minimum value of the operation frequency of the ith water taking pump and the delay time after the operation frequency of the ith water taking pump is too high or too low is delayed, stopping the ith water taking pump; if the above condition is not satisfied, continuing to repeat step C1;

c3, stopping the ith water intake pump, judging whether the actual total flow of the water intake pumps in operation is less than the total water intake amount on the ground source side, and delaying the delay time after the total flow of the outlet pipes of the water intake pumps in operation is less than the total water intake flow; if yes, starting a standby water taking pump, and if not, ending the control flow.

In the above technical solution, step d specifically includes the following steps:

d1, the controller adjusts the actual operation frequency of the ith water taking pump according to the set value and the real-time detection value of the initial flow of the outlet pipe of the ith water taking pump and the flow increased by other running water taking pumps due to the fault of the jth water taking pump, and receives the adjusted real-time detection value of the flow of the outlet pipe of the ith water taking pump in real time;

d2, if the actual value of the operation frequency of the ith water taking pump is more than or equal to the maximum value of the operation frequency of the ith water taking pump and the delay time after the operation frequency of the ith water taking pump is too high or too low is delayed, operating the ith water taking pump at the maximum power; if the above condition is not met, continuing to repeat step D1;

d3, after the ith water intake pump is operated at the maximum power, judging whether the actual total flow of the water intake pump in operation is less than the total water intake quantity at the ground source side or not and delaying the delay time after the total flow of the outlet pipe of each operated water intake pump is less than the total water intake flow; if yes, starting a standby water taking pump, and if not, ending the control flow.

In the above technical solution, step f specifically includes the following steps:

f1, the controller adjusts the actual operating frequency of the ith recharging pump according to the difference value between the set value and the actual value of the initial pressure of the outlet pipe of the ith recharging pump, and receives the actual value of the initial pressure of the outlet pipe of the ith recharging pump after adjustment in real time;

f2, stopping the ith recharging pump if the actual value of the operating frequency of the ith recharging pump is less than or equal to the minimum value of the operating frequency of the ith recharging pump and the delay time is delayed after the operating frequency of the ith recharging pump is too high or too low; if the above condition is not satisfied, continuing to repeat step F1;

f3, after stopping the ith recharging pump, judging whether the actual total flow of the running recharging pump is less than the total water intake on the ground source side or not and delaying the delay time when the total flow of the outlet pipe of each running recharging pump is less than the total flow of the recharging pump; if yes, starting a standby recharging pump, and if not, ending the control flow.

In the above technical solution, step g specifically includes the following steps:

g1, the controller adjusts the actual operation frequency of the ith recharging pump according to the set value and the real-time detection value of the initial flow of the outlet pipe of the ith recharging pump and the flow which needs to be increased by other running recharging pumps due to the fault of the jth recharging pump, and receives the adjusted real-time detection value of the flow of the outlet pipe of the ith recharging pump in real time;

g2, if the actual value of the operation frequency of the ith recharging pump is more than or equal to the maximum value of the operation frequency of the ith recharging pump and the delay time after the operation frequency of the ith recharging pump is too high or too low is delayed, operating the ith recharging pump at the maximum power; if the above condition is not met, continuing to repeat step G1;

g3, after the ith recharging pump is operated at the maximum power, judging whether the actual total flow of the operating recharging pump is less than the total water intake on the ground source side or not and delaying the delay time after the total flow of the outlet pipe of each operating recharging pump is less than the total flow of the recharging pump; if yes, starting a standby recharging pump, and if not, ending the control flow.

The geothermal well water-taking and recharging system has the advantages that the water-taking pump and the recharging pump are independently arranged, the outlet of the water-taking pump is provided with the flowmeter and the conductivity meter, the outlet of the recharging pump is provided with the pressure sensor and the flowmeter, the water-taking state and the recharging state can be detected in real time, the water yield of the geothermal well can be accurately adjusted according to water yield parameters, meanwhile, the appropriate recharging water amount can be automatically set according to the recharging capacity of each recharging well, the pump consumption of the system is saved, and the efficiency and the energy are saved.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Wherein, 1: a water separator; 2: a water collector; 3: a plate heat exchanger; 4.1-4. i: a back-filling pump; 5.1-5. i: a first flow meter; 6.1-6. i: a geothermal well; 7.1-7. i: a conductivity meter; 8.1-8. i: a water taking pump; 9.1-9. i: a pressure gauge; 10.1-10. i: a second flow meter; 11: a balance tube; 12: and a third flow meter.

FIG. 2 is a water intake pump control flow chart;

FIG. 3 is a block diagram of a water intake pump control logic 1;

FIG. 4 is a block diagram of the water intake pump control logic 2;

wherein, F_{General assembly}The total water intake (m) of the ground source side³/h)；

F_{q amount of}For water intake pump rated flow (m)³/h)；

F_{h amount}Rated flow (m) for the recharge pump³/h)；

F_qyxActual total flow (m) for the running water intake pump³/h)；

F_hyxActual total flow (m) for running recharge pump³/h)；

F_qi0For the initial flow (m) of the outlet pipe of the ith water pump³/h)；

F_qiFor the actual flow (m) of the outlet pipe of the ith water pump³/h)；

ΔF_qjThe flow (m) increased by the water intake pumps in other operation is needed after the frequency of the jth water intake pump is reduced due to over-silt³/h)；F_hioFor the initial flow (m) of the outlet pipe of the ith recharging pump³/h)；

F_hiFor the actual flow (m) of the outlet pipe of the ith recharging pump³/h)；

ΔF_hjThe flow (m) increased by other running recharge pumps is needed after the jth recharge pump runs in a frequency-reducing mode due to well blockage³/h)

F_hj0For the outlet pipe initial flow (m) of the jth recharging pump³/h)；

F_hjFor the outlet pipe actual flow (m) of the jth recharging pump³/h)；

P_hi0Setting the initial pressure value (MPa) of the outlet pipe of the ith recharging pump;

P_hithe actual value (MPa) of the initial pressure of the outlet pipe of the ith recharging pump is obtained;

f_himinthe minimum value of the operation frequency (Hz) of the ith recharging pump is obtained;

f_himaxthe operation frequency of the ith recharging pump is the highestLarge value (Hz);

f_hithe actual operating frequency (Hz) of the ith recharging pump is calculated;

f_qiminthe minimum value (Hz) of the operation frequency of the ith water taking pump is obtained;

f_qimaxthe maximum value (Hz) of the operation frequency of the ith water taking pump is obtained;

f_qian actual operation frequency value (Hz) of the ith water taking pump;

σ_qi0setting the initial conductivity (S/m) of the outlet pipe of the ith water taking pump;

σ_qian initial conductivity actual value (S/m) of an outlet pipe of the ith water taking pump;

t_hi0the delay time(s) is the time after the pump outlet pressure of the ith recharging pump exceeds a set value;

t_hi1the delay time(s) after the operation frequency of the ith recharging pump is too high or too low is obtained;

t_hi2the delay time(s) after the total flow of the outlet pipe of the recharging pump for each operation is lower than the total flow of the water intake;

t_qi0the delay time(s) is set after the outlet pressure of the water pump of the ith station exceeds a set value;

t_qi1the delay time(s) is the delay time after the operation frequency of the ith water taking pump is too high or too low;

t_qi2the delay time(s) after the total flow of the water intake pump outlet pipe for each operation is lower than the total flow of the water intake;

roundup is an upward rounding function;

n is the total number of the water taking pump and the back-filling pump.

Detailed Description

The invention will be further described in detail with reference to the following drawings and specific examples, which are not intended to limit the invention, but are for clear understanding.

As shown in fig. 1, the invention provides an intelligent recharge control system for a geothermal well group, which is characterized in that: the system comprises a plurality of geothermal wells 6, a water collector 2, a plate type heat exchanger 3, a water distributor 1 and a heat pump host, wherein a water taking pump is arranged in each geothermal well 6, the water outlet ends of the water taking pumps 9 are respectively communicated with the water inlet end of the water collector 2 through pipelines, the water outlet end of the water collector 2 is communicated with the water inlet end of the water distributor 1 through the plate type heat exchanger 3, and the plate type heat exchanger 3 is connected with the heat pump host; the water outlet end of the water separator 1 is provided with a plurality of recharge pumps 4, the recharge pumps 4 are arranged in one-to-one correspondence with a plurality of geothermal wells 6, and the water outlet end of each recharge pump 4 is communicated with the corresponding geothermal well 6 through a pipeline; a balance pipe 11 is arranged between the water separator 1 and the water collector 2; the outlet water of the geothermal water of each water taking pump 9 is respectively collected to the water collector 2, the geothermal water entering the water collector 2 exchanges heat through the plate heat exchanger 3 to provide cold and heat sources for the heat pump host, and the geothermal water after heat exchange enters the water separator 1 and is respectively recharged to the corresponding geothermal wells 6 through the recharging pump 4; the water outlet end of each water taking pump 9 is provided with a first flow meter 5 and a conductivity meter 7; the water outlet end of each recharge pump 4 is provided with a pressure gauge 9 and a second flow meter 10; a third flow meter 12 is arranged on the balance pipe 11; the controller drives each water taking pump and each recharging pump according to the required water taking amount and the measurement data of the first flowmeter, the conductivity meter, the pressure meter, the second flowmeter and the third flowmeter

The water taking pumps 8.1-8. i are variable frequency water pumps, the total water taking amount is calculated according to energy consumption load, so that the number of the water taking pumps 8.1-8. i is selected to be started, the water taking pumps 8.1-8.j are selected to operate, outlet water is collected to the water collector 2, water of the water collector 5 exchanges heat through the plate heat exchanger 3 to provide cold and heat sources for a heat pump host, geothermal water after heat exchange enters the water separator 1, a recharge pump 4.1-4. i is arranged at the outlet of the water separator 1, and the recharge pump 4.1-4. i is a variable frequency water pump. And selecting the number of the recharge pumps 4.1-4. i to be started according to the total water intake amount, selecting 4 (J +1) -4. k to be started so as to ensure 100% recharge, and recharging geothermal water in the water collector 5 to the corresponding geothermal wells 6 (J +1) -6. k through the recharge pumps 4 (J +1) -4. k respectively.

Firstly, the controller determines the total water intake F on the ground source side according to the number of the running hosts_{General assembly}Then, the number K of the water taking pumps which need to be operated in the initial state is respectively calculated by using the formulas (1) and (2)_qAnd the number K of the recharge pumps_h

Wherein, F_{q amount of}For water intake pump rated flow (m)³/h)；F_{h amount}Rated flow (m) for recharging pump³H); roundup is an ceiling function.

According to the obtained K_q、K_hThe initial flow rate set values F of the outlet pipes of the water taking pump and the recharging pump in the ith running stage can be respectively calculated by using the formulas (3) and (4)_qi0，F_hi0(and should be adjusted in real time according to the running states of other water pumps), the running frequency of the water taking pump and the recharging pump corresponding to the operation of the ith station is f_qi，f_hi。

The flow balance adjustment algorithm module of the water taking pump and the recharging pump mainly utilizes the formulas (5) and (6) and delta F_qjThe flow (m) increased by the water intake pumps in other operation is needed after the frequency of the jth water intake pump is reduced due to over-silt³/h)；ΔF_hjThe flow (m) increased by other running recharge pumps is needed after the jth recharge pump runs in a frequency-reducing mode due to well blockage³/h)；F_qiFor the ith (i is 1,2, 3 …) water pump outlet pipe actual flow (m)³/h)；F_hiFor the ith (i ═ 1,2, 3 …) actual flow rate of the outlet pipe of the recharging pump (m ═ 1,2, 3 …)³H); the actual flow of the outlet pipes of the water taking pump and the recharging pump is measured by a flowmeter

The actual total flow rate of the water-taking pump and the recharging pump which are in operation at the moment is (the number K of the pumps which are in operation at present is equal to K)_q-1)：

F_qyx＝F_q1+F_q2+……+F_qkFormula (7)

F_hyx＝F_h1+F_h2+……+F_hkFormula (8)

Take the water intake pump and the recharge pump that are normally operated in the ith (i ≠ j, i ≦ n, j ≦ n) (the other pumps that normally operate refer to the control logic of this pump), and assume that the outlet pipe of the water intake pump that is operated in the jth has a lower conductivity and the outlet pipe of the recharge pump has an excessive pressure alarm (refer to the control logic of this pump if the other pumps have the same alarm signal). The control flow is as follows:

a control method of an intelligent recharge control system of a geothermal well group is characterized by comprising the following steps:

a. the controller judges that the conductivity of the outlet pipe of the water taking pump operated in the jth station is lower and the pressure of the outlet pipe of the recharging pump is too high to alarm; after data initialization, the controller calculates and acquires initial state information, rated state information and delay state information of the water taking pump and the back-filling pump.

b. The controller judges whether the actual value of the initial conductivity of the outlet pipe of the ith water taking pump is less than or equal to a set value or not and the delay time t after the outlet pressure of the ith water taking pump exceeds the set value_qi0；

c. And in the step b, if the controller judges that the water taking pump is operated according to the control logic 1 based on the conductivity set value. Adjusting the operating frequency of the ith water taking pump according to the actual value and the set value of the initial conductivity of the outlet pipe of the ith water taking pump, and selecting whether to stop the ith water taking pump and start a standby water taking pump or not based on the actual operating frequency of the ith water taking pump and the actual total flow of the operating water taking pump;

d. and in the step b, if the controller judges that the water taking pump does not work, the water taking pump works according to the control logic 2 based on the flow set value. Adjusting the operation frequency of the ith water taking pump according to the actual value of the initial flow of the outlet pipe of the ith water taking pump and the initial flow and the actual flow of the outlet pipe of the jth water taking pump, and selecting whether to start the maximum frequency state of the ith water taking pump and start a standby water taking pump based on the actual operation frequency of the ith water taking pump and the actual total flow of the running water taking pump;

e. the controller judges whether the actual value of the initial pressure of the outlet pipe of the ith recharging pump is larger than the set value or not and the delay time t after the outlet pressure of the ith recharging pump exceeds the set value_qi1；

f. If the controller judges that the pressure value is positive in the step e, the recharging pump operates according to the control logic 1 based on the pressure set value, the operation frequency of the ith recharging pump is adjusted according to the actual value of the initial pressure of the outlet pipe of the ith recharging pump and the set value, and whether the ith recharging pump is stopped or not and a standby recharging pump is started or not is selected based on the actual operation frequency of the ith recharging pump and the actual total flow of the water taking pump which is in operation;

g. and e, if the controller judges that the current flow is not the maximum frequency, the recharging pump operates according to the control logic 2 based on the flow set value, the operation frequency of the ith recharging pump is adjusted according to the initial flow of the outlet pipe of the ith recharging pump, the initial flow of the outlet pipe of the jth recharging pump and the actual flow, and whether the maximum frequency state of the ith recharging pump is started or not and the standby recharging pump is started is selected based on the actual operation frequency of the ith recharging pump and the actual total flow of the water taking pump which is in operation.

In the above technical solution, step c specifically includes the following steps:

c1, the PID controller adjusts the actual operation frequency of the ith water pump according to the difference value between the set value and the actual value of the initial conductivity of the outlet pipe of the ith water pump, and receives the actual value of the initial conductivity of the outlet pipe of the ith water pump after adjustment in real time to form a closed loop control process, as shown in FIG. 3;

c2, stopping the ith water pump if the actual value of the operation frequency of the ith water pump is less than or equal to the minimum value of the operation frequency of the ith water pump and the delay time after the operation frequency of the ith water pump is too high or too low is delayed; if the above condition is not satisfied, continuing to repeat step C1;

c3, stopping the ith water intake pump, judging whether the actual total flow of the water intake pumps in operation is less than the total water intake amount on the ground source side, and delaying the delay time after the total flow of the outlet pipes of the water intake pumps in operation is less than the total water intake flow; if yes, starting a standby water taking pump, and if not, ending the control flow.

In the above technical solution, step d specifically includes the following steps:

d1, the controller adjusts the actual operation frequency of the ith water pump according to the set value and the real-time detection value of the initial flow of the outlet pipe of the ith water pump and the flow (obtained by calculating by adopting a flow balance adjustment algorithm, namely formula 5) of the jth water pump which needs to be operated by other water pumps due to the fault of the jth water pump, and receives the adjusted real-time detection value of the flow of the outlet pipe of the ith water pump in real time to form a closed-loop control process, as shown in figure 4;

d2, if the actual value of the operation frequency of the ith water taking pump is more than or equal to the maximum value of the operation frequency of the ith water taking pump and the delay time after the operation frequency of the ith water taking pump is too high or too low is delayed, operating the ith water taking pump at the maximum power; if the above condition is not met, continuing to repeat step D1;

d3, after the ith water intake pump is operated at the maximum power, judging whether the actual total flow of the water intake pump in operation is less than the total water intake quantity at the ground source side or not and delaying the delay time after the total flow of the outlet pipe of each operated water intake pump is less than the total water intake flow; if yes, starting a standby water taking pump, and if not, ending the control flow.

In the above technical solution, step f specifically includes the following steps:

f1, the controller adjusts the actual operating frequency of the ith recharging pump according to the difference value between the set value and the actual value of the initial pressure of the outlet pipe of the ith recharging pump, and receives the adjusted actual value of the initial pressure of the outlet pipe of the ith recharging pump in real time to form a closed-loop control process;

f2, stopping the ith recharging pump if the actual value of the operating frequency of the ith recharging pump is less than or equal to the minimum value of the operating frequency of the ith recharging pump and delaying the delay time after the operating frequency of the ith recharging pump is too high or too low; if the above condition is not satisfied, continuing to repeat step F1;

f3, after stopping the ith recharging pump, judging whether the actual total flow of the running recharging pump is less than the total water intake on the ground source side or not and delaying the delay time after the total flow of the outlet pipe of each running recharging pump is less than the total flow of the recharging pump; if yes, starting a standby recharging pump, and if not, ending the control flow.

In the above technical solution, step g specifically includes the following steps:

g1, the controller adjusts the actual operation frequency of the ith recharge pump according to the set value and the real-time detection value of the initial flow of the outlet pipe of the ith recharge pump and the flow (obtained by adopting a flow balance adjustment algorithm, namely formula 6) of the recharge pump which needs to be operated by other pumps due to the fault of the jth recharge pump, and receives the adjusted real-time detection value of the flow of the outlet pipe of the ith recharge pump in real time to form a closed-loop control process;

g2, if the actual value of the operation frequency of the ith recharging pump is more than or equal to the maximum value of the operation frequency of the ith recharging pump and the delay time after the operation frequency of the ith recharging pump is too high or too low is delayed, operating the ith recharging pump at the maximum power; if the above condition is not met, continuing to repeat step G1;

g3, after the ith recharging pump is operated at the maximum power, judging whether the actual total flow of the operating recharging pump is less than the total water intake on the ground source side or not and delaying the delay time after the total flow of the outlet pipe of each operating recharging pump is less than the total flow of the recharging pump; if yes, starting a standby recharging pump, and if not, ending the control flow

Those not described in detail in this specification are within the skill of the art.

Claims (1)

1. The utility model provides a geothermal well crowd intelligence recharge control system which characterized in that: the system comprises a plurality of geothermal wells, a water collector, plate type heat exchangers, a water separator and a heat pump host, wherein a water taking pump is arranged in each geothermal well, the water outlet ends of the water taking pumps are respectively communicated with the water inlet end of the water collector through pipelines, the water outlet end of the water collector is communicated with the water inlet end of the water separator through the plate type heat exchangers, and the plate type heat exchangers are connected with the heat pump host; the water outlet end of the water separator is provided with a plurality of recharge pumps, the recharge pumps are arranged in one-to-one correspondence with the plurality of geothermal wells, and the water outlet end of each recharge pump is communicated with the corresponding geothermal well through a pipeline; a balance pipe is arranged between the water separator and the water collector; the outlet water of the geothermal water of each water taking pump is respectively collected to a water collector, the geothermal water entering the water collector exchanges heat through a plate heat exchanger to provide a cold and heat source for a heat pump host, and the geothermal water after heat exchange enters a water separator and is respectively refilled to corresponding geothermal wells by refilling pumps; the water outlet end of each water taking pump is provided with a first flow meter and a conductivity meter; the water outlet end of each recharge pump is provided with a pressure gauge and a second flow meter; a third flow meter is arranged on the balance pipe; the controller is electrically connected with the first flowmeter, the conductivity meter pressure gauge, the second flowmeter and the third flowmeter.

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