CN103673116A - Energy-storage type fluorine pump heat pipe system and control method thereof - Google Patents

Abstract

The invention discloses an energy storage type fluorine pump heat pipe system and a control method thereof. The energy storage type fluorine pump heat pipe system includes a first indoor unit, a second indoor unit, an outdoor unit, a liquid storage tank, a fluorine pump, and an electric two-way valve , electric three-way valve, liquid pipe branch, gas pipe branch and controller, the control method of the energy storage type fluorine pump heat pipe system is through switching the fluorine pump, electric two-way valve, three-way reversing valve, electric three-way valve, The start and stop of the fan can realize the switching of various working conditions, which can not only ensure the temperature and humidity requirements of industrial buildings, but also ensure the thermal comfort requirements of commercial buildings. The invention makes full use of natural cooling sources and industrial waste heat, effectively improves energy utilization efficiency and indoor comfort, and reduces economical operating costs by utilizing low electricity prices at night.

Description

An energy storage type fluorine pump heat pipe system and its control method

technical field

The invention belongs to the field of air conditioning and new energy applications, and relates to an energy storage type fluorine pump heat pipe system and a control method thereof.

Background technique

At present, energy-saving air conditioners commonly used in industrial buildings include direct introduction of fresh air energy-saving systems, plate-type isolated air heat exchange systems, and heat pipe energy-saving systems. Although the direct introduction of the fresh air energy-saving system has a simple structure and a small volume, it requires frequent replacement of the filter, which is very expensive. Moreover, the humidity requirements in the computer room cannot be guaranteed. The plate-type isolated air heat exchange system has a large volume due to the small heat transfer per unit. This is mainly used in a large computer room; although the heat pipe energy-saving system has a simple structure and can directly use natural cooling sources, but the use of natural cooling sources The cycle is determined by the temperature difference between indoor and outdoor. When the temperature difference between indoor and outdoor cannot reach a certain level, the traditional compression refrigeration system is still used.

It can be seen from the above schemes that some schemes can achieve the purpose of energy saving to a certain extent, and make full use of natural cooling to improve energy utilization rate, but they do not use industrial waste heat.

Contents of the invention

The purpose of the present invention is to overcome the problems of low energy saving effect, complicated control and high energy consumption of the air conditioning system commonly used in industrial buildings in the prior art, and provide an energy storage type fluorine pump heat pipe system and its control method.

An energy storage type fluorine pump heat pipe system, including a first indoor unit 1, a second indoor unit 2, an outdoor unit 3, a first fluorine pump 4, a gas pipe branch 6, a liquid pipe branch 7, and a first electric three-way valve 9. The second electric three-way valve 10, the second electric two-way valve 12, a temperature sensor module, a communication module and a controller;

The first indoor unit 1 includes a first heat pipe phase change energy storage module 18, a heat exchanger 19, a first fan 20, a second fan 21, a first three-way reversing valve 22 and a second three-way reversing valve 23 A second three-way reversing valve 23 is provided on the connecting pipeline of one end of the first heat pipe phase change energy storage module 18 and the heat exchanger 19, and the first heat pipe phase change energy storage module 18 and the heat exchanger 19 The connecting pipeline at the other end is provided with a first three-way reversing valve 22;

The second indoor unit 2 includes a second heat pipe phase change energy storage module 24, an evaporator 25, a third fan 26, a fourth fan 27, a third three-way reversing valve 28 and a fourth three-way reversing valve 29, A fourth three-way reversing valve 29 is provided on the connecting pipeline between the second heat pipe phase change energy storage module 24 and one end of the evaporator 25, and the other end of the second heat pipe phase change energy storage module 24 and the evaporator 25 A third three-way reversing valve 28 is provided on the connecting pipeline;

The outlet n of the first electric three-way valve 9 is connected to the outdoor unit 3 through the trachea branch 6, and the outlet q and outlet p of the first electric three-way valve 9 are respectively connected to the first three-way reversing valve in the first indoor unit 1. The outlet j of 22 is connected with the outlet c of the third three-way reversing valve 28 in the second indoor unit 2;

The outlet z of the second electric three-way valve 10 is connected to the outdoor unit 3 through the liquid pipe branch 6, and the outlet y and outlet x of the first electric three-way valve 10 are respectively reversible with the second three-way in the first indoor unit 1. The valve 23 is connected to the fourth three-way reversing valve 29 in the second indoor unit 2, and the first fluorine pump 4 is provided on the liquid pipe branch 6;

The outdoor unit 3 includes a condenser 30 and a condensing fan 31;

The temperature sensor module includes a first temperature sensor arranged on the first indoor unit 1, a second temperature sensor on the second indoor unit 2 and a third temperature sensor on the outdoor unit 3. The first fluorine pump 4, The first electric three-way valve 9, the second electric three-way valve 10, the first three-way reversing valve 22, the second three-way reversing valve 23, the third three-way reversing valve 28, the fourth three-way reversing valve 29. The first fan 20, the second fan 21, the third fan 26, and the fourth fan 27 are all controlled by the controller, and the temperature sensor module is connected to the input end of the controller;

The first indoor unit 1 and the second indoor unit 2 include an air-conditioning system AC1 and an air-conditioning system AC2 respectively, and both the air-conditioning system AC1 and the air-conditioning system AC2 are controlled by a controller.

The first heat pipe phase change energy storage module 18 and the second heat pipe phase change energy storage module 24 mean that the heat exchange components in the heat pipe loop are embedded in the phase change material, and the outside is provided with a metal shell or a plastic shell.

The metal shell or the plastic shell is provided with an insulating layer.

The material of the insulation layer is polyurethane, polystyrene, aluminum silicate felt or rubber and plastic.

A sixth electric two-way valve 16 is provided between the second electric three-way valve 10 and the second three-way reversing valve 23, and a sixth electric two-way valve 16 is provided between the second electric three-way valve 10 and the fourth three-way reversing valve 29. A seventh electric two-way valve 17 is provided.

It also includes a liquid storage pipeline connected in parallel between the connection point of the second three-way reversing valve 23 and the sixth electric two-way valve 16 and between the connection point of the fourth three-way reversing valve 29 and the seventh electric two-way valve 17 , the second electric two-way valve 12, the second fluorine pump 5, the liquid storage tank 8 and the third electric two-way valve 13 are sequentially arranged on the liquid storage pipeline, the second electric two-way valve 12, the second fluorine pump 5 and the third electric two-way valve 13 are all controlled by the controller 32 .

The first fluorine pump 4 and the second fluorine pump 5 function as circulation pumps during the circulation process to transport liquid refrigerant working fluid.

The liquid storage tank 8 is used to store the working medium.

A fourth electric two-way valve 14 is arranged between the first electric three-way valve 9 and the third three-way reversing valve 28, and a fourth electric two-way valve 14 is arranged between the first electric three-way valve 9 and the first three-way reversing valve 22. A fifth electric two-way valve 15 is provided.

It also includes a switching line connected in parallel between the connection point between the first electric three-way valve 9 and the fourth electric two-way valve 14 and the connection point between the first electric three-way valve 9 and the fifth electric two-way valve 15, said A first electric two-way valve 11 is arranged on the switching pipeline, and the first electric two-way valve 11 , the fourth electric two-way valve 14 and the fifth electric two-way valve 15 are all controlled by the controller 32 .

A control method for an energy storage type fluorine pump heat pipe system. Based on the energy storage type fluorine pump heat pipe system, a temperature sensor module is used to detect the indoor temperature t _b of a commercial building, the indoor temperature t _a of an industrial building, and the outdoor temperature t _out . The second indoor unit 2 installed in an industrial building with waste heat generation, the first indoor unit 1 and outdoor unit 3 installed in a commercial building without waste heat generation are controlled as follows:

1) Industrial building refrigeration:

Step a: Detect the outdoor temperature t _out and the temperature inside the industrial building t _a :

When t _a -t _out <10°C, enter step b1; when t _a -t _out ≥10°C, enter step b2;

Step b1: When t _a ≥ t _set1 , go to step c; otherwise, return to step a, where t _set1 is the temperature setting value of the industrial building;

Step b2: when t _a ≥ t _hp-on , go to step d1; otherwise, go to step d2, where t _hp-on is the set value of the heat pipe cycle opening temperature;

Step c: turn on SHPS1 to discharge energy, when t _a ≥ t _set1 , go to step e1, and when t _a <t _set1 , go to step e2;

Step e1: turn on the industrial building AC1, when it is detected that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, return to step a, otherwise repeat step e1;

Step e2: Turn off SHPS1 to discharge energy, return to step a;

Step d1: Start the SHP0 cycle, when t _a <t _hp-off , enter step d2; when t _a ≥t _hp-off , repeat step d1;

Step d2: Start the SHP0" cycle and return to step a;

Turning on SHPS1 to release energy means to turn on the third fan 26 to cool down the heat pipe phase change module, and turning off SHPS1 to release energy means to turn off the third fan 26 so that the heat pipe phase change module stops cooling;

AC1 refers to the air conditioning system used in industrial buildings, controlled by the controller;

Said turning on the industrial building AC1 means turning on the air conditioning system AC1 for the industrial building;

Opening the SHP0 cycle refers to opening the fourth electric two-way valve 14 and the sixth electric two-way valve 16, opening the first electric three-way valve 9 and the second electric three-way valve 10, and connecting to the outlet b of the third three-way reversing valve 28 and outlet c, communicate with the fourth three-way reversing valve 29 outlet e and outlet f, open the fourth fan 27, condensing fan 31, and open the first fluorine pump 4;

Opening the SHP0" cycle refers to opening the fourth electric two-way valve 14 and the sixth electric two-way valve 16, opening the first electric three-way valve 9 and the second electric three-way valve 10, and connecting to the outlet of the third three-way reversing valve 28 a and outlet c, connected to the fourth three-way reversing valve 29 outlet d and outlet f, open the third fan 26, condensing fan 31, except the fourth electric two-way valve 14, the sixth electric two-way valve 16, the first electric two-way valve Three-way valve 9, second electric three-way valve 10, third three-way reversing valve 28, fourth three-way reversing valve 29, third fan 26 and valves other than condensing fan 31, fan and fluorine pump are all closed state;

2) Simultaneous cooling of industrial buildings and commercial buildings;

Step f: Detect the outdoor temperature t _out , the temperature inside the industrial building t _a and the temperature inside the commercial building t _b :

When t _a -t _out ≥10°C and t _b -t _out ≥10°C, enter step h1;

When t _a -t _out ≥10°C and t _b -t _out <10°C, go to step h2;

When t _a -t _out <10°C and t _b -t _out ≥10°C, go to step h3;

When t _a -t _out <10°C and t _b -t _out <10°C, go to step h4;

Step h1: when ta≥t _hp-on and t _b ≥t _hp-on , go to step i1;

When ta≥t _hp-on and t _b <t _hp-on , enter step i2;

When ta<t _hp-on and t _b ≥t _hp-on , go to step i3;

When ta<t _hp-on and t _b <t _hp-on , start the SHP5 cycle, otherwise return to step f;

Step h2: when t _b <t _set2 , return to step f, otherwise enter step j1;

When t _a ≥ _{t hp-on} , go to step j2, otherwise start the SHP0" cycle and return to step f; where t _set2 is the temperature set value of the first commercial building, and t _hp-on is the heat pipe cycle start temperature set value;

Step h3: when ta<t _set1 , return to step f, otherwise enter step j3;

When t _b ≥ _{t hp-on} , go to step j4, otherwise start the SHP1" cycle and return to step f; where t _set1 is the temperature setting value of the industrial building, and t _hp-on is the temperature setting value of the heat pipe cycle opening;

Step h4: when t _a <t _set1 , return to step f, otherwise, enter step j5; when t _b <t _set2 , return to step f, otherwise, enter step j6;

Step i1: Turn on SHP2 to detect the temperature t _a in the industrial building and the indoor temperature t _b in the commercial building:

When t _a ≥ t _hp-off and t _b ≥ t _hp-off , repeat step i1;

When t _a ≥ t _hp-off and t _b < t _hp-off , enter step i2;

When t _a <t _hp-off and t _b ≥t _hp-off , go to step i3;

When t _a <t _hp-off and t _b <t _hp-off , start the SHP5 cycle and return to step f;

Step i2: Turn on the SHP3 cycle, and then detect the temperature t _a in the industrial building. When t _a ≥ t _hp-off , repeat step i2, otherwise turn on SHP5 and return to step f;

Step i3: Start the SHP4 cycle, and then detect the temperature t _b in the office. When t _b ≥ t _hp-off , repeat step i3, otherwise, start the SHP5 cycle, and return to step f;

Step j1: Turn on SHPS2 to discharge energy, and then detect the temperature t _b in the commercial building: when t _b ≥ t _set2 , go to step k1, otherwise, turn off SHPS2 to discharge energy, and return to step f;

Step j2: Start the SHP0 cycle, detect the temperature t _a in the industrial building, and repeat step j2 when ta≥t _hp-off , otherwise start the SHP0" cycle, and return to step f;

Step j3: Turn on SHPS1 to discharge energy, and then detect the temperature t _a in the industrial building: when t _a ≥ t _set1 , turn off SHPS1 to discharge energy, and return to step f, otherwise, enter step k2;

Step j4: Start the SHP1 cycle to detect the temperature t _b in the commercial building. When t _b ≥ t _hp-on , repeat step j4; otherwise, start the SHP1" cycle and return to step f;

Step j5: Turn on SHPS1 to discharge energy, detect the temperature t _a in the industrial building, when t _a ≥ t _set1 , go to step k2, otherwise turn off SHPS1 to discharge energy, and return to step f;

Step j6: Turn on SHPS2 to discharge energy, detect the temperature t _b in the commercial building, and when t _b ≥ t _set2 , go to step k1, otherwise, turn off SHPS2 to discharge energy;

Step k1: Turn on the commercial building AC2 until it detects that the temperature inside the commercial building t _b ≤ t _set2 -2°C, turn off the commercial building AC2, otherwise repeat step k1;

Step k2: turn on the industrial building AC1 until it detects that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, otherwise repeat step k2;

The opening of the SHP1 cycle refers to opening the fifth electric two-way valve 15, the seventh electric two-way valve 17, the first electric three-way valve 9, the second electric three-way valve 10, and connecting the outlet of the second three-way reversing valve 23 m and outlet k are connected to outlet i and outlet h of the first three-way reversing valve 22, open the second fan 21, condensing fan 31, and open the first fluorine pump 4;

The opening of the SHP1" cycle refers to opening the fifth electric two-way valve 15, the seventh electric two-way valve 17, the first electric three-way valve 9, the second electric three-way valve 10, and connecting the second three-way reversing valve 23 The outlet m and the outlet j are connected to the outlet i and the outlet g of the first three-way reversing valve 22, the first fan 20 and the condensation fan 31 are turned on, and the first fluorine pump 4 is turned on;

The opening of the SHP2 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the outlet m and the outlet k of the second three-way reversing valve 23, connected to the outlet i and the outlet h of the first three-way reversing valve 22, and opens the fourth fan 27, the second fan 21, and the condensing fan 31 , start the first fluorine pump 4;

The opening of the SHPS2 to discharge energy refers to opening the first fan 20 to allow the heat pipe phase change module to cool down, and closing the SHPS2 to discharge energy is to turn off the first fan 20 to stop the heat pipe phase change module from cooling;

Said turning on the commercial building AC2 means turning on the air conditioning system AC2 for the commercial building;

The opening of the SHP3 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the outlet m and the outlet j of the second three-way reversing valve 23, connected to the outlet i and the outlet g of the first three-way reversing valve 22, and connected to the outlet b and the outlet c of the third three-way reversing valve 28 , connect the outlet e and outlet f of the fourth three-way reversing valve 22, open the fourth fan 27, the first fan 20, the condensation fan 31, and start the first fluorine pump 4;

The opening of the SHP4 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the second three-way reversing valve 23 outlet m and outlet k, connected to the first three-way reversing valve 22 outlet i and outlet h, and connected to the third three-way reversing valve 28 outlet a and outlet c , connect the outlet d and outlet f of the fourth three-way reversing valve 22, open the third fan 26, the second fan 21, the condensation fan 31, and open the first fluorine pump 4;

The opening of the SHP5 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the outlet m and the outlet j of the second three-way reversing valve 23, connected to the outlet i and the outlet g of the first three-way reversing valve 22, and connected to the outlet a and the outlet c of the third three-way reversing valve 28 , connect the outlet d and outlet f of the fourth three-way reversing valve 22, open the third fan 26, the first fan 20, the condensation fan 31, and open the first fluorine pump 4;

3) Industrial buildings need refrigeration, and commercial buildings need heating mode;

Step m: Detect the temperature t _a in the industrial building and the temperature t _b in the commercial building: when t _a -t _b <10°C, go to step n1, otherwise go to step n2;

Step n1: Simultaneously detect the temperature t _a in the industrial building and detect the temperature t _b in the commercial building:

When ta<t _set1 , return to step m, otherwise enter step s1;

When t _b <t _set3 , enter step s2, otherwise return to step m; wherein, t _set3 is the temperature setting value of the second commercial building;

Step n2: when t _a ≥ t _hp-on , go to step s3, otherwise start the SHP7 cycle and return to step m;

Step s1: Turn on SHPS1 to discharge energy, and then detect the temperature t _a in the industrial building: when t _a <t _set1 , turn off SHPS1 to discharge energy, and return to step m, otherwise, enter step p1;

Step s2: Turn on SHPS3 to discharge energy, and then detect the temperature t _b in the commercial building: when t _b <t _set1 , go to step p2, otherwise, turn off SHPS2 to discharge energy, and return to step m;

Step s3: Start the SHP6 cycle, detect the current time t: when τ∈τ ₁ and τ ₂ , go to step p3, otherwise go to step p4, where τ ₁ and τ ₂ are the start time of cooling or heating of commercial buildings respectively and end time;

Step p1: Turn on the industrial building AC1 until it detects that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, otherwise repeat step p1;

Step p2: Turn on the commercial building AC2 until the temperature t _b ≥ t _set3 +2°C in the commercial building is detected, then turn off the commercial building AC2, otherwise repeat step p2;

Step p3: Detect the temperature t _a in the industrial building: when t _a ≥ t _hp-off , return to step s3, otherwise, start the SHP7 cycle and return to step m;

Step p4: Start the SHP8 cycle, and detect the temperature t _a in the industrial building: when t _a ≥ t _hp-off , repeat step p4, otherwise start the SHP9 cycle, and return to step m;

The opening of the SHP6 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, and connecting the first electric two-way valve. Two three-way reversing valve 23 outlet m and outlet k, communicate with the first three-way reversing valve 22 outlet i and outlet h, communicate with the third three-way reversing valve 28 outlet b and outlet c, communicate with the fourth three-way reversing Valve 22 outlet e and outlet f, open the second fan 21, the fourth fan 27, open the second fluorine pump 5;

The opening of the SHP7 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, Two three-way reversing valve 23 outlet m and outlet k, communicate with the first three-way reversing valve 22 outlet i and outlet h, communicate with the third three-way reversing valve 28 outlet a and outlet c, communicate with the fourth three-way reversing Valve 22 outlet d and outlet f, open the second fan 21, the third fan 26, open the second fluorine pump 5;

The opening of the SHP8 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, Two three-way reversing valve 23 outlet m and outlet j, communicate with the first three-way reversing valve 22 outlet i and outlet g, communicate with the third three-way reversing valve 28 outlet b and outlet c, communicate with the fourth three-way reversing Valve 22 outlet e and outlet f, open the first fan 20, the fourth fan 27, open the second fluorine pump 5;

The opening of the SHP9 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, and the first electric two-way valve. Two three-way reversing valve 23 outlet m and outlet j, communicate with the first three-way reversing valve 22 outlet i and outlet g, communicate with the third three-way reversing valve 28 outlet a and outlet c, communicate with the fourth three-way reversing Valve 22 outlet d and outlet f, open the first fan 20, the third fan 26, open the second fluorine pump 5;

Turning on the SHPS3 to release energy refers to turning on the first blower 20 to make the heat pipe phase change module release heat.

Beneficial effect

Compared with the existing technology, the present invention fully combines the load characteristics of commercial buildings and industrial buildings, and invents an energy storage type fluorine pump heat pipe system. This system can not only directly transfer waste heat from industrial buildings to commercial buildings, reduce energy waste and achieve energy-saving effects, but also ensure a certain degree of thermal comfort in commercial buildings, and store excess heat in winter nights by utilizing low electricity prices at night In the phase change module, it can be used for heating during the day. In summer, the excess cold energy can be stored in the heat pipe phase change module for cooling during the day; direct heat pipe cooling using a natural cooling source or heat pipe using a natural cooling source Cold storage, prolonging the utilization cycle of natural cooling sources; the control method of the invention can accurately and quickly switch between different working conditions to extend the cycle of utilizing natural cooling sources, make full use of low electricity prices and improve the utilization rate of industrial waste heat, accurate and fast The control method has a significant effect on improving energy utilization.

Description of drawings

Figure 1 is a schematic diagram of the overall structure of the energy storage type fluorine pump heat pipe system of the present invention;

Fig. 2 is the block diagram of the control structure of the energy storage type fluorine pump heat pipe system of the present invention;

3 is a schematic diagram of a heat pipe phase change energy storage module of the present invention;

Fig. 4 is the control flow chart under the refrigeration mode of the industrial building of the present invention;

Fig. 5 is the control flow diagram under the refrigeration mode that both industrial building and commercial building of the present invention need;

Fig. 6 is a control flow chart of the present invention in the mode where cooling is required for industrial buildings and heating is required for commercial buildings.

Detailed ways

The present invention will be further described below in conjunction with accompanying drawings and examples.

As shown in Figures 1 and 2, an energy storage type fluorine pump heat pipe system includes a first indoor unit 1, a second indoor unit 2, an outdoor unit 3, a first fluorine pump 4, a gas pipe branch 6, and a liquid pipe branch Circuit 7, first electric three-way valve 9, second electric three-way valve 10, second electric two-way valve 12, temperature sensor module, communication module and controller;

The first indoor unit 1 includes a first heat pipe phase change energy storage module 18, a heat exchanger 19, a first fan 20, a second fan 21, a first three-way reversing valve 22 and a second three-way reversing valve 23 A second three-way reversing valve 23 is provided on the connecting pipeline of one end of the first heat pipe phase change energy storage module 18 and the heat exchanger 19, and the first heat pipe phase change energy storage module 18 and the heat exchanger 19 The connecting pipeline at the other end is provided with a first three-way reversing valve 22;

The second indoor unit 2 includes a second heat pipe phase change energy storage module 24, an evaporator 25, a third fan 26, a fourth fan 27, a third three-way reversing valve 28 and a fourth three-way reversing valve 29, A fourth three-way reversing valve 29 is provided on the connecting pipeline between the second heat pipe phase change energy storage module 24 and one end of the evaporator 25, and the other end of the second heat pipe phase change energy storage module 24 and the evaporator 25 A third three-way reversing valve 28 is provided on the connecting pipeline;

The outlet n of the first electric three-way valve 9 is connected to the outdoor unit 3 through the trachea branch 6, and the outlet q and outlet p of the first electric three-way valve 9 are respectively connected to the first three-way reversing valve in the first indoor unit 1. The outlet j of 22 is connected with the outlet c of the third three-way reversing valve 28 in the second indoor unit 2;

The outlet z of the second electric three-way valve 10 is connected to the outdoor unit 3 through the liquid pipe branch 6, and the outlet y and outlet x of the first electric three-way valve 10 are respectively reversible with the second three-way in the first indoor unit 1. The valve 23 is connected to the fourth three-way reversing valve 29 in the second indoor unit 2, and the first fluorine pump 4 is provided on the liquid pipe branch 6;

The outdoor unit 3 includes a condenser 30 and a condensing fan 31;

The temperature sensor module includes a first temperature sensor arranged on the first indoor unit 1, a second temperature sensor on the second indoor unit 2 and a third temperature sensor on the outdoor unit 3, the first fluorine pump 4, The first electric three-way valve 9, the second electric three-way valve 10, the first three-way reversing valve 22, the second three-way reversing valve 23, the third three-way reversing valve 28, the fourth three-way reversing valve 29. The first fan 20, the second fan 21, the third fan 26, and the fourth fan 27 are all controlled by the controller, and the temperature sensor module is connected to the input end of the controller;

The first indoor unit 1 and the second indoor unit 2 include an air-conditioning system AC1 and an air-conditioning system AC2 respectively, and both the air-conditioning system AC1 and the air-conditioning system AC2 are controlled by a controller.

As shown in Figure 3, the first heat pipe phase change energy storage module 18 and the second heat pipe phase change energy storage module 24 refer to the fact that the heat exchange components in the heat pipe loop are embedded in the phase change material, and the outside is provided with a metal shell or plastic shell.

Among them, the heat exchange component refers to the evaporation section or condensation section of the heat pipe. The feature of the heat pipe phase change energy storage module is to use the characteristics of the separated heat pipe, make full use of industrial waste heat and natural cold sources, and directly circulate the cold through the separated heat pipe. The evaporation section of the heat pipe is stored in the phase change module of the heat pipe or the heat is directly stored in the phase change module of the heat pipe through the condensation section of the separated heat pipe cycle. The system uses the principle of heat pipes, without a compressor, only the fluorine pump promotes the circulation of the refrigerant in the heat pipe, but the power of the fluorine pump is much smaller than that of the compressor, thus achieving the purpose of energy saving. Moreover, the system can directly transfer the waste heat of the industrial building to the commercial building through the heat pipe circulation, so that the waste heat recovery in the prior art reduces the loss of multi-stage transmission energy. The system can also make full use of peak and valley electricity prices to store cold or heat in the heat pipe phase change module in advance, so that the energy in the heat pipe phase change energy storage module can be released when needed to meet the temperature requirements of industrial buildings or commercial buildings.

The metal shell or the plastic shell is provided with an insulating layer.

The material of the insulation layer is polyurethane, polystyrene, aluminum silicate felt or rubber and plastic.

A sixth electric two-way valve 16 is provided between the second electric three-way valve 10 and the second three-way reversing valve 23, and a sixth electric two-way valve 16 is provided between the second electric three-way valve 10 and the fourth three-way reversing valve 29. A seventh electric two-way valve 17 is provided.

It also includes a liquid storage pipeline connected in parallel between the connection point of the second three-way reversing valve 23 and the sixth electric two-way valve 16 and between the connection point of the fourth three-way reversing valve 29 and the seventh electric two-way valve 17 , the second electric two-way valve 12, the second fluorine pump 5, the liquid storage tank 8 and the third electric two-way valve 13 are sequentially arranged on the liquid storage pipeline, the second electric two-way valve 12, the second fluorine pump 5 and the third electric two-way valve 13 are all controlled by the controller 32 .

The first fluorine pump 4 and the second fluorine pump 5 function as circulation pumps during the circulation process to transport liquid refrigerant working fluid.

The liquid storage tank 8 is used to store the working medium.

A fourth electric two-way valve 14 is arranged between the first electric three-way valve 9 and the third three-way reversing valve 28, and a fourth electric two-way valve 14 is arranged between the first electric three-way valve 9 and the first three-way reversing valve 22. A fifth electric two-way valve 15 is provided.

It also includes a switching line connected in parallel between the connection point between the first electric three-way valve 9 and the fourth electric two-way valve 14 and the connection point between the first electric three-way valve 9 and the fifth electric two-way valve 15, said A first electric two-way valve 11 is arranged on the switching pipeline, and the first electric two-way valve 11 , the fourth electric two-way valve 14 and the fifth electric two-way valve 15 are all controlled by the controller 32 .

A control method for an energy storage type fluorine pump heat pipe system. Based on the energy storage type fluorine pump heat pipe system, a temperature sensor module is used to detect the indoor temperature t _b of a commercial building, the indoor temperature t _a of an industrial building, and the outdoor temperature t _out . The second indoor unit 2 installed in an industrial building with waste heat generation, the first indoor unit 1 and outdoor unit 3 installed in a commercial building without waste heat generation are controlled as follows:

1) Industrial building refrigeration, as shown in Figure 4:

Step a: Detect the outdoor temperature t _out and the temperature inside the industrial building t _a :

When t _a -t _out <10°C, enter step b1; when t _a -t _out ≥10°C, enter step b2;

Step b1: When t _a ≥ t _set1 , go to step c; otherwise, return to step a, where t _set1 is the temperature setting value of the industrial building;

Step b2: when t _a ≥ t _hp-on , go to step d1; otherwise, go to step d2, where t _hp-on is the set value of the heat pipe cycle opening temperature;

Step c: turn on SHPS1 to discharge energy, when t _a ≥ t _set1 , go to step e1, and when t _a <t _set1 , go to step e2;

Step e1: turn on the industrial building AC1, when it is detected that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, return to step a, otherwise repeat step e1;

Step e2: Turn off SHPS1 to discharge energy, return to step a;

Step d1: Start the SHP0 cycle, when t _a <t _hp-off , enter step d2; when t _a ≥t _hp-off , repeat step d1;

Step d2: Start the SHP0" cycle and return to step a;

Turning on SHPS1 to release energy means to turn on the third fan 26 to cool down the heat pipe phase change module, and turning off SHPS1 to release energy means to turn off the third fan 26 so that the heat pipe phase change module stops cooling;

AC1 refers to the air conditioning system used in industrial buildings, controlled by the controller;

Said turning on the industrial building AC1 means turning on the air conditioning system AC1 for the industrial building;

Opening the SHP0 cycle refers to opening the fourth electric two-way valve 14 and the sixth electric two-way valve 16, opening the first electric three-way valve 9 and the second electric three-way valve 10, and connecting to the outlet b of the third three-way reversing valve 28 and outlet c, connected to outlet e and outlet f of the fourth three-way reversing valve 29, open the fourth fan 27, condensing fan 31, open the first fluorine pump 4, and other valves, fans and fluorine pump are in the closed state.

Opening the SHP0" cycle refers to opening the fourth electric two-way valve 14 and the sixth electric two-way valve 16, opening the first electric three-way valve 9 and the second electric three-way valve 10, and connecting to the outlet of the third three-way reversing valve 28 a and outlet c, connected to the fourth three-way reversing valve 29 outlet d and outlet f, open the third fan 26, condensing fan 31, except the fourth electric two-way valve 14, the sixth electric two-way valve 16, the first electric two-way valve Three-way valve 9, second electric three-way valve 10, third three-way reversing valve 28, fourth three-way reversing valve 29, third fan 26 and valves other than condensing fan 31, fan and fluorine pump are all closed state;

In the above operation mode, when the difference between the internal temperature t _a of the industrial building and the outdoor temperature t _out is greater than 10°C, the SHP0 cycle is started to make full use of the natural cold source for cooling the industrial building. The cooling capacity is stored in the heat pipe phase change energy storage module, when the difference between the temperature t _a in the industrial building and the outdoor temperature t _out is less than 10°C and the temperature t _a in the industrial building is greater than the set temperature value t _set1 in the industrial building , using SHPS1 to discharge can meet the temperature requirements of industrial buildings.

2) Simultaneous cooling of industrial buildings and commercial buildings, as shown in Figure 5;

Step f: Detect the outdoor temperature t _out , the temperature inside the industrial building t _a and the temperature inside the commercial building t _b :

When t _a -t _out ≥10°C and t _b -t _out ≥10°C, enter step h1;

When t _a -t _out ≥10°C and t _b -t _out <10°C, go to step h2;

When t _a -t _out <10°C and t _b -t _out ≥10°C, go to step h3;

When t _a -t _out <10°C and t _b -t _out <10°C, go to step h4;

Step h1: when ta≥t _hp-on and t _b ≥t _hp-on , go to step i1;

When ta≥t _hp-on and t _b <t _hp-on , enter step i2;

When ta<t _hp-on and t _b ≥t _hp-on , go to step i3;

When ta<t _hp-on and t _b <t _hp-on , start the SHP5 cycle, otherwise return to step f;

Step h2: when t _b <t _set2 , return to step f, otherwise enter step j1;

When t _a ≥ _{t hp-on} , go to step j2, otherwise start the SHP0" cycle and return to step f; where t _set2 is the temperature set value of the first commercial building, and t _hp-on is the heat pipe cycle start temperature set value;

Step h3: when ta<t _set1 , return to step f, otherwise enter step j3;

When t _b ≥ _{t hp-on} , go to step j4, otherwise start the SHP1" cycle and return to step f; where t _set1 is the temperature setting value of the industrial building, and t _hp-on is the temperature setting value of the heat pipe cycle opening;

Step h4: when t _a <t _set1 , return to step f, otherwise, enter step j5; when t _b <t _set2 , return to step f, otherwise, enter step j6;

Step i1: Turn on SHP2 to detect the temperature t _a in the industrial building and the indoor temperature t _b in the commercial building:

When t _a ≥ t _hp-off and t _b ≥ t _hp-off , repeat step i1;

When t _a ≥ t _hp-off and t _b < t _hp-off , enter step i2;

When t _a <t _hp-off and t _b ≥t _hp-off , go to step i3;

When t _a <t _hp-off and t _b <t _hp-off , start the SHP5 cycle and return to step f;

Step i2: Turn on the SHP3 cycle, and then detect the temperature t _a in the industrial building. When t _a ≥ t _hp-off , repeat step i2, otherwise turn on SHP5 and return to step f;

Step i3: Start the SHP4 cycle, and then detect the temperature t _b in the office. When t _b ≥ t _hp-off , repeat step i3, otherwise, start the SHP5 cycle, and return to step f;

Step j1: Turn on SHPS2 to discharge energy, and then detect the temperature t _b in the commercial building: when t _b ≥ t _set2 , go to step k1, otherwise, turn off SHPS2 to discharge energy, and return to step f;

Step j2: Start the SHP0 cycle, detect the temperature t _a in the industrial building, and repeat step j2 when ta≥t _hp-off , otherwise start the SHP0" cycle, and return to step f;

Step j3: Turn on SHPS1 to discharge energy, and then detect the temperature t _a in the industrial building: when t _a ≥ t _set1 , turn off SHPS1 to discharge energy, and return to step f, otherwise, enter step k2;

Step j4: Start the SHP1 cycle to detect the temperature t _b in the commercial building. When t _b ≥ t _hp-on , repeat step j4; otherwise, start the SHP1" cycle and return to step f;

Step j5: Turn on SHPS1 to discharge energy, detect the temperature t _a in the industrial building, when t _a ≥ t _set1 , go to step k2, otherwise turn off SHPS1 to discharge energy, and return to step f;

Step j6: Turn on SHPS2 to discharge energy, detect the temperature t _b in the commercial building, and when t _b ≥ t _set2 , go to step k1, otherwise, turn off SHPS2 to discharge energy;

Step k1: Turn on the commercial building AC2 until it detects that the temperature inside the commercial building t _b ≤ t _set2 -2°C, turn off the commercial building AC2, otherwise repeat step k1;

Step k2: turn on the industrial building AC1 until it detects that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, otherwise repeat step k2;

The opening of the SHP1 cycle refers to opening the fifth electric two-way valve 15, the seventh electric two-way valve 17, the first electric three-way valve 9, the second electric three-way valve 10, and connecting the outlet of the second three-way reversing valve 23 m and outlet k are connected to outlet i and outlet h of the first three-way reversing valve 22, open the second fan 21, condensing fan 31, and open the first fluorine pump 4;

The opening of the SHP1" cycle refers to opening the fifth electric two-way valve 15, the seventh electric two-way valve 17, the first electric three-way valve 9, the second electric three-way valve 10, and connecting the second three-way reversing valve 23 The outlet m and the outlet j are connected to the outlet i and the outlet g of the first three-way reversing valve 22, the first fan 20 and the condensation fan 31 are turned on, and the first fluorine pump 4 is turned on;

The opening of the SHP2 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the outlet m and the outlet k of the second three-way reversing valve 23, connected to the outlet i and the outlet h of the first three-way reversing valve 22, and opens the fourth fan 27, the second fan 21, and the condensing fan 31 , start the first fluorine pump 4;

The opening of the SHPS2 to discharge energy refers to opening the first fan 20 to allow the heat pipe phase change module to cool down, and closing the SHPS2 to discharge energy is to turn off the first fan 20 to stop the heat pipe phase change module from cooling;

Said turning on the commercial building AC2 means turning on the air conditioning system AC2 for the commercial building;

The opening of the SHP3 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the outlet m and the outlet j of the second three-way reversing valve 23, connected to the outlet i and the outlet g of the first three-way reversing valve 22, and connected to the outlet b and the outlet c of the third three-way reversing valve 28 , connect the outlet e and outlet f of the fourth three-way reversing valve 22, open the fourth fan 27, the first fan 20, the condensation fan 31, and start the first fluorine pump 4;

The opening of the SHP4 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the second three-way reversing valve 23 outlet m and outlet k, connected to the first three-way reversing valve 22 outlet i and outlet h, and connected to the third three-way reversing valve 28 outlet a and outlet c , connect the outlet d and outlet f of the fourth three-way reversing valve 22, open the third fan 26, the second fan 21, the condensation fan 31, and open the first fluorine pump 4;

The opening of the SHP5 cycle refers to opening the fourth electric two-way valve 14, the fifth electric two-way valve 15, the sixth electric two-way valve 16, the seventh electric two-way valve 17, the first electric three-way valve 9, the second The electric three-way valve 10 is connected to the outlet m and the outlet j of the second three-way reversing valve 23, connected to the outlet i and the outlet g of the first three-way reversing valve 22, and connected to the outlet a and the outlet c of the third three-way reversing valve 28 , connect the outlet d and outlet f of the fourth three-way reversing valve 22, open the third fan 26, the first fan 20, the condensation fan 31, and open the first fluorine pump 4;

In the above operation mode, when the difference between the temperature t _a and the outdoor temperature t _out of the industrial building and the difference between the temperature t _b and the outdoor temperature t _out of the commercial building are compared with 10°C, different cycle conditions are started in different situations, These mainly include the SHP2 cycle that uses natural cold sources to cool industrial buildings and commercial buildings, the SHP3 cycle that uses natural cold sources to cool industrial buildings and commercial buildings, and the SHP4 cycle that uses natural cold sources to store cold for industrial buildings and commercial buildings. Cycle, the SHP5 cycle that uses natural cold sources to store cold for both industrial buildings and commercial buildings, SHPS1 cooling conditions and SHPS2 cooling conditions. Relying on active and reliable control to ensure the efficient and reliable operation of the energy storage fluorine pump heat pipe system, it can not only ensure the temperature and humidity requirements of industrial buildings, but also ensure a certain degree of comfort in commercial buildings.

3) Industrial buildings need refrigeration, and commercial buildings need heating mode, as shown in Figure 6;

Step m: Detect the temperature t _a in the industrial building and the temperature t _b in the commercial building: when t _a -t _b <10°C, go to step n1, otherwise go to step n2;

Step n1: Simultaneously detect the temperature t _a in the industrial building and detect the temperature t _b in the commercial building:

When ta<t _set1 , return to step m, otherwise enter step s1;

When t _b <t _set3 , enter step s2, otherwise return to step m; wherein, t _set3 is the temperature setting value of the second commercial building;

Step n2: when t _a ≥ t _hp-on , go to step s3, otherwise start the SHP7 cycle and return to step m;

Step s1: Turn on SHPS1 to discharge energy, and then detect the temperature t _a in the industrial building: when t _a <t _set1 , turn off SHPS1 to discharge energy, and return to step m, otherwise, enter step p1;

Step s2: Turn on SHPS3 to discharge energy, and then detect the temperature t _b in the commercial building: when t _b <t _set1 , go to step p2, otherwise, turn off SHPS2 to discharge energy, and return to step m;

Step s3: Start the SHP6 cycle, detect the current time t: when τ∈τ ₁ and τ ₂ , go to step p3, otherwise go to step p4, where τ ₁ and τ ₂ are the start time of cooling or heating of commercial buildings respectively and end time;

Step p1: Turn on the industrial building AC1 until it detects that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, otherwise repeat step p1;

Step p2: Turn on the commercial building AC2 until the temperature t _b ≥ t _set3 +2°C in the commercial building is detected, then turn off the commercial building AC2, otherwise repeat step p2;

Step p3: Detect the temperature t _a in the industrial building: when t _a ≥ t _hp-off , return to step s3, otherwise, start the SHP7 cycle and return to step m;

Step p4: Start the SHP8 cycle, and detect the temperature t _a in the industrial building: when t _a ≥ t _hp-off , repeat step p4, otherwise start the SHP9 cycle, and return to step m;

The opening of the SHP6 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, and connecting the first electric two-way valve. Two three-way reversing valve 23 outlet m and outlet k, communicate with the first three-way reversing valve 22 outlet i and outlet h, communicate with the third three-way reversing valve 28 outlet b and outlet c, communicate with the fourth three-way reversing Valve 22 outlet e and outlet f, open the second fan 21, the fourth fan 27, open the second fluorine pump 5;

The opening of the SHP7 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, Two three-way reversing valve 23 outlet m and outlet k, communicate with the first three-way reversing valve 22 outlet i and outlet h, communicate with the third three-way reversing valve 28 outlet a and outlet c, communicate with the fourth three-way reversing Valve 22 outlet d and outlet f, open the second fan 21, the third fan 26, open the second fluorine pump 5;

The opening of the SHP8 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, Two three-way reversing valve 23 outlet m and outlet j, communicate with the first three-way reversing valve 22 outlet i and outlet g, communicate with the third three-way reversing valve 28 outlet b and outlet c, communicate with the fourth three-way reversing Valve 22 outlet e and outlet f, open the first fan 20, the fourth fan 27, open the second fluorine pump 5;

The opening of the SHP9 cycle refers to opening the first electric two-way valve 11, the second electric two-way valve 12, the third electric two-way valve 13, the fourth electric two-way valve 14, the fifth electric two-way valve 15, and the first electric two-way valve. Two three-way reversing valve 23 outlet m and outlet j, communicate with the first three-way reversing valve 22 outlet i and outlet g, communicate with the third three-way reversing valve 28 outlet a and outlet c, communicate with the fourth three-way reversing Valve 22 outlet d and outlet f, open the first fan 20, the third fan 26, open the second fluorine pump 5;

In the above operation mode, the difference between the temperature t _a in the industrial building and the temperature t _b in the commercial building is compared with that at 10°C. Different conditions start different cycle conditions, which mainly include using industrial waste heat as a heat source, and commercial buildings as a heat source. Cold source, SHP6 cycle for commercial building heating while cooling industrial buildings, industrial building cold storage, commercial building heating SHP7 cycle, industrial building refrigeration, commercial building heat storage SHP8 cycle and industrial building cold storage, commercial building storage Hot SHP9 loop. Through the switching of the control system, the efficient and reliable operation of the energy storage fluorine pump heat pipe system is ensured, and the industrial waste heat is transferred to commercial buildings to improve energy utilization.

Turning on the SHPS3 to release energy refers to turning on the first blower 20 to make the heat pipe phase change module release heat.

Selection of the phase change temperature of the phase change material in the heat pipe phase change module, the phase change temperature of the second heat pipe phase change module in industrial buildings is t _out <t _m1 <t _set1 , the phase change temperature of the first heat pipe phase change module in commercial buildings is The phase transition temperature is t _out <t _m2 <t _set2 and t _set3 <t _m2 <t _set1 (t _set3 <<t _set2 ).

t _set1 is the temperature setting value of the industrial building, which is set to 28°C; t _set2 is the temperature setting value of the first commercial building, and the value range is 26-28°C; t _set3 is the temperature setting value of the second commercial building, which is taken as The value range is 18-20°C; τ ₁ and τ ₂ are the start time 08:00 and the end time 18:00 of the cooling or heating of the commercial building, respectively.

In the above control process, the step "standby" shown in Figure 5 and Figure 6 means returning to the first step of the current control flow, when the steps "Close AC1", "Close AC2", "Open SHP5", "Close SHPS1 Discharge", "Disable SHPS2 Discharge", "Turn on SHP0", "Turn on SHP1", "Turn on SHP7" and "Turn on SHP9" as the last step in the control flow chart, all indicate that the next step is to return The first step of the current control flow.

Each set temperature value has a difference value, which is set to 1°C to prevent the frequent start and stop of the fluorine pump; the temperature sensors in industrial buildings and commercial buildings are installed in the return air of the indoor unit The outdoor temperature sensor is installed at the air inlet of the outdoor unit.

Claims (9)

1. An energy storage type fluorine pump heat pipe system, characterized in that it includes a first indoor unit (1), a second indoor unit (2), an outdoor unit (3), a first fluorine pump (4), and a tracheal branch (6), liquid pipe branch (7), first electric three-way valve (9), second electric three-way valve (10), second electric two-way valve (12), temperature sensor module, communication module and control device; The first indoor unit (1) includes a first heat pipe phase change energy storage module (18), a heat exchanger (19), a first fan (20), a second fan (21), a first three-way reversing valve (22) and the second three-way reversing valve (23), the second three-way reversing valve is provided on the connecting pipeline between the first heat pipe phase change energy storage module (18) and one end of the heat exchanger (19) (23), a first three-way reversing valve (22) is provided on the connecting pipeline between the first heat pipe phase change energy storage module (18) and the other end of the heat exchanger (19); The second indoor unit (2) includes a second heat pipe phase change energy storage module (24), an evaporator (25), a third fan (26), a fourth fan (27), a third three-way reversing valve ( 28) and the fourth three-way reversing valve (29), the fourth three-way reversing valve (29) is provided on the connecting pipeline between the second heat pipe phase change energy storage module (24) and one end of the evaporator (25) ), a third three-way reversing valve (28) is provided on the connecting pipeline between the second heat pipe phase change energy storage module (24) and the other end of the evaporator (25); The outlet n of the first electric three-way valve (9) is connected to the outdoor unit (3) through the trachea branch (6), and the outlet q and outlet p of the first electric three-way valve (9) are respectively connected to the first indoor unit (1 The outlet j of the first three-way reversing valve (22) in ) is connected to the outlet c of the third three-way reversing valve (28) in the second indoor unit (2); The outlet z of the second electric three-way valve (10) is connected to the outdoor unit (3) through the liquid pipe branch (6), and the outlet y and outlet x of the first electric three-way valve (10) are respectively connected to the first indoor unit ( The second three-way reversing valve (23) in 1) is connected to the fourth three-way reversing valve (29) in the second indoor unit (2), and the first fluorine pump is installed on the liquid pipe branch (6) (4); The outdoor unit (3) includes a condenser (30) and a condensation fan (31); The temperature sensor module includes a first temperature sensor arranged on the first indoor unit (1), a second temperature sensor on the second indoor unit (2) and a third temperature sensor on the outdoor unit (3), the The first fluorine pump (4), the first electric three-way valve (9), the second electric three-way valve (10), the first three-way reversing valve (22), the second three-way reversing valve (23), The third three-way reversing valve (28), the fourth three-way reversing valve (29), the first fan (20), the second fan (21), the third fan (26), and the fourth fan (27) all controlled by a controller, the temperature sensor module is connected to the input end of the controller; The first indoor unit (1) and the second indoor unit (2) respectively include an air conditioning system AC1 and an air conditioning system AC2, and both the air conditioning system AC1 and the air conditioning system AC2 are controlled by a controller. 2. The energy storage type fluorine pump heat pipe system according to claim 1, characterized in that, the first heat pipe phase change energy storage module (18) and the second heat pipe phase change energy storage module (24) refer to the heat pipe ring The heat exchange components in the circuit are embedded in the phase change material, and the outside is provided with a metal shell or a plastic shell. 3. The energy storage type fluorine pump heat pipe system according to claim 2, characterized in that an insulating layer is provided on the metal shell or the plastic shell. 4. The energy storage type fluorine pump heat pipe system according to claim 3, characterized in that, the insulation layer material is polyurethane, polystyrene, aluminum silicate felt or rubber and plastic. 5. The energy storage type fluorine pump heat pipe system according to claim 1, characterized in that a sixth electric motor is set between the second electric three-way valve (10) and the second three-way reversing valve (23). A two-way valve (16), a seventh electric two-way valve (17) is provided between the second electric three-way valve (10) and the fourth three-way reversing valve (29). 6. The energy storage type fluorine pump heat pipe system according to claim 5, further comprising a liquid storage pipeline connected in parallel to the second three-way reversing valve (23) and the sixth electric two-way valve (16) between the connecting point of the fourth three-way reversing valve (29) and the seventh electric two-way valve (17), the second electric two-way valve (12), the seventh Difluorine pump (5), liquid storage tank (8) and third electric two-way valve (13), second electric two-way valve (12), second fluorine pump (5) and third electric two-way valve (13 ) are controlled with the controller (32). 7. The energy storage type fluorine pump heat pipe system according to claim 6, characterized in that a fourth electric motor A two-way valve (14), a fifth electric two-way valve (15) is provided between the first electric three-way valve (9) and the first three-way reversing valve (22). 8. The energy storage type fluorine pump heat pipe system according to claim 7, characterized in that it further comprises a switching pipeline connected in parallel to the connection between the first electric three-way valve (9) and the fourth electric two-way valve (14) point and the connection point between the first electric three-way valve (9) and the fifth electric two-way valve (15), the switch pipeline is provided with a first electric two-way valve (11), the first electric two-way valve (11), the fourth electric two-way valve (14) and the fifth electric two-way valve (15) are all controlled by the controller (32). _9. A control method for an energy storage type fluorine pump heat pipe system, characterized in that, based on the energy storage type fluorine pump heat pipe system according to any one of claims 1-8, a temperature sensor module is used to detect the indoor temperature t of a commercial building , the indoor temperature t _a of the industrial building, and the outdoor temperature t _out , for the second indoor unit (2) installed in an industrial building with waste heat generation, the first indoor unit (1) installed in a commercial building without waste heat generation, and The outdoor unit (3) is controlled as follows: 1) Industrial building refrigeration: Step a: Detect the outdoor temperature t _out and the temperature inside the industrial building t _a : When t _a -t _out <10°C, enter step b1; when t _a -t _out ≥10°C, enter step b2; Step b1: When t _a ≥ t _set1 , go to step c; otherwise, return to step a, where t _set1 is the temperature setting value of the industrial building; Step b2: when t _a ≥ t _hp-on , go to step d1; otherwise, go to step d2, where t _hp-on is the set value of the heat pipe cycle opening temperature; Step c: turn on SHPS1 to discharge energy, when t _a ≥ t _set1 , go to step e1, and when t _a <t _set1 , go to step e2; Step e1: turn on the industrial building AC1, when it is detected that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, return to step a, otherwise repeat step e1; Step e2: Turn off SHPS1 to discharge energy, return to step a; Step d1: Start the SHP0 cycle, when t _a <t _hp-off , enter step d2; when t _a ≥t _hp-off , repeat step d1; Step d2: Start the SHP0" cycle and return to step a; Turning on SHPS1 to release energy means to turn on the third fan (26) to cool the heat pipe phase change module, and turning off SHPS1 to release energy means to turn off the third fan (26) so that the heat pipe phase change module stops cooling; AC1 refers to the air conditioning system used in industrial buildings, controlled by the controller; Said turning on the industrial building AC1 means turning on the air conditioning system AC1 for the industrial building; Opening the SHP0 cycle refers to opening the fourth electric two-way valve (14), the sixth electric two-way valve (16), opening the first electric three-way valve (9), the second electric three-way valve (10), and connecting the third The outlet b and outlet c of the three-way reversing valve (28) are connected to the outlet e and outlet f of the fourth three-way reversing valve (29), the fourth fan (27) and the condensing fan (31) are turned on, and the first fluorine pump is turned on (4); Opening the SHP0" cycle refers to opening the fourth electric two-way valve (14) and the sixth electric two-way valve (16), opening the first electric three-way valve (9) and the second electric three-way valve (10), and connecting the The outlet a and outlet c of the three-way reversing valve (28) are connected to the outlet d and f of the fourth three-way reversing valve (29), and the third fan (26) and the condensing fan (31) are turned on, except for the fourth motor Two-way valve (14), sixth electric two-way valve (16), first electric three-way valve (9), second electric three-way valve (10), third three-way reversing valve (28), fourth Valves, fans and fluorine pumps other than the three-way reversing valve (29), the third fan (26) and the condensing fan (31) are all closed; 2) Simultaneous cooling of industrial buildings and commercial buildings; Step f: Detect the outdoor temperature t _out , the temperature inside the industrial building t _a and the temperature inside the commercial building t _b : When t _a -t _out ≥10°C and t _b -t _out ≥10°C, enter step h1; When t _a -t _out ≥10°C and t _b -t _out <10°C, go to step h2; When t _a -t _out <10°C and t _b -t _out ≥10°C, go to step h3; When t _a -t _out <10°C and t _b -t _out <10°C, go to step h4; Step h1: when t _a ≥ t _hp-on and t _b ≥ t _hp-on , go to step i1; When ta≥t _hp-on and t _b <t _hp-on , enter step i2; When ta<t _hp-on and t _b ≥t _hp-on , go to step i3; When ta<t _hp-on and t _b <t _hp-on , start the SHP5 cycle, otherwise return to step f; Step h2: when t _b <t _set2 , return to step f, otherwise enter step j1; When t _a ≥ _{t hp-on} , go to step j2, otherwise start the SHP0" cycle and return to step f; where t _set2 is the temperature set value of the first commercial building, and t _hp-on is the heat pipe cycle start temperature set value; Step h3: when ta<t _set1 , return to step f, otherwise enter step j3; When t _b ≥ _{t hp-on} , go to step j4, otherwise start the SHP1" cycle and return to step f; where t _set1 is the temperature setting value of the industrial building, and t _hp-on is the temperature setting value of the heat pipe cycle opening; Step h4: when t _a <t _set1 , return to step f, otherwise, enter step j5; when t _b <t _set2 , return to step f, otherwise, enter step j6; Step i1: Turn on SHP2 to detect the temperature t _a in the industrial building and the indoor temperature t _b in the commercial building: When t _a ≥ t _hp-off and t _b ≥ t _hp-off , repeat step i1; When t _a ≥ t _hp-off and t _b < t _hp-off , enter step i2; When t _a <t _hp-off and t _b ≥t _hp-off , go to step i3; When t _a <t _hp-off and t _b <t _hp-off , start the SHP5 cycle and return to step f; Step i2: Turn on the SHP3 cycle, and then detect the temperature t _a in the industrial building. When t _a ≥ t _hp-off , repeat step i2, otherwise turn on SHP5 and return to step f; Step i3: Start the SHP4 cycle, and then detect the temperature t _b in the office. When t _b ≥ t _hp-off , repeat step i3, otherwise, start the SHP5 cycle, and return to step f; Step j1: Turn on SHPS2 to discharge energy, and then detect the temperature t _b in the commercial building: when t _b ≥ t _set2 , go to step k1, otherwise, turn off SHPS2 to discharge energy, and return to step f; Step j2: Start the SHP0 cycle, detect the temperature t _a in the industrial building, and repeat step j2 when ta≥t _hp-off , otherwise start the SHP0" cycle, and return to step f; Step j3: Turn on SHPS1 to discharge energy, and then detect the temperature t _a in the industrial building: when t _a ≥ t _set1 , turn off SHPS1 to discharge energy, and return to step f, otherwise, enter step k2; Step j4: Start the SHP1 cycle to detect the temperature t _b in the commercial building. When t _b ≥ t _hp-on , repeat step j4; otherwise, start the SHP1" cycle and return to step f; Step j5: Turn on SHPS1 to discharge energy, detect the temperature t _a in the industrial building, when t _a ≥ t _set1 , go to step k2, otherwise turn off SHPS1 to discharge energy, and return to step f; Step j6: Turn on SHPS2 to discharge energy, detect the temperature t _b in the commercial building, and when t _b ≥ t _set2 , go to step k1, otherwise, turn off SHPS2 to discharge energy; Step k1: Turn on the commercial building AC2 until it detects that the temperature inside the commercial building t _b ≤ t _set2 -2°C, turn off the commercial building AC2, otherwise repeat step k1; Step k2: turn on the industrial building AC1 until it detects that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, otherwise repeat step k2; The opening of the SHP1 cycle refers to opening the fifth electric two-way valve (15), the seventh electric two-way valve (17), the first electric three-way valve (9), the second electric three-way valve (10), and connecting the The outlet m and outlet k of the two-way reversing valve (23) are connected to the outlet i and the outlet h of the first three-way reversing valve (22), and the second fan (21) and the condensing fan (31) are turned on, and the first fluorine fan (31) is turned on. pump (4); The opening of the SHP1" cycle refers to opening the fifth electric two-way valve (15), the seventh electric two-way valve (17), the first electric three-way valve (9), the second electric three-way valve (10), the communication The outlet m and outlet j of the second three-way reversing valve (23) are connected to the outlet i and outlet g of the first three-way reversing valve (22), and the first fan (20) and the condensing fan (31) are turned on. Fluorine pump (4); The opening of the SHP2 cycle refers to opening the fourth electric two-way valve (14), the fifth electric two-way valve (15), the sixth electric two-way valve (16), the seventh electric two-way valve (17), the first The electric three-way valve (9), the second electric three-way valve (10), are connected to the outlet m and the outlet k of the second three-way reversing valve (23), and are connected to the outlet i and the outlet of the first three-way reversing valve (22). h, turn on the fourth fan (27), the second fan (21), the condensation fan (31), and turn on the first fluorine pump (4); The opening of the SHPS2 to release energy refers to turning on the first fan (20) to cool the heat pipe phase change module, and turning off the SHPS2 to release energy means to turn off the first fan (20) to stop the cooling of the heat pipe phase change module; Said turning on the commercial building AC2 means turning on the air conditioning system AC2 for the commercial building; The opening of the SHP3 cycle refers to opening the fourth electric two-way valve (14), the fifth electric two-way valve (15), the sixth electric two-way valve (16), the seventh electric two-way valve (17), the first The electric three-way valve (9), the second electric three-way valve (10), is connected to the outlet m and outlet j of the second three-way reversing valve (23), and is connected to the outlet i and outlet of the first three-way reversing valve (22). g, connected to outlet b and outlet c of the third three-way reversing valve (28), connected to outlet e and outlet f of the fourth three-way reversing valve (22), and turned on the fourth fan (27) and the first fan (20) , Condensing fan (31), open the first fluorine pump (4); The opening of the SHP4 cycle refers to opening the fourth electric two-way valve (14), the fifth electric two-way valve (15), the sixth electric two-way valve (16), the seventh electric two-way valve (17), the first The electric three-way valve (9), the second electric three-way valve (10), are connected to the outlet m and the outlet k of the second three-way reversing valve (23), and are connected to the outlet i and the outlet of the first three-way reversing valve (22). h, connected to outlet a and outlet c of the third three-way reversing valve (28), connected to outlet d and outlet f of the fourth three-way reversing valve (22), and opened the third blower fan (26) and the second blower fan (21) , Condensing fan (31), open the first fluorine pump (4); The opening of the SHP5 cycle refers to opening the fourth electric two-way valve (14), the fifth electric two-way valve (15), the sixth electric two-way valve (16), the seventh electric two-way valve (17), the first The electric three-way valve (9), the second electric three-way valve (10), is connected to the outlet m and outlet j of the second three-way reversing valve (23), and is connected to the outlet i and outlet of the first three-way reversing valve (22). g, connected to outlet a and outlet c of the third three-way reversing valve (28), connected to outlet d and outlet f of the fourth three-way reversing valve (22), and turned on the third blower fan (26) and the first blower fan (20) , Condensing fan (31), open the first fluorine pump (4); 3) Industrial buildings need refrigeration, and commercial buildings need heating mode; Step m: Detect the temperature t _a in the industrial building and the temperature t _b in the commercial building: when t _a -t _b <10°C, go to step n1, otherwise go to step n2; Step n1: Simultaneously detect the temperature t _a in the industrial building and detect the temperature t _b in the commercial building: When ta<t _set1 , return to step m, otherwise enter step s1; When t _b <t _set3 , enter step s2, otherwise return to step m; wherein, t _set3 is the temperature setting value of the second commercial building; Step n2: when t _a ≥ t _hp-on , go to step s3, otherwise start the SHP7 cycle and return to step m; Step s1: Turn on SHPS1 to discharge energy, and then detect the temperature t _a in the industrial building: when t _a <t _set1 , turn off SHPS1 to discharge energy, and return to step m, otherwise, enter step p1; Step s2: Turn on SHPS3 to discharge energy, and then detect the temperature t _b in the commercial building: when t _b <t _set1 , go to step p2, otherwise, turn off SHPS2 to discharge energy, and return to step m; Step s3: Start the SHP6 cycle, detect the current time t: when τ∈(τ ₁ , τ ₂ ), go to step p3, otherwise go to step p4, where τ ₁ and τ ₂ are the cooling or heating of commercial buildings respectively start time and end time; Step p1: Turn on the industrial building AC1 until it detects that the temperature in the industrial building t _a ≤ t _set1 -2°C, turn off the industrial building AC1, otherwise repeat step p1; Step p2: Turn on the commercial building AC2 until the temperature t _b ≥ t _set3 +2°C in the commercial building is detected, then turn off the commercial building AC2, otherwise repeat step p2; Step p3: Detect the temperature t _a in the industrial building: when t _a ≥ t _hp-off , return to step s3, otherwise, start the SHP7 cycle and return to step m; Step p4: Start the SHP8 cycle, and detect the temperature t _a in the industrial building: when t _a ≥ t _hp-off , repeat step p4, otherwise start the SHP9 cycle, and return to step m; The opening of the SHP6 cycle refers to opening the first electric two-way valve (11), the second electric two-way valve (12), the third electric two-way valve (13), the fourth electric two-way valve (14), the fifth The electric two-way valve (15) is connected to outlet m and outlet k of the second three-way reversing valve (23), connected to outlet i and outlet h of the first three-way reversing valve (22), and connected to the third three-way reversing valve (28) Outlet b and outlet c are connected to outlet e and outlet f of the fourth three-way reversing valve (22), the second fan (21) and the fourth fan (27) are turned on, and the second fluorine pump (5) is turned on; The opening of the SHP7 cycle refers to opening the first electric two-way valve (11), the second electric two-way valve (12), the third electric two-way valve (13), the fourth electric two-way valve (14), the fifth The electric two-way valve (15) is connected to outlet m and outlet k of the second three-way reversing valve (23), connected to outlet i and outlet h of the first three-way reversing valve (22), and connected to the third three-way reversing valve (28) Outlet a and outlet c are connected to outlet d and outlet f of the fourth three-way reversing valve (22), the second fan (21) and the third fan (26) are turned on, and the second fluorine pump (5) is turned on; The opening of the SHP8 cycle refers to opening the first electric two-way valve (11), the second electric two-way valve (12), the third electric two-way valve (13), the fourth electric two-way valve (14), the fifth The electric two-way valve (15) is connected to outlet m and outlet j of the second three-way reversing valve (23), connected to outlet i and outlet g of the first three-way reversing valve (22), and connected to the third three-way reversing valve (28) Outlet b and outlet c are connected to outlet e and outlet f of the fourth three-way reversing valve (22), the first fan (20) and the fourth fan (27) are turned on, and the second fluorine pump (5) is turned on; The opening of the SHP9 cycle refers to opening the first electric two-way valve (11), the second electric two-way valve (12), the third electric two-way valve (13), the fourth electric two-way valve (14), the fifth The electric two-way valve (15) is connected to outlet m and outlet j of the second three-way reversing valve (23), connected to outlet i and outlet g of the first three-way reversing valve (22), and connected to the third three-way reversing valve (28) Outlet a and outlet c are connected to outlet d and outlet f of the fourth three-way reversing valve (22), the first fan (20), the third fan (26) are turned on, and the second fluorine pump (5) is turned on; Turning on the SHPS3 to release energy refers to turning on the first fan (20) to make the heat pipe phase change module release heat.

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