EASY-TO-INSTALL MULTI-PURPOSE COOLING AND HEATING MACHINE SYSTEM

Abstract

Compared with an opposite arrangement of a cold system/a heat system in a traditional compression refrigeration household appliance, an automatic cold/heat balance storage operation system controlled by a cloud-networked microprocessor controller is added to an easy-to-install multi-purpose cooling and heating machine system, which has automatic cold/heat balance, self-heating and defrosting, and a plurality of modes of cold/heat storage. Cold/heat balance configuration achieves double-effect power conservation and outputs cold/heat in a plurality of modes The easy-to-install cooling and heating machine system includes: a cold/heat balancing heat exchanger, a cold/heat balancing self-defrosting cold/heat output machine, a cold/heat storage compensation equipment, and a cold/heat balance using equipment. The cold/heat storage compensation equipment includes: a hot water storage tank, a cold/heat storage tank, an ice/hot water storage tank, an ice/hot water energy storage tank, and a self-cycling hot cold water storage tank

Claims

1. An easy-to-install multi-purpose cooling/heating machine main system comprising: a cloud-networked microprocessor controller starts; a refrigerating system starts to operate; a refrigeration compressor sucks a normal temperature gas-refrigerant from a normal temperature gas-refrigerant gas return box; a high temperature and high pressure gas-refrigerant is compressed and discharged via the refrigeration compressor to enable the high temperature and high pressure gas-refrigerant to flow into a cold-dry air heater/cooler, a dual source heat-exchanger heat pipe of the cold-dry air heater/cooler, a heat accumulator with water condensation, and a condensation heat accumulator in sequence through a high pressure and high temperature refrigerant connecting pipeline; after the high temperature and high pressure gas-refrigerant in the condensation heat accumulator being condensed and heated to form a normal temperature liquid-refrigerant, the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box, and then passes through a large capacity refrigerant distribution box, a connecting pipeline for outputting the normal temperature liquid-refrigerant, an evaporator/cold accumulator, a refrigerator and an air conditioner indoor unit in sequence; after the normal temperature liquid-refrigerant in the air conditioner indoor unit being evaporated and refrigerated to form a normal temperature gas-refrigerant, the normal temperature gas-refrigerant flows into a connecting pipeline of a normal temperature gas-refrigerant return box and the normal temperature gas-refrigerant return box; the process is recycled reciprocally; a heat-carrying agent flows into a hot water storage tank, and an ice/hot water energy storage tank in sequence via a heat-carrying agent cycling pump and a connecting pipeline for outputting the heat-carrying agent; after heat being discharged from the heat-carrying agent in the ice/hot water energy storage tank by exchange of the hot water storage tank, the heat-carrying agent flows into a connecting pipeline for returning the heat-carrying agent and then a heat-carrying agent return box; above process are cyclically repeated; a cooling medium flows into a connecting pipeline for outputting the cooling medium, a refrigerator with the cooling medium as a cold source, a draught fan with the cooling medium as a cold source, a dual-purpose machine with the cooling medium as a cold source, a dual source heat-exchanger cold pipe of a cold-dry air heater/cooler, and the ice/hot water energy storage tank in sequence via a cooling medium cycling pump; after cold being discharged from cooling medium in the ice/hot water energy storage tank by exchange of the hot water storage tank, the cooling medium flows into a connecting pipeline for returning the cooling medium/a storage box connecting pipeline for the cooling medium/the heat-carrying agent, and then into a cooling medium return box; above process are cyclically repeated; hot water of a heat accumulator with water condensation flows from a heat-carrying agent outlet into the dual source heat-exchanger heat pipe of the cold-dry air heater/cooler, and then into the heat accumulator with the water condensation; above process are cyclically repeated; when the main system is under a working condition of excessive heat, the first cloud-networked microprocessor controller instructs a solenoid control valve/a conversion solenoid valve for returning the heat-carrying agent to be interchangeably connected, enabling a cold/heat balance heat exchanger, a dual component cold/heat balance self-defrosting heat exchanger, a dual component and dual pipeline cold/heat balance self-defrosting heat exchanger, a high pressure and high temperature refrigerant connecting pipeline to discharge heat; when the main system is under a working condition of excessive cold, the first cloud networked microprocessor controller instructs to communicate the connecting pipeline for outputting cooling medium/a connecting pipeline for outputting the normal temperature liquid-refrigerant, the cold/heat balance heat exchanger, the dual component cold/heat balance self-defrosting heat exchanger, and the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger discharge cold; when the cold/heat balance heat exchanger, the dual component cold/heat balance self-defrosting heat exchanger, and the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger are under a working condition of frosting, and the first cloud networked microprocessor controller instructs the heat-carrying agent return conversion solenoid valve to interchangeably connect with the a solenoid control valve; the cold/heat balance heat exchanger, the dual component cold/heat balance self-defrosting heat exchanger, and the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger perform cross-transforming of discharging, defrosting, an A assembly, and an B assembly, so as to discharge cold and defrost continuously; a solenoid regulation and control valve converts a storage of cold/heat to a compensation of cold/heat on the basis of instructions of the first cloud-networked microprocessor controller the cold-dry air heater/cooler runs; the first cloud-networked microprocessor controller instructs to connect the dual source heat-exchanger cold pipe to provide cold air for a dry-hot/cold air outlet/the first cloud-networked microprocessor controller instructs to connect the dual source heat-exchanger heat pipe to provide hot air for the dry-hot/cold air outlet/the first cloud-networked microprocessor controller instructs to connect the dual source heat-exchanger cold pipe and the dual source heat-exchanger heat pipe simultaneously, so as to provide cold-dry air for the dry-hot/cold air outlet; a dual component and dual temperature region cold/heat balance self-defrosting heat exchanger runs; when the microprocessor controller instructs to connect the dual source heat-exchanger heat pipe to discharge heat; when the main system is under the working condition of excessive cold, the first cloud-networked microprocessor controller instructs to connect the dual source heat-exchanger cold pipe to discharge cold; when the main system is under the working condition of frosting, the first cloud-networked microprocessor controller instructs the dual component and dual temperature region cold/heat balance self-defrosting heat exchanger to perform cross-transforming of discharging cold, defrosting, the A assembly, and the B assembly so as to discharge cold and defrost continuously; the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger, and the dual component and dual temperature region cold/heat balance self-defrosting heat exchanger operates anti-frosting; the first cloud-networked microprocessor controller instructs to connect the cold and the heat of a cold and heat dual source simultaneously to control a working temperature of heat exchange of a cold/heat balance self-defrosting heat exchanger at an anti-frosting working condition; and the first cloud-networked microprocessor controller leads a network to a second network cloud-networked microprocessor controller and a third network cloud-networked microprocessor controller, or networked microprocessor controllers host machines and auxiliary machines such that a plurality of functions of cold/heat balance, storage, and compensation are in combination of centralization and decentralization; and comprehensive balance and cross-use improve the efficiency.

2. A refrigerator-air conditioner-water heater multi-purpose machine comprising: a cloud-network microprocessor controller starts; a refrigerating system starts to operate; normal temperature gas-refrigerant is sucked from a normal temperature gas-refrigerant return box by a refrigeration compressor; a high temperature and high pressure gas-refrigerant is compressed and discharged via the refrigeration compressor to enable the high temperature and high pressure gas-refrigerant to flow into a self-cycling hot/cold water storage tank, a dual temperature region cold-dry hot/cold air conditioner indoor unit, a water heater with condensation storage, and a drying cabinet in sequence through a high pressure and high temperature refrigerant connecting pipeline; after the high temperature and high pressure gas-refrigerant in the drying cabinet being condensed and heated to form a normal temperature liquid-refrigerant, the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box, a large capacity refrigerant distribution box, a connecting pipeline for outputting the normal temperature liquid-refrigerant, a refrigerator, a water heater, with condensation and storage function, a self-cycling hot/cold water storage tank, and a dual temperature region cold-dry hot/cold air conditioner indoor unit in sequence; after the normal temperature liquid-refrigerant in the dual temperature region cold-dry hot/cold air conditioner indoor unit being evaporated and refrigerated to form a normal temperature gas-refrigerant, the normal temperature gas-refrigerant flows into a connecting pipeline of a normal temperature gas-refrigerant return box and the normal temperature gas-refrigerant return box; above process are cyclically repeated; when the main system is under a working condition of excessive heat, the second cloud-networked microprocessor controller instructs to connect a self-balancing defrosting cold/heat output machine, an A assembly, the high pressure and high temperature refrigerant connecting pipeline; the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box to discharge heat; when the main system is under a working condition of excessive cold, the second cloud-networked microprocessor controller instructs to connect the self-balancing defrosting cold/heat output machine, the A assembly, the connecting pipeline for outputting the normal temperature liquid-refrigerant, and the connecting pipeline to the normal temperature gas-refrigerant return box to discharge cold; when the main system is under a working condition of frosting, and the second cloud-networked microprocessor controller instructs to connect the self-balancing defrosting cold/heat output machine to perform cross-transforming of discharging cold, defrosting, the A assembly, and an B assembly so as to discharge cold and defrost continuously; the second cloud-networked microprocessor controller is networked to a first cloud-networked microprocessor controller and a third cloud-networked microprocessor controller . . . , or networked microprocessor controllers host machines and auxiliary machines such that a plurality of functions of cold/heat balance, storage, and compensation are in combination of centralization and decentralization; and comprehensive balance and cross-use improve the efficiency.

3. An easy-to-install multi-purpose cold/heat output machine comprising: a third cloud-networked microprocessor controller instructs to start; a refrigerating system starts to operate; a normal temperature gas-refrigerant is sucked from a normal temperature gas-refrigerant return box by a refrigeration compressor; a high temperature and high pressure gas-refrigerant is compressed and discharged via the refrigeration compressor to enable the high temperature and high pressure gas-refrigerant to flow into a cold/heat storage tank, an ice/hot water storage tank, and the cold/heat storage tank in sequence through the high pressure and high temperature refrigerant connecting pipeline; after the high temperature and high pressure gas-refrigerant in the connecting pipeline being condensed and heated to form a normal temperature liquid-refrigerant, the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box, a large capacity refrigerant distribution box, a connecting pipeline for outputting the normal temperature liquid refrigerant, the cold/heat storage tank, the ice/hot water storage tank, and the cold/heat storage tank in sequence; after the normal temperature liquid-refrigerant in the cold/heat storage tank being evaporated and refrigerated to form a normal temperature gas-refrigerant, the refrigerant flows into a connecting pipeline of a normal temperature gas-refrigerant return box and the normal temperature gas-refrigerant return box; above process are cyclically repeated; when the main system is in a working condition of excessive heat, the third cloud networked microprocessor controller instructs to connect a self-balancing defrosting cold/heat output machine, an A assembly, the high pressure and high temperature refrigerant connecting pipeline, and the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box to discharge heat; when the main system is under a working condition of excessive cold, and the third cloud-networked microprocessor controller instructs to connect the self-balancing defrosting cold/heat output machine, the A assembly, the connecting pipeline for outputting the normal temperature liquid refrigerant, and the connecting pipeline to the normal temperature gas-refrigerant return box to discharge cold; when the main system is under a working condition of frosting, the third cloud-networked microprocessor controller instructs to connect the self-balancing defrosting cold/heat output machine to perform cross-transforming of discharging cold, defrosting, the A assembly, and an B assembly to discharge cold and defrost continuously; the easy-to-install multi-purpose cold/heat output machine is split/integrated, or the easy-to-install multi-purpose cold/heat output machine is enabled to have a plurality of combination modes, each of the cold/heat storage tank, the ice/hot water storage tank, and the self-balancing defrosting cold/heat output machine is a split/combined part; and the third cloud-networked microprocessor controller is networked to a first cloud-networked microprocessor controller and a second cloud-networked microprocessor controller, or networked microprocessor controllers host machines and auxiliary machines such that a plurality of functions of cold/heat balance, storage, and compensation are in combination of centralization and decentralization; and comprehensive balance and cross-use improve the efficiency.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] Reference signs in all drawings are: cloud-networked microprocessor controller (01) (02) (03), large capacity refrigerant distribution box (3), normal temperature gas-refrigerant return box (8), heat-carrying agent cycling pump (9), heat-carrying agent outlet (10), heat-carrying agent return conversion solenoid valve (13), heat-carrying agent return box (14), tap water check valve inlet (15), cooling medium cycling pump (16), cooling medium outlet (17), cooling medium return box (18), cooling medium/heat-carrying agent storage box (19), low-level fluid supplementation pipe (20), high-level interconnecting pipe (21), cold/heat balance heat exchanger (22), gas-liquid separator (24), exhaust port/fan (82), air inlet screen (83), water filling/breathing port (84), drying cabinet (85), dry-hot/cold air outlet (89), high pressure and high temperature refrigerant connecting pipeline (90), connecting pipeline from normal temperature liquid refrigerant to refrigerant distribution box (91), connecting pipeline (92) for outputting a normal temperature liquid-refrigerant, connecting pipeline (93) to normal temperature gas-refrigerant return box, connecting pipeline (94) for outputting a heat-carrying agent, connecting pipeline (95) for returning a heat-carrying agent, connecting pipeline (96) for outputting a cooling medium, connecting pipeline (97) for returning a cooling medium, connecting pipeline (98) for cooling medium/heat-carrying agent to return to cooling medium/heat-carrying agent storage box, connecting pipeline (99) for outputting hot/cold water, connecting pipeline (100) for returning hot/cold water, refrigerator (104), evaporator/cold accumulator (105), condensation heat accumulator (106), air conditioner indoor unit (125), refrigeration compressor (201) with networking function, refrigeration compressor (202) with networking function, refrigeration compressor (203), with networking function cooling medium cold source refrigerator (304), draught fan (312C) with cooling medium as a cold source, dual-purpose machine (351) with cooling medium as a cold source, heat accumulator (506) with water condensation, water heater (506B) with condensation storage, cold-dry air heater/cooler (512C), dual component and dual temperature region cold/heat balance self-defrosting heat exchanger (512CD), solenoid regulation and control valve (653), refrigerator (704), hot water storage tank (711), control valve (713) for returning cooling medium in a hot water storage tank, dual component cold/heat balance self-defrosting heat exchanger (722), solenoid regulation and control valve (723), dual temperature region cold-dry hot/cold air conditioner indoor unit (725), cold/heat storage tank (756), ice/hot water storage tank (757), refrigerator-air conditioner-water heater multi-purpose machine (789), ice/hot water energy storage tank (811), dual component and dual pipeline cold/heat balance self-defrosting heat exchanger (822), self-cycling hot/cold water storage tank (911), cycling pump (916), self-balancing defrosting cold/heat output machine (2722), self-balancing defrosting cold/heat output machine (2821), easy-to-install multi-purpose cold/heat output machine (2822), dual component cold/heat balance self-defrosting heat-exchanger assembly A (A), dual component cold/heat balance self-defrosting heat-exchanger assembly B (B), dual source heat-exchanger cold pipe (L), and dual source heat-exchanger heat pipe (R).

[0010] Combination split line ( . . . + . . . )

[0011] FIG. 1 is a schematic operation diagrams of an easy-to-install multi-purpose cooling and heating machine main system according to an embodiment of the present disclosure;

[0012] FIG. 2 is another schematic operation diagram of an easy-to-install multi-purpose cooling and heating machine main system according to an embodiment of the present disclosure;

[0013] FIG. 3 is a schematic operation diagram of a refrigerator-air conditioner-water heater multi-purpose machine (789) of an easy-to-install multi-purpose cooling and heating machine system according to another embodiment of the present disclosure; and

[0014] FIG. 4 is a schematic operation diagram of an easy-to-install multi-purpose cold/heat output machine (2822) of an easy-to-install multi-purpose cooling and heating machine system according to yet another embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0015] FIGS. 1 and 2 are schematic operation diagrams of an easy-to-install multi-purpose cooling and heating machine main system.

[0016] An operation method of the main system of an easy-to-install multi-purpose cooling and heating machine includes: a cloud-networked microprocessor controller (01) starts; a cooling system starts to operate; a refrigeration compressor (201) sucks a normal temperature gas-refrigerant from a normal temperature gas-refrigerant gas return box (8); a high temperature and high pressure gas-refrigerant is compressed and discharged via the refrigeration compressor (201) to enable the high temperature and high pressure gas-refrigerant to flow into a cold-dry air heater/cooler (512C), a dual source heat-exchanger heat pipe (R) of the cold-dry air heater/cooler, a heat accumulator (506) with water condensation, and a condensation heat accumulator (106) in sequence through a high pressure and high temperature refrigerant connecting pipeline (90); after the high temperature and high pressure gas-refrigerant in the condensation heat accumulator (106) being condensed and heated to form a normal temperature liquid-refrigerant, the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box (91), and then passes through a large capacity refrigerant distribution box (3), a connecting pipeline (92) for outputting the normal temperature liquid-refrigerant, an evaporator/cold accumulator (105), a refrigerator (104), and an air conditioner indoor unit (125) in sequence; after the normal temperature liquid-refrigerant in the air conditioner indoor unit being evaporated and refrigerated to form a normal temperature gas-refrigerant, the normal temperature gas-refrigerant flows into a connecting pipeline of a normal temperature gas-refrigerant return box (93) and the normal temperature gas-refrigerant return box (8); the process is recycled reciprocally; a heat-carrying agent flows into a hot water storage tank (711), and an ice/hot water energy storage tank (811) in sequence via a heat-carrying agent cycling pump (9) and a connecting pipeline (94) for outputting the heat-carrying agent; after heat being discharged from the heat-carrying agent in the ice/hot water energy storage tank (811) by exchange of the hot water storage tank (711), the heat-carrying agent flows into a connecting pipeline (95) for returning the heat-carrying agent and then a heat-carrying agent return box (14); above process are cyclically repeated; a cooling medium flows into a connecting pipeline (96) for outputting the cooling medium, a refrigerator (304) with the cooling medium as a cold source, a draught fan (312C) with the cooling medium as a cold source, a dual-purpose machine (351) with the cooling medium as a cold source, a dual source heat-exchanger cold pipe (L) of a cold-dry air heater/cooler (512C), and the ice/hot water energy storage tank (811) in sequence via a cooling medium cycling pump (16); after cold being discharged from cooling medium in the ice/hot water energy storage tank (811) by exchange of the hot water storage tank (711), the cooling medium flows into a connecting pipeline (97) for returning the cooling medium/a storage box connecting pipeline (98) for the cooling medium/the heat-carrying agent, and then into a cooling medium return box (18); above process are cyclically repeated. Hot water of a heat accumulator (506) with water condensation flows from a heat-carrying agent outlet (10) into the dual source heat-exchanger heat pipe (R) of the cold-dry air heater/cooler (512C), and then into the heat accumulator (506) with the water condensation; above process are cyclically repeated; when the main system is under a working condition of excessive heat, the cloud-networked microprocessor controller (01) instructs a solenoid control valve (653)/a conversion solenoid valve (13) for returning the heat-carrying agent to be interchangeably connected, enabling a cold/heat balance heat exchanger (22), a dual component cold/heat balance self-defrosting heat exchanger (722), a dual component and dual pipeline cold/heat balance self-defrosting heat exchanger (822), a high pressure and high temperature refrigerant connecting pipeline (90) to discharge heat; when the main system is under a working condition of excessive cold, the cloud networked microprocessor controller (01) instructs to communicate the connecting pipeline (96) for outputting cooling medium/a connecting pipeline (92) for outputting the normal temperature liquid-refrigerant, the cold/heat balance heat exchanger (22), the dual component cold/heat balance self-defrosting heat exchanger (722), and the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger (822) discharge cold; when the cold/heat balance heat exchanger (22), the dual component cold/heat balance self-defrosting heat exchanger (722), and the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger (822) are under a working condition of frosting, and the cloud networked microprocessor controller (01) instructs the heat-carrying agent return conversion solenoid valve (13) to interchangeably connect with the a solenoid control valve (653). The cold/heat balance heat exchanger (22), the dual component cold/heat balance self-defrosting heat exchanger (722), and the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger (822) perform cross-transforming of discharging, defrosting, an A assembly, and an B assembly, so as to discharge cold and defrost continuously; a solenoid regulation and control valve (723) converts a storage of cold/heat to a compensation of cold/heat on the basis of instructions of the cloud-networked microprocessor controller (01), the cold-dry air heater/cooler (512C) runs . . . . The cloud-networked microprocessor controller (01) instructs to connect the dual source heat-exchanger cold pipe (L) to provide cold air for a dry-hot/cold air outlet (89)/the cloud-networked microprocessor controller (01) instructs to connect the dual source heat-exchanger heat pipe (R) to provide hot air for the dry-hot/cold air outlet (89)/the cloud-networked microprocessor controller (01) instructs to connect the dual source heat-exchanger cold pipe (L) and the dual source heat-exchanger heat pipe (R) simultaneously, so as to provide cold-dry air for the dry-hot/cold air outlet (89); a dual component and dual temperature region cold/heat balance self-defrosting heat exchanger (512CD) runs; when the main system is under the working condition of excessive heat, and the cloud-networked microprocessor controller (01) instructs to connect the dual source heat-exchanger heat pipe (R) to discharge heat; when the main system is under the working condition of excessive cold, the cloud-networked microprocessor controller (01) instructs to connect the dual source heat-exchanger cold pipe (L) to discharge cold; when the main system is under the working condition of frosting, the cloud-networked microprocessor controller (01) instructs the dual component and dual temperature region cold/heat balance self-defrosting heat exchanger (512CD) to perform cross-transforming of discharging cold (L), defrosting (R). The A assembly (A), and the B assembly (B) so as to discharge cold and defrost continuously; the dual component and dual pipeline cold/heat balance self-defrosting heat exchanger (822), and the dual component and dual temperature region cold/heat balance self-defrosting heat exchanger (512CD) operates anti-frosting; the cloud-networked microprocessor controller (01) instructs to connect the cold and the heat of a cold and heat dual source simultaneously to control a working temperature of heat exchange of a cold/heat balance self-defrosting heat exchanger at an anti-frosting working condition; and the cloud-networked microprocessor controller (01) leads a network to a network cloud-networked microprocessor controller (02) and a network cloud-networked microprocessor controller (03) . . . , such that a plurality of functions of cold/heat balance, storage, and compensation are in combination of centralization and decentralization; and comprehensive balance and cross-use improve the efficiency.

[0017] In FIG. 3, an operation method of a refrigerator-air conditioner-water heater multi-purpose machine (789) of a system of an easy-to-install multi-purpose cooling/heating machine system is provided, the operation method includes the following steps.

[0018] A cloud-network microprocessor controller (02) starts; a cooling system starts to operate; a normal temperature gas-refrigerant is sucked from a normal temperature gas-refrigerant return box (8) by a refrigeration compressor (202); a high temperature and high pressure gas-refrigerant is compressed and discharged via the refrigeration compressor (202) to enable the high temperature and high pressure gas-refrigerant to flow into a self-cycling hot/cold water storage tank (911), a dual temperature region cold-dry hot/cold air conditioner indoor unit (725), a water heater (506B) with condensation storage, and a drying cabinet (85) in sequence through a high pressure and high temperature refrigerant connecting pipeline (90); after the high temperature and high pressure gas-refrigerant in the drying cabinet (85) being condensed and heated to form a normal temperature liquid-refrigerant, the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box (91), a large capacity refrigerant distribution box (3), a connecting pipeline (92) for outputting the normal temperature liquid-refrigerant, a refrigerator (704), a water heater with condensation and storage function, a self-cycling hot/cold water storage tank (911), and a dual temperature region cold-dry hot/cold air conditioner indoor unit (725) in sequence; after the normal temperature liquid-refrigerant in the dual temperature region cold-dry hot/cold air conditioner indoor unit (725) being evaporated and refrigerated to form a normal temperature gas-refrigerant, the normal temperature gas-refrigerant flows into a connecting pipeline of a normal temperature gas-refrigerant return box (93) and the normal temperature gas-refrigerant return box (8); above process are cyclically repeated; when the main system is under a working condition of excessive heat, the cloud-networked microprocessor controller (02) instructs to connect a self-balancing defrosting cold/heat output machine (2722), an A assembly (A), the high pressure and high temperature refrigerant connecting pipeline (90); the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box (91) to discharge heat; when the main system is under a working condition of excessive cold, the cloud-networked microprocessor controller (02) instructs to connect the self-balancing defrosting cold/heat output machine (2722), the A assembly (A), the connecting pipeline (92) for outputting the normal temperature liquid-refrigerant, and the connecting pipeline to the normal temperature gas-refrigerant return box (93) to discharge cold; when the main system is under a working condition of frosting, and the cloud-networked microprocessor controller (02) instructs to connect the self-balancing defrosting cold/heat output machine (2722) to perform cross-transforming of discharging cold, defrosting, the A assembly (A), and an B assembly (B) so as to discharge cold and defrost continuously; the cloud-networked microprocessor controller (02) is networked to the cloud-networked microprocessor controller (01) and a cloud-networked microprocessor controller (03) . . . , such that a plurality of functions of cold/heat balance, storage, and compensation are in combination of centralization and decentralization; and comprehensive balance and cross-use improve the efficiency.

[0019] In FIG. 4, an operation method an easy-to-install multi-purpose cold/heat output machine (2822) of a system of an easy-to-install multi-purpose cooling/heating machine is provided, the method includes the following steps.

[0020] A cloud-networked microprocessor controller (03) instructs to start; a refrigerating system starts to operate; a normal temperature gas-refrigerant is sucked from a normal temperature gas-refrigerant return box (8) by a refrigeration compressor (203); a high temperature and high pressure gas-refrigerant is compressed and discharged via the refrigeration compressor (203) to enable the high temperature and high pressure gas-refrigerant to flow into a cold/heat storage tank (756), an ice/hot water storage tank (757), and the cold/heat storage tank (756) in sequence through the high pressure and high temperature refrigerant connecting pipeline (90); after the high temperature and high pressure gas-refrigerant in the connecting pipeline (90) being condensed and heated to form a normal temperature liquid-refrigerant, the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box (91), a large capacity refrigerant distribution box (3), a connecting pipeline (92) for outputting the normal temperature liquid refrigerant, the cold/heat storage tank (756), the ice/hot water storage tank (757), and the cold/heat storage tank (756) in sequence; after the normal temperature liquid-refrigerant in the cold/heat storage tank (756) being evaporated and refrigerated to form a normal temperature gas-refrigerant, the refrigerant flows into a connecting pipeline of a normal temperature gas-refrigerant return box (93) and the normal temperature gas-refrigerant return box (8); above process are cyclically repeated; when the main system is in a working condition of excessive heat, the cloud networked microprocessor controller (03) instructs to connect a self-balancing defrosting cold/heat output machine (2821), an A assembly (A), the high pressure and high temperature refrigerant connecting pipeline (90), and the normal temperature liquid-refrigerant flows into a connecting pipeline of a refrigerant distribution box (91) to discharge heat; when the main system is under a working condition of excessive cold, and the cloud-networked microprocessor controller (03) instructs to connect the self-balancing defrosting cold/heat output machine (2821), the A assembly (A), the connecting pipeline (92) for outputting the normal temperature liquid refrigerant, and the connecting pipeline to the normal temperature gas-refrigerant return box (93) to discharge cold; when the main system is under a working condition of frosting, the cloud-networked microprocessor controller (03) instructs to connect the self-balancing defrosting cold/heat output machine (2821) to perform cross-transforming of discharging cold, defrosting, the A assembly, and an B assembly to discharge cold and defrost continuously; the easy-to-install multi-purpose cold/heat output machine (2822) is split/integrated, or the easy-to-install multi-purpose cold/heat output machine (2822) is enabled to have a plurality of combination modes, each of the cold/heat storage tank (756), the ice/hot water storage tank (757), and the self-balancing defrosting cold/heat output machine (2821) is a split/combined part; and the cloud-networked microprocessor controller (03) is networked to a cloud-networked microprocessor controller (01) and a cloud-networked microprocessor controller (02) . . . such that a plurality of functions of cold/heat balance, storage, and compensation are in combination of centralization and decentralization; and comprehensive balance and cross-use improve the efficiency.

[0021] To sum up, the embodiments and principle are illustrated by using specific examples in the present disclosure. The present disclosure provides a cool and heat conversion system. The number of refrigeration compressors and cloud-networked microprocessor controllers can be flexibly configured according to requirements. And the number of multi-purpose refrigerating and heating machine terminals or the networked host machines and auxiliary machines can be dynamically increased or decreased, and then these devices can be networked.