BE1029653B1 - Dual Thermal and Cold Energy Storage System - Google Patents

Abstract

The present invention provides a thermal and cold energy dual storage system, which comprises: a power unit enabling transmission of electricity generated from a renewable energy network and a power network non-renewable to a heating device and a refrigeration device; a heating device enabling conversion of electrical heat according to the transmitted electricity in order to achieve thermal energy storage; a refrigeration device enabling conversion of electric refrigeration according to the transmitted electricity to achieve cold energy storage; a deployment unit allowing future deployment of currently stored thermal and cold energy according to the actual demand for thermal and cold energy.

Description

Description

Dual Thermal and Cold Energy Storage System

Technical area

The present invention relates to the technical field of dual storage of thermal and cold energy, and in particular a dual storage system of thermal and cold energy.

Core technology

More and more cases of dual storage of cold and hot energy are found in daily life. We must address both thermal energy storage and cold energy storage. In this case, when heating and refrigeration are carried out according to the electricity production system, a certain amount of thermal and cold energy is stored and used according to the predefined mode. However, this mode cannot meet the actual needs of heat and cold energy well, that is, heat and cold energy cannot be used reasonably. For example, after the heat and cold energy are discharged, the service life of the temperature discharge pipe will be reduced because of the large temperature difference.

The present invention therefore proposes a dual storage system for thermal and cold energy.

Content of the invention

The present invention provides a dual thermal and cold energy storage system for storing cold and thermal energy from both the renewable network and the non-renewable network, efficiently deploying the stored cold and thermal energy according to the real needs, and thus achieve the rational storage and emission of thermal and cold energy through the control of the valves.

The present invention provides a dual thermal and cold energy storage system, comprising:

A power unit enabling transmission of electricity generated from a renewable energy network and a non-renewable energy network to a heating device and a refrigeration device;

A heating device allowing conversion of electrical heat according to the electricity transmitted in order to achieve thermal energy storage;

A refrigeration device enabling conversion of electric refrigeration according to the transmitted electricity in order to achieve cold energy storage;

A deployment unit allowing future deployment of currently stored thermal and cold energy according to the actual demand for thermal and cold energy;

A control module making it possible to control the first group of valves connected to the heating device and the second group of valves connected to the refrigeration device according to future deployment, and to store and rationally evacuate thermal and cold energy according to the result control.

Preferably, the power supply unit comprises:

A first electrical energy collection unit for collecting the first electrical energy from the non-renewable energy network and constructing the first generation curve, the first power supply curve and the first generation loss curve on the basis of the non-renewable energy network;

A second electrical energy collection unit for collecting the second electrical energy from the renewable energy network and constructing the second generation curve, the second power curve and the second generation loss curve based on the network renewable energy;

A first determination unit for determining the first stability coefficient of the non-renewable energy network;

A second determination unit for determining the second stability coefficient of the renewable energy network;

A first acquisition unit for acquiring the first electricity efficiently transmitted from the non-renewable energy network according to the first stability coefficient;

a second acquisition unit for acquiring the second electricity efficiently transmitted from the renewable energy network according to the second stability coefficient;

A heating switch distribution unit for distributing to the heating device the first switch group of the non-renewable energy network and the second group of switches of the renewable energy network according to the heating demand of the heating device and the first electricity transmitted efficiently;

A refrigeration switch distribution unit for distributing to the refrigeration device the third switch group of the non-renewable energy network and the fourth switch group of the renewable energy network according to the refrigeration demand of the refrigeration device and the second electricity transmitted efficiently;

Preferably, the first determination unit comprises:

A first factor determination block for determining an adjustment factor of the first stability coefficient; 41 = ST 2nd sli — Zu nl £oi1=1 s0j1

Where, n1 represents a representative time point based on the first generation curve; s0;, represents the curve value of the 1st time point on the first generation curve; s1;, represents the curve value of the 1'i1° time point on the first power curve; s2;, represents the curve value of the i1° time point on the first generation loss curve; 01 represents the adjustment factor of the first stability coefficient;

A first coefficient determination block for calculating a first stability coefficient on the basis of the adjustment factor determined by the first factor determination block;

W1=1->. [Sun Se — 41 x In(1 + 81) i1=1 1S0j1 + SOj1—1

Where, W1 represents the first stability coefficient of the non-renewable energy network; ln(1 + 01) represents an adjustment function of the first stability coefficient; s0j,_, represents the curve value of the il-1° time point on the first generation curve.

Preferably, the second determination unit comprises:

a second factor determination block for determining an adjustment factor of the second stability coefficient; 92 = ST not — S21;, — ZZ nl Zui1=1 s20;1

Where, n1 represents a representative time point based on the second generation curve and is equivalent to the number of representative time points on the first generated curve; s20;, represents the curve value of the 1st time point on the second generation curve; s21;, represents the curve value of the 1st time point on the second power curve; s22;4 represents the curve value of the 1st time point on the second generation loss curve; 02 represents the adjustment factor of the second stability coefficient;

a second coefficient determination block for calculating a second stability coefficient on the basis of the adjustment factor determined by the second factor determination block;

W2=1- > es _— | x In(1 + 02) i1=1 1820j1 + S20j1—1

Where, W2 represents the second stability coefficient of the renewable energy network; In(1 +02) represents an adjustment function of the second stability coefficient; s20;4_, represents the curve value of the i1-1° time point on the second generation curve.

Preferably, the heating device comprises:

A first thermal energy storage unit for performing heat conversion of electricity transmitted by the non-renewable energy network on the basis of the first switch group connected to the non-renewable energy network, and perform a first thermal energy storage;

A second thermal energy storage unit for performing heat conversion of electricity transmitted by the renewable energy network on the basis of the second switch group connected to the renewable energy network, and performing second thermal energy storage; 5 A combined thermal and cold energy storage unit for performing thermal energy storage on the basis of the first thermal energy storage and the second thermal energy storage.

Preferably, the deployment unit comprises:

An energy determination unit for acquiring the thermal energy currently stored by the heating device and the cold energy currently stored by the refrigeration device;

A demand analysis unit for performing an analysis of the actual cooling and heating demand, and determining the requested quantity of thermal energy and the duration of the thermal energy demand, as well as the demand for cold energy and the duration of cold energy demand;

A duration determination unit for determining the first available duration of the currently stored thermal energy according to the requested quantity of thermal energy and the duration of thermal energy demand;

If the thermal energy demand duration is less than the first available duration, determining the transmissible thermal energy corresponding to each first switch of the first switch group and the transmissible cold energy corresponding to each second switch of the second switch group;

A switch control unit for determining the first stop switch and controlling the closing of the first stop switch according to the remaining thermal energy difference between the thermal energy currently stored in the heater and the requested quantity thermal energy, the sequence of transmissible thermal energy of the first group of switches, the sequence of transmissible cold energy of the second group of switches and the stability standards for the electrothermal conversion of the non-renewable energy networks and the networks of 'renewable energy;

If the thermal power demand duration is equal to the first available duration, controlling each first switch of the first switch group and each second switch of the second switch group to remain unchanged;

If the thermal energy demand duration is greater than the second available duration, then determine whether the cold energy currently stored in the refrigeration device can meet the requested amount of cold energy and the duration of the heat demand. cold energy;

A switching direction control unit for obtaining an idling switch of the refrigeration device and controlling the switching direction of the idling switch as switches to be increased for the heating device to determine that the cold energy currently stored in the refrigeration device meets the requested quantity of cold energy and the duration of cold energy demand.

Preferably, the control module comprises:

A valve determination unit for determining, according to future deployment, whether the thermal energy of the heater should be released, and if necessary, determining the first group of valves according to the thermal energy release standard, at the same time determining whether to release cold energy from the cooling device and determining, if necessary, the second group of valves in accordance with the cold energy release standard;

A temperature determination unit for estimating, according to the first valve group, the first temperature of the thermal energy pipe after releasing part of the thermal energy from the heater to the thermal energy pipe;

Estimate, according to the second group of valves, the third temperature of the cold energy pipe after releasing part of the cold energy from the refrigeration device to the cold energy pipe;

Determine the second temperature of the constant temperature pipe connected to the thermal power pipe based on the first temperature and determine the fourth temperature of the constant temperature pipe connected to the cold power pipe based on the third temperature;

Determining the final temperature of the constant temperature pipeline on the basis of the second temperature and the fourth temperature, and the duration of the second temperature and the duration of the fourth temperature;

A temperature evaluation unit for performing the corresponding release according to the determined first valve group and the second valve group when the final temperature is within the normal temperature range;

If the final temperature Tzy; is less than the minimum value Tyn of the normal temperature range, determine, according to Tyn — Tzu, the number of closed valves in the second group of valves;

If the final temperature Tzy; is less than the maximum Tyax value of the normal temperature range, determine, according to Tzy; — Tmax; the number of closed valves in the first group of valves.

Preferably, the temperature evaluation unit comprises:

A valve determination block for determining, according to Tyn —

Tzu, the number of closed valves in the second group of valves;

N1 = E Tain — Tzur + a2 sa sx T =

AT AT

Where, Nl represents the number of closed valves in the second group of valves; al represents the representative coefficient for the minimum value of the normal temperature range; a2 represents the representative coefficient for the average value of the normal temperature range, and a2+a1=1, a2>al; AT represents the refrigeration variant of each valve of the second valve group for constant temperature driving; [] represents the rounding symbol.

Other characteristics and advantages of the present invention will be presented in the following description, and will become apparent in part through the description, or may be learned by carrying out the present invention. The object and other advantages of the present invention can be realized and achieved by the description, the claims, and the structure particularly highlighted in the accompanying drawings.

The technical solutions of the present invention will be described in detail below through the drawings and examples.

Description of the designs

These drawings are intended to provide a better understanding of the present invention, and constitute part of the instructions for use. They are used to explain the present invention with the examples of the present invention, and do not constitute a limitation of the present invention. In the drawings below:

FIG.1 Structural diagram of a dual thermal and cold energy storage system in the embodiment of the present invention;

FIG.1 Pipe connection diagram in the embodiment of the present invention.

Specific embodiments

Preferred examples of the present invention will be described below with reference to the accompanying drawings. It should be understood that the preferred examples described herein are used only to illustrate and explain the present invention, but not to limit the present invention.

The present invention provides a dual storage system for thermal and cold energy, comprising as illustrated in FIG.1:

A power unit enabling transmission of electricity generated from a renewable energy network and a non-renewable energy network to a heating device and a refrigeration device;

A heating device allowing conversion of electrical heat according to the electricity transmitted in order to achieve thermal energy storage;

A refrigeration device enabling conversion of electric refrigeration according to the transmitted electricity in order to achieve cold energy storage;

A deployment unit allowing future deployment of currently stored thermal and cold energy according to the actual demand for thermal and cold energy;

A control module making it possible to control the first group of valves connected to the heating device and the second group of valves connected to the refrigeration device according to future deployment, and to store and rationally evacuate thermal and cold energy according to the result control.

In this embodiment, the non-renewable energy network refers to a thermal energy network, and the renewable energy network refers to a solar or hydro or other renewable energy network.

In this embodiment, the heater may refer to a device that supplies heat to the heating line, and the cooling device refers to a device that exhausts cold air to the cooling line.

In this embodiment, the actual heating and cooling demand refers to the thermal energy requested, the heating duration, the cold energy requested, and the cooling duration.

In this embodiment, future deployment refers to the mode of discharging and storing energy in the heating device and the cooling device, i.e. subsequently controlling the valves on different devices to effectively control heating and cooling, realize the rational storage of energy in the heating device and the cooling device, and discharge the energy to the connected pipeline according to the corresponding devices.

The beneficial effect of the above technical solution is to store cold and thermal energy from both the renewable network and the non-renewable network, to efficiently deploy the stored cold and thermal energy according to actual needs, and to thus achieve the rational storage and emission of thermal and cold energy through the control of the valves.

The present invention provides a dual storage system for thermal and cold energy, and its power unit comprises:

A first electrical energy collection unit for collecting the first electrical energy from the non-renewable energy network and constructing the first generation curve, the first power supply curve and the first generation loss curve on the basis of the non-renewable energy network;

A second electrical energy collection unit for collecting the second electrical energy from the renewable energy network and constructing the second generation curve, the second power curve and the second generation loss curve based on the network renewable energy;

A first determination unit for determining the first stability coefficient of the non-renewable energy network;

A second determination unit for determining the second stability coefficient of the renewable energy network;

A first acquisition unit for acquiring the first electricity efficiently transmitted from the non-renewable energy network according to the first stability coefficient;

a second acquisition unit for acquiring the second electricity efficiently transmitted from the renewable energy network according to the second stability coefficient;

A heating switch distribution unit for distributing to the heating device the first switch group of the non-renewable energy network and the second group of switches of the renewable energy network according to the heating demand of the heating device and the first electricity transmitted efficiently;

A refrigeration switch distribution unit for distributing to the refrigeration device the third switch group of the non-renewable energy network and the fourth switch group of the renewable energy network according to the refrigeration demand of the refrigeration device and the second electricity transmitted efficiently;

In this embodiment, the generation curve refers to the curve formed by the quantity of electricity from the electrical network at different times; power curve refers to the curve formed by the amount of electricity consumed from the power grid at different times; Loss curve refers to the curve formed by the loss of electricity from the power grid at different times which is caused by external disturbances.

In this embodiment, the stability coefficient is mainly calculated on the basis of the quantity of electricity generated, the quantity of electricity lost and the quantity of electricity offered.

In this embodiment, the electrical energy transmitted efficiently is the product of the quantity of electricity generated multiplied by the stability coefficient.

In this embodiment, the sum between the product of the first effective electrical energy multiplied by time and the product of the second effective electrical energy multiplied by time represents the effective electrical energy that can be generated at the same time by the network non-renewable energy and the renewable energy network.

In this embodiment, the total effective electrical energy corresponding to the heating demand, and the sum between the product of the first effective electrical energy multiplied by time and the product of the second effective electrical energy multiplied by time, can planning the first switch group and the second switch group and the corresponding intelligent exclusive switch group is similar to this principle.

The quantity of electricity transmitted at a unit time corresponding to each switch of each group of switches is known. Therefore, different groups of switches can be obtained by matching the combination of switches with the total effective electrical energy.

The beneficial effect of the above technical solution is to determine the corresponding stability coefficients according to the curves of different power networks and distribute corresponding switch groups to different devices to reasonably and efficiently store energy for different devices, and provide a basis for the further realization of the rational storage and evacuation of thermal and cold energy.

The present invention provides a dual storage system for thermal and cold energy, and its first determination unit comprises:

A first factor determination block for determining an adjustment factor of the first stability coefficient; 41 = ST 2e — sli — Zn nl £oi1=1 s0j1

Where, n1 represents a representative time point based on the first generation curve; s0;, represents the curve value of the i1th time point on the first generation curve; s1;, represents the curve value of 1°11° time point on the first power curve; s2;, represents the curve value of 1’11° time point on the first generation loss curve; 01 represents the adjustment factor of the first stability coefficient;

A first coefficient determination block for calculating a first stability coefficient on the basis of the adjustment factor determined by the first factor determination block;

Wi=1- >“ ee Se — Se x In(1 + 01) i1=1 [S0;1 + S0j1—1

Where, W1 represents the first stability coefficient of the non-renewable energy network; In(1 + 01) represents an adjustment function of the first stability coefficient; s0;,_, represents the curve value of the il-1° time point on the first generation curve.

The beneficial effect of the above technical solution is to analyze the curve values on different curves, effectively obtain the adjustment factor,

comparatively analyzing the curve values at adjacent points of time based on the adjustment factor, and obtaining the first stability coefficient to facilitate the subsequent storage of thermal energy.

The present invention provides a dual storage system for thermal and cold energy, and its second determination unit comprises:

a second factor determination block for determining an adjustment factor of the second stability coefficient; 92 = ST not — S21j, — a nl Zui1=1 S20;1

Where, n1 represents a representative time point based on the second generation curve and is equivalent to the number of representative time points on the first generated curve; s20;, represents the curve value of the 1st time point on the second generation curve; s21;, represents the curve value of the i1th time point on the second power curve; s22;4 represents the curve value of the 1st time point on the second generation loss curve; 02 represents the adjustment factor of the second stability coefficient;

a second coefficient determination block for calculating a second stability coefficient on the basis of the adjustment factor determined by the second factor determination block;

W2=1- >“ PE x In(1 + 82) i1=1 1820j1 + S20j1—1

Where, W2 represents the second stability coefficient of the renewable energy network; In(1 + 02) represents an adjustment function of the second stability coefficient; s20;4_, represents the curve value of the i1-1° time point on the second generation curve.

The beneficial effect of the above technical solution is to analyze the curve values on different curves, effectively obtain the adjustment factor, comparatively analyze the curve values at adjacent time points on the basis of the adjustment factor, and to obtain the second stability coefficient to facilitate the subsequent storage of cold energy.

The present invention provides a dual storage system for thermal and cold energy, and its heating device comprises:

A first thermal energy storage unit for performing heat conversion of electricity transmitted by the non-renewable energy network on the basis of the first switch group connected to the non-renewable energy network, and perform a first storage of thermal energy;

A second thermal energy storage unit for performing heat conversion of electricity transmitted by the renewable energy network on the basis of the second switch group connected to the renewable energy network, and performing second thermal energy storage;

A combined thermal and cold energy storage unit for performing thermal energy storage on the basis of the first thermal energy storage and the second thermal energy storage.

The beneficial effect of the above technical solution is to respectively store thermal energy through groups of switches connected to different power grids to realize thermal energy storage.

The present invention provides a dual storage system for thermal and cold energy, and its deployment unit comprises:

An energy determination unit for acquiring the thermal energy currently stored by the heating device and the cold energy currently stored by the refrigeration device;

A demand analysis unit for performing an analysis of the actual cooling and heating demand, and determining the requested quantity of thermal energy and the duration of the thermal energy demand, as well as the demand for cold energy and the duration of cold energy demand;

A duration determination unit for determining the first available duration of the currently stored thermal energy according to the requested quantity of thermal energy and the duration of thermal energy demand;

If the thermal energy demand duration is less than the first available duration, determining the transmissible thermal energy corresponding to each first switch of the first switch group and the transmissible cold energy corresponding to each second switch of the second switch group;

A switch control unit for determining the first stop switch and controlling the closing of the first stop switch according to the remaining thermal energy difference between the thermal energy currently stored in the heater and the requested quantity thermal energy, the sequence of transmissible thermal energy of the first group of switches, the sequence of transmissible cold energy of the second group of switches and the stability standards for the electrothermal conversion of the non-renewable energy networks and the networks of 'renewable energy;

If the thermal power demand duration is equal to the first available duration, controlling each first switch of the first switch group and each second switch of the second switch group to remain unchanged;

If the thermal energy demand duration is greater than the second available duration, then determine whether the cold energy currently stored in the refrigeration device can meet the requested amount of cold energy and the duration of the heat demand. cold energy;

A switching direction control unit for obtaining an idling switch of the refrigeration device and controlling the switching direction of the idling switch as switches to be increased for the heating device to determine that the cold energy currently stored in the refrigeration device meets the requested quantity of cold energy and the duration of cold energy demand.

In this embodiment, the available duration is calculated based on dividing the thermal energy demand by the amount of thermal energy consumption per unit time.

In this embodiment, each switch corresponds to a certain transmitted energy, so the sequence of the first switch group and the second switch group are obtained by converting the stability standards to determine the first stop switch.

The beneficial effect of the technical solution mentioned above is to analyze the demand and calculate the available duration of thermal and cold energy consumption; it is possible to effectively discuss the control of corresponding switches under different consumption durations according to different types; when the heat power demand duration is greater than the second available duration, the idle switch corresponding to the refrigeration device is determined to control the switching connection direction, so as to realize the efficient transfer of the switch of the heating device.

The present invention provides a dual storage system for thermal and cold energy, and its control module comprises:

A valve determination unit for determining, according to future deployment, whether the thermal energy of the heater should be released, and if necessary, determining the first group of valves according to the thermal energy release standard, at the same time determining whether to release cold energy from the cooling device and determining, if necessary, the second group of valves in accordance with the cold energy release standard;

A temperature determination unit for estimating, according to the first valve group, the first temperature of the thermal energy pipe after releasing part of the thermal energy from the heater to the thermal energy pipe;

Estimate, according to the second group of valves, the third temperature of the cold energy pipe after releasing part of the cold energy from the refrigeration device to the cold energy pipe;

Determine the second temperature of the constant temperature pipe connected to the thermal power pipe based on the first temperature and determine the fourth temperature of the constant temperature pipe connected to the cold power pipe based on the third temperature;

Determining the final temperature of the constant temperature pipeline on the basis of the second temperature and the fourth temperature, and the duration of the second temperature and the duration of the fourth temperature;

A temperature evaluation unit for performing the corresponding release according to the determined first valve group and the second valve group when the final temperature is within the normal temperature range;

If the final temperature Tzy; is less than the minimum value Tyn of the normal temperature range, determine, according to Tuin — Tzu: the number of closed valves in the second group of valves;

If the final temperature Tzy; is less than the maximum Tyax value of the normal temperature range, determine, according to Tzy; — Tmax, the number of closed valves in the first group of valves.

In this embodiment, the first valve group and the second valve group are the connection between the device and the discharge pipe, and the switch group is the connection between the electrical network and the device.

In this embodiment, it is a pipe connection diagram, as illustrated in Figure 2.

In this embodiment, the standard temperature range is preset, and the thermal energy release standard and the cold energy release standard are also preset, in order to determine the corresponding valve group.

The beneficial effect of the above technical solution is to determine the corresponding valve group according to the corresponding release label, and then effectively ensure the reasonable range of the release temperature according to the final energy temperature after the releasing energy according to different devices to the constant temperature pipe, which can effectively ensure the life of the pipes and effectively neutralize the fluid with excessive temperature difference to avoid damage to the surrounding environment after the 'evacuation.

The present invention provides a dual storage system for thermal and cold energy, and its temperature evaluation unit comprises:

A valve determination block for determining, according to Tyn —

Tzyr. the number of closed valves in the second group of valves; ‘vi fen an to —

AT AT

Where, Nl represents the number of closed valves in the second group of valves; al represents the representative coefficient for the minimum value of the normal temperature range; a2 represents the representative coefficient for the average value of the normal temperature range, and a2+a1=1, a2>a1; AT represents the refrigeration variant of each valve of the second valve group for constant temperature driving; [] represents the rounding symbol.

In this embodiment, the operating hours of the open valves controlled in all groups are the same.

The beneficial effect of the above technical solution is to calculate the number of closed valves based on the maximum value and minimum value in the standard temperature range to provide an effective control basis and provide an effective basis for rational disposal and storage.

Obviously, technicians relating to this field can make various modifications and variations for the present invention. All this is done without departing from the spirit and scope of the present invention. Thus, provided that such modifications and variations of the present invention are within the scope of the claims and their equivalents of the present invention, the present invention is also intended to include such modifications and variations.

Claims (8)

CLAIM 1. Dual thermal and cold energy storage system, comprising: A power supply unit allowing transmission of electricity generated from a renewable energy network and a non-renewable energy network to a heating device and a refrigeration device; A heating device allowing conversion of electrical heat according to the electricity transmitted in order to achieve thermal energy storage; A refrigeration device enabling conversion of electric refrigeration according to the transmitted electricity in order to achieve cold energy storage; A deployment unit allowing future deployment of currently stored thermal and cold energy according to the actual demand for thermal and cold energy; A control module making it possible to control the first group of valves connected to the heating device and the second group of valves connected to the refrigeration device according to future deployment, and to store and rationally evacuate thermal and cold energy according to of the control result. 2. Dual thermal and cold energy storage system according to claim 1, characterized in that the power supply unit comprises: A first electrical energy collection unit making it possible to collect the first electrical energy from the energy network non-renewable and constructing the first generation curve, the first supply curve and the first generation loss curve on the basis of the non-renewable energy network; A second electrical energy collection unit for collecting the second electrical energy from the renewable energy network and constructing the second generation curve, the second power supply curve and the second generation loss curve on the basis of the network renewable energy; A first determination unit for determining the first stability coefficient of the non-renewable energy network; A second determination unit for determining the second stability coefficient of the renewable energy network; A first acquisition unit for acquiring the first electricity efficiently transmitted from the non-renewable energy network according to the first stability coefficient; a second acquisition unit for acquiring the second electricity efficiently transmitted from the renewable energy network according to the second stability coefficient; A heating switch distribution unit for distributing to the heating device the first switch group of the non-renewable energy network and the second group of switches of the renewable energy network according to the heating demand of the heating device and the first electricity transmitted efficiently; A refrigeration switch distribution unit for distributing to the refrigeration device the third switch group of the non-renewable energy network and the fourth switch group of the renewable energy network according to the refrigeration demand of the refrigeration device and the second electricity transmitted efficiently. 3. Dual thermal and cold energy storage system according to claim 2, characterized in that the first determination unit comprises: A first factor determination block making it possible to determine an adjustment factor of the first stability coefficient; 4 = ST = —Sli1— Zu nl Zui1=1 s0;1 Where, n1 represents a representative time point based on the first generation curve; s0;, represents the curve value of the 1st time point on the first generation curve; s1;, represents the curve value of the 11th time point on the first power curve; s2;, represents the curve value of the i1° time point on the first generation loss curve; 01 represents the adjustment factor of the first stability coefficient; A first coefficient determination block for calculating a first stability coefficient on the basis of the adjustment factor determined by the first factor determination block; w1=1- > es x In(1 + 81) i1=1 1S0j1 + SOj1—1 Where, W1 represents the first stability coefficient of the non-renewable energy network; In(1 + 01) represents an adjustment function of the first stability coefficient; s0;4_, represents the curve value of the il-1° time point on the first generation curve. 4. Dual thermal and cold energy storage system according to claim 2, characterized in that the second determination unit comprises: A second factor determination block making it possible to determine an adjustment factor of the second stability coefficient; 92 = ST ps — S21j4 — Zi nl Zui1=1 S20;1 Where, n1 represents a representative time point based on the second generation curve and is equivalent to the number of representative time points on the first generated curve; s20;, represents the curve value of the 1st time point on the second generation curve; s21;, represents the curve value of the 1st time point on the second power curve; s22;, represents the curve value of the 1st time point on the second generation loss curve; 02 represents the adjustment factor of the second stability coefficient; a second coefficient determination block for calculating a second stability coefficient on the basis of the adjustment factor determined by the second factor determination block; W2=1- >" ee — Si x In(1 + 82) i1=1 1520; + S20;1_1 Where, W2 represents the second stability coefficient of the renewable energy network; In(1 + 02) represents a function for adjusting the second stability coefficient; s20;4_4 represents the curve value of the i1-1° time point on the second generation curve. 5. Double thermal and cold energy storage system according to claim 2, characterized in that the heating device comprises: A first thermal energy storage unit making it possible to carry out heat conversion of the electricity transmitted by the non-renewable energy network on the basis of the first switch group connected to the non-renewable energy network, and performing first thermal energy storage; A second thermal energy storage unit for performing heat conversion of electricity transmitted by the renewable energy network on the basis of the second switch group connected to the renewable energy network, and performing second thermal energy storage; A combined thermal and cold energy storage unit for performing thermal energy storage on the basis of the first thermal energy storage and the second thermal energy storage. 6. Dual thermal and cold energy storage system according to claim 1, characterized in that the deployment unit comprises: An energy determination unit making it possible to acquire the thermal energy currently stored by the heating device and the cold energy currently stored by the refrigeration device; A demand analysis unit for performing an analysis of the actual cooling and heating demand, and determining the requested quantity of thermal energy and the duration of the thermal energy demand, as well as the demand for cold energy and the duration of cold energy demand; A duration determination unit for determining the first available duration of the currently stored thermal energy according to the requested quantity of thermal energy and the duration of thermal energy demand; If the thermal energy demand duration is less than the first available duration, determining the transmissible thermal energy corresponding to each first switch of the first switch group and the transmissible cold energy corresponding to each second switch of the second switch group; A switch control unit for determining the first stop switch and controlling the closing of the first stop switch according to the remaining thermal energy difference between the thermal energy currently stored in the heater and the requested quantity thermal energy, the sequence of transmissible thermal energy of the first group of switches, the sequence of transmissible cold energy of the second group of switches and the stability standards for the electrothermal conversion of the non-renewable energy networks and the networks of 'renewable energy; If the thermal power demand duration is equal to the first available duration, controlling each first switch of the first switch group and each second switch of the second switch group to remain unchanged; If the thermal energy demand duration is greater than the second available duration, then determine whether the cold energy currently stored in the refrigeration device can meet the requested amount of cold energy and the duration of the heat demand. cold energy; A switching direction control unit for obtaining an idling switch of the refrigeration device and controlling the switching direction of the idling switch as switches to be increased for the heating device to determine that the cold energy currently stored in the refrigeration device meets the requested quantity of cold energy and the duration of cold energy demand. 7. Dual thermal and cold energy storage system according to claim 1, characterized in that the control module comprises: A valve determination unit for determining, depending on future deployment, whether the thermal energy of the heater should be released, and if necessary, determining the first group of valves according to the thermal energy release standard, at the same time determining whether to release the cold energy of the cooling device and determining, if necessary, the second group of valves in accordance with the cold energy release standard; A temperature determination unit for estimating, according to the first valve group, the first temperature of the thermal energy pipe after releasing part of the thermal energy from the heater to the thermal energy pipe; Estimate, according to the second group of valves, the third temperature of the cold energy pipe after releasing part of the cold energy from the refrigeration device to the cold energy pipe; Determine the second temperature of the constant temperature pipe connected to the thermal power pipe based on the first temperature and determine the fourth temperature of the constant temperature pipe connected to the cold power pipe based on the third temperature; Determining the final temperature of the constant temperature pipeline on the basis of the second temperature and the fourth temperature, and the duration of the second temperature and the duration of the fourth temperature; A temperature evaluation unit for performing the corresponding release according to the determined first valve group and the second valve group when the final temperature is within the normal temperature range; If the final temperature Tzy; is less than the minimum value Tyn of the normal temperature range, determine, according to Tyn — Tzu, the number of closed valves in the second group of valves; If the final temperature Tzy; is less than the maximum Tyax value of the normal temperature range, determine, according to Tzy; — Tmax, the number of closed valves in the first group of valves. 8. Dual thermal and cold energy storage system according to claim 7, characterized in that the temperature evaluation unit comprises: A valve determination block making it possible to determine, according to Tyn — Tzur: the number of valves closed in the second group of valves; Tuin + Tmax Ni = an Pay = Taur La 2 Rate AT AT Where, Nl represents the number of closed valves in the second group of valves; al represents the representative coefficient for the minimum value of the normal temperature range; a2 represents the representative coefficient for the average value of the normal temperature range, and a2+a1=1, a2>a1; AT represents the refrigeration variant of each valve of the second valve group for constant temperature driving; [] represents the rounding symbol.