CN117146397B - Cold accumulation temperature optimization control method and system for chilled water air conditioner system - Google Patents

Abstract

The invention relates to a cold accumulation temperature optimization control system and a cold accumulation temperature optimization control method of a water cold accumulation air conditioning system, wherein the system comprises a refrigerating unit, a cold accumulation tank, a chilled water return pipe, a chilled water supply pipe, a chilled water pump, a cold accumulation pump, a cold discharge pump, a cold gauge and a controller, wherein the cold gauge accumulates the cold amount used by the metering system, the controller is used for determining the current total day cold supply amount Q _real, assigning the current total day cold supply amount Q _next to the next day predicted cold supply amount Q _next, comparing the next day predicted cold supply amount Q _next with the theoretical maximum cold accumulation amount Q _max of the cold accumulation tank, and determining the optimal cold accumulation temperature t _set of the cold accumulation tank; the controller is also used for controlling the system to enter a cold accumulation mode running state or a stop state according to the optimal cold accumulation temperature t _set. The invention can not only just meet the cold energy required in the next day, but also improve the outlet water temperature of the refrigerating unit during cold accumulation working condition, improve the COP of the refrigerating unit, ensure the refrigerating unit to operate under the working condition of high efficiency, and realize the energy-saving operation of the water cold accumulation air conditioning system.

Description

Cold accumulation temperature optimization control method and system for chilled water air conditioner system

Technical Field

The invention relates to the technical field of air conditioner control, in particular to a cold accumulation temperature optimization control method and system of a chilled water storage air conditioner system.

Background

With the high-speed development of the economy in China, the development of the third industry is rapid, public buildings occupy a large share in new buildings, wherein the application of a central air conditioner is very wide, and the energy consumption of the central air conditioner accounts for about 40% of the total energy consumption of the public buildings. Many cities can be air conditioned up to 50% of peak local grid loads. Therefore, the energy-saving research in the air conditioner field becomes a very important part of energy-saving work in China, and the air conditioner energy-saving research has great significance on energy conservation. In the 90 s, professional journals in domestic refrigeration and heating industries began to introduce an advanced and novel central air conditioning system, namely a cold accumulation air conditioning system, to the domestic, wherein the water cold accumulation air conditioning system is widely applied to various projects due to excellent economic benefits. The water cold storage technology utilizes night valley electricity period, uses a conventional refrigerating unit to prepare cold water, stores the cold water in a water tank, uses electricity peak period in the daytime the next day, and uses the stored cold water to supply cold for users. In the prior art, a mode adopted by a common water cold storage air conditioning system is that the water inlet and outlet temperature of 4/12 ℃ is fixed, the water is supplied for cooling all the year round, the maximum temperature difference can be obtained in the mode, the theoretical cold storage amount of the water cold storage system is maximum, and the economic benefit is also maximum under the policy of peak-to-valley electricity price. However, for the building with annual cold supply, the building needs to be cooled in transitional seasons and even winter, in the period, the actual cold load of the building is far smaller than the theoretical cold storage amount, if the cold storage is performed according to the mode of 4/12 ℃, the situation that the once cold storage amount is too large and the whole cold storage amount can be completely discharged only after a plurality of days of cold storage is needed, so that a large amount of cold storage amount remains, and in the cold storage period, the absolute heat preservation cannot be realized, the cold amount is lost, and the energy waste is caused. Therefore, an optimal control algorithm is needed for the cold accumulation temperature, when the actual cold load is smaller, the proper cold accumulation temperature is selected, the cold accumulation amount just meets the demand amount of the next day when full storage is realized, the waste of the cold accumulation amount is avoided, and meanwhile, the proper cold accumulation temperature can improve the water outlet temperature of the refrigerating unit during cold accumulation, so that the COP of the refrigerating unit is improved to some extent, and the energy-saving effect can be achieved on the system.

Disclosure of Invention

The invention aims to solve the technical problem of providing a cold accumulation temperature optimization control system and method of a chilled water storage air conditioning system aiming at the defects of the prior art.

The technical scheme for solving the technical problems is as follows: the cold accumulation temperature optimization control system of the chilled water cold accumulation air conditioning system comprises a refrigerating unit, a cold accumulation tank, a chilled water return pipe, a chilled water supply pipe, a chilled water pump, a cold accumulation pump, a cold discharge pump and a controller, wherein the chilled water return pipe, the chilled water pump, the refrigerating unit, the chilled water supply pipe and a user terminal are sequentially communicated and form a circulating water loop, the chilled water return pipe, the cold accumulation tank, the cold discharge pump, the chilled water supply pipe and the user terminal are sequentially communicated and form a cold discharge loop, the cold accumulation tank, the cold accumulation pump and the refrigerating unit are sequentially communicated and form a cold accumulation loop, a cold gauge is arranged on the chilled water supply pipe, and the refrigerating unit, the cold gauge, the chilled water pump, the cold accumulation pump, the cold discharge pump and a temperature measurement cable are respectively electrically connected with the controller;

the cold gauge accumulates the using cold energy of the metering system and sends the accumulated using cold energy to the controller;

The controller obtains the current total-day cold supply amount Qrea l through the difference value of the accumulated cold supply amounts at the same time point of the front day and the rear day, and assigns the current total-day cold supply amount Qrea l to the predicted cold supply amount Q _next of the next day so as to compare the predicted cold supply amount Q _next of the next day with the theoretical maximum cold storage amount Q _max of the cold storage tank and determine the optimal cold storage temperature t _set of the cold storage tank;

The controller is also used for controlling the system to enter a cold accumulation mode running state according to the optimal cold accumulation temperature t _set.

The beneficial effects of the invention are as follows: according to the cold accumulation temperature optimization control system of the chilled water cold accumulation air conditioning system, a circulating water loop is formed through the chilled water return pipe, the chilled water pump, the refrigerating unit, the chilled water supply pipe and the user terminal, a cold release loop is formed through the chilled water return pipe, the cold accumulation tank, the cold release pump, the chilled water supply pipe and the user terminal, the cold accumulation tank, the cold accumulation pump and the refrigerating unit form the cold accumulation loop, so that the switching between chilled water accumulation and cold release can be realized, the current total-day cold supply quantity Q _real detected by the cold gauge is used, the optimal cold accumulation temperature t _set is further calculated, the required cold quantity in the next day can be just met, meanwhile, the water outlet temperature of the refrigerating unit in the cold accumulation working condition of the refrigerating unit can be improved, the COP of the refrigerating unit is improved, the refrigerating unit is ensured to operate under the working condition of high efficiency, and the aim of saving energy is achieved. The system has simple structure, stable and reliable operation, can reduce the energy consumption of the system while ensuring the cooling capacity required by users, realizes the energy-saving operation of the chilled water storage air conditioning system, is suitable for the installation and debugging of practical engineering, and can be widely applied to building air conditioning systems.

Based on the technical scheme, the invention can also be improved as follows:

Further: the controller compares the predicted cold supply quantity Q _next of the next day with the theoretical maximum cold storage quantity Q _max of the cold storage tank, and determines the specific implementation of the optimal cold storage temperature t _set of the cold storage tank to be as follows:

if Q _next≥r₁*Q_max, determining that the optimal cold storage temperature t _set is equal to a minimum cold storage temperature threshold t _min;

If r ₂*Q_max＜Q_next＜r₁*Q_max, the optimal cold storage temperature t _set is determined according to the following formula:

t_set＝t_min+

If Q _next≤r₂*Q_max, determining that the optimal cold storage temperature t _set is equal to a maximum cold storage temperature threshold t _max;

Wherein Q _max = c ρ V Δt; c is the specific heat capacity of cooling water, ρ is the density of water when the minimum cold storage temperature threshold t _min, V is the cold storage volume of the cold storage tank, Δt is the temperature difference of water at the inlet and outlet of the cold storage tank, r ₁ and r ₂ are the first cold storage critical coefficient and the second cold storage critical coefficient respectively, and 1 is more than r ₁＞r₂ is more than 0.

The beneficial effects of the above-mentioned further scheme are: the predicted cold supply quantity Q _next on the next day is compared with the theoretical maximum cold storage quantity Q _max of the cold storage tank, and the cold storage tank is divided into different gradients according to the size relation of the predicted cold supply quantity Q _next and the theoretical maximum cold storage quantity Q _max, so that the cold storage temperature reaches maximum rationalization, the cold supply quantity required by the water cold storage on the next day can be met, the excessive cold supply quantity can not be caused, the energy waste caused by the loss of the cold supply quantity can be avoided, the energy consumption of the system can be reduced while the cold supply quantity required by a user is ensured, and the energy-saving operation of the water cold storage air conditioning system can be realized.

Further: a temperature measuring cable is arranged in the cold accumulation tank and used for measuring water temperatures with different heights in the cold accumulation tank;

The controller is also used for calculating the average temperature of water in the cold accumulation tank according to the temperature measurement cable measuring the water temperatures with different heights in the cold accumulation tank, and controlling the working state of the circulating cold accumulation loop according to the average temperature and the preset temperature.

The beneficial effects of the above-mentioned further scheme are: the temperature measuring cable is used for measuring the water temperatures at different heights in the cold storage tank, so that the average temperature of the water in the cold storage tank is accurately calculated, and the temperature in the cold storage tank Shui Wenheng can be dynamically controlled to be within a set range.

Further: the controller controls the working state of the circulating cold accumulation loop according to the average temperature and the preset temperature to be as follows:

And when the average temperature is equal to the preset temperature, controlling the circulating cold accumulation loop to enter a cold accumulation mode stop state, otherwise, controlling the circulating cold accumulation loop to operate according to the optimal cold accumulation temperature t _set, and keeping the circulating cold accumulation loop in the cold accumulation mode operation state.

The beneficial effects of the above-mentioned further scheme are: when the average temperature is equal to the preset temperature, the circulating cold accumulation loop is controlled to enter a cold accumulation mode stop state, so that energy consumption can be reduced, energy waste is reduced, the water cold accumulation state is switched again when the average temperature exceeds the preset temperature, and energy-saving operation is realized on the basis of realizing water cold accumulation.

The invention also provides a cold accumulation temperature optimization control method of the water cold accumulation air conditioning system, which comprises the following steps:

the cold gauge accumulates the using cold energy of the metering system and sends the accumulated using cold energy to the controller;

The controller calculates total-day cold supply amount Qrea l through the accumulated cold quantity difference value of the same time point of the two days before and after, and assigns the total-day cold supply amount Q _real to the next-day predicted cold supply amount Q _next so as to compare the next-day predicted cold supply amount Q _next with the theoretical maximum cold storage amount Q _max of the cold storage tank and determine the optimal cold storage temperature t _set of the cold storage tank.

And the controller controls the system to enter a cold accumulation mode running state according to the optimal cold accumulation temperature t _set.

According to the cold accumulation temperature optimization control method of the chilled water storage air conditioning system, the current total-day cold supply quantity Q _real detected by the cold gauge is used, the optimal cold accumulation temperature t _set is further calculated, the cold quantity required in the next day can be just met, meanwhile, the water outlet temperature of a refrigerating unit in a cold accumulation working condition can be increased, the COP of the refrigerating unit is increased, the refrigerating unit is ensured to operate under a high-efficiency working condition, and the purpose of energy conservation is achieved. The system has simple structure, stable and reliable operation, can reduce the energy consumption of the system while ensuring the cooling capacity required by users, realizes the energy-saving operation of the chilled water storage air conditioning system, is suitable for the installation and debugging of practical engineering, and can be widely applied to building air conditioning systems.

Based on the technical scheme, the invention can also be improved as follows:

Further: the controller compares the predicted cold supply quantity Q _next on the next day with the theoretical maximum cold storage quantity Q _max of the cold storage tank, and determines the optimal cold storage temperature t _set of the cold storage tank. The method specifically comprises the following steps:

if Q _next≥r₁*Q_max, determining that the optimal cold storage temperature t _set is equal to a minimum cold storage temperature threshold t _min;

If r ₂*Q_max＜Q_next＜r₁*Q_max, the optimal cold storage temperature t _set is determined according to the following formula:

t_set＝t_min+

If Q _next≤r₂*Q_max, determining that the optimal cold storage temperature t _set is equal to a maximum cold storage temperature threshold t _max;

Wherein Q _max = c ρ V Δt; c is the specific heat capacity of cooling water, ρ is the density of water when the minimum cold storage temperature threshold t _min, V is the cold storage volume of the cold storage tank, Δt is the temperature difference of water at the inlet and outlet of the cold storage tank, r ₁ and r ₂ are the first cold storage critical coefficient and the second cold storage critical coefficient respectively, and 1 is more than r ₁＞r₂ is more than 0.

The beneficial effects of the above-mentioned further scheme are: the predicted cold supply quantity Q _next on the next day is compared with the theoretical maximum cold storage quantity Q _max of the cold storage tank, and the cold storage tank is divided into different gradients according to the size relation of the predicted cold supply quantity Q _next and the theoretical maximum cold storage quantity Q _max, so that the cold storage temperature reaches maximum rationalization, the cold supply quantity required by the water cold storage on the next day can be met, the excessive cold supply quantity can not be caused, the energy waste caused by the loss of the cold supply quantity can be avoided, the energy consumption of the system can be reduced while the cold supply quantity required by a user is ensured, and the energy-saving operation of the water cold storage air conditioning system can be realized.

Further: the cold accumulation temperature optimization control method of the chilled water accumulation air conditioning system further comprises the following steps:

the temperature measuring cable measures the water temperatures at different heights in the cold accumulation tank in real time, and the controller calculates the average temperature of the water in the cold accumulation tank according to the water temperatures at different heights in the cold accumulation tank and controls the working state of the circulating cold accumulation loop according to the average temperature and the preset temperature.

The beneficial effects of the above-mentioned further scheme are: the temperature measuring cable is used for measuring the water temperatures at different heights in the cold storage tank, so that the average temperature of the water in the cold storage tank is accurately calculated, and the temperature in the cold storage tank Shui Wenheng can be dynamically controlled to be within a set range.

Further: the controller controls the working state of the circulating cold accumulation loop according to the average temperature and the preset temperature, and specifically comprises the following steps:

And when the average temperature is equal to the preset temperature, controlling the circulating cold accumulation loop to enter a cold accumulation mode stop state, otherwise, controlling the circulating cold accumulation loop to operate according to the optimal cold accumulation temperature t _set, and keeping the circulating cold accumulation loop in the cold accumulation mode operation state.

The beneficial effects of the above-mentioned further scheme are: when the average temperature is equal to the preset temperature, the circulating cold accumulation loop is controlled to enter a cold accumulation mode stop state, so that energy consumption can be reduced, energy waste is reduced, the water cold accumulation state is switched again when the average temperature exceeds the preset temperature, and energy-saving operation is realized on the basis of realizing water cold accumulation.

The invention also provides a computer readable storage medium, characterized in that it has stored thereon a computer program which, when executed by a processor, implements the method.

The invention also provides cold accumulation temperature optimization control equipment of the chilled water accumulation air conditioning system, which comprises a communication interface, a memory, a communication bus and the controller, wherein the controller, the communication interface and the memory are communicated with each other through the communication bus;

The memory is used for storing a computer program;

And the controller is used for realizing the step of the cold accumulation temperature optimization control method of the chilled water storage air conditioning system when executing the program stored in the memory.

Drawings

FIG. 1 is a schematic diagram of a cold storage temperature optimizing control system of a chilled water storage air conditioning system according to an embodiment of the invention;

Fig. 2 is a flow chart of a cold storage temperature optimizing control method of a chilled water storage air conditioning system according to an embodiment of the invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. The refrigerating unit comprises a refrigerating unit body 2, a cold storage tank 3, a cold storage tank 4, a chilled water return pipe 5, a chilled water supply pipe 6, a controller 7, a chilled water pump 8, a cold storage pump 9, a cold discharge pump 10 and a temperature measuring cable.

Detailed Description

The principles and features of the present invention are described below with reference to the drawings, the examples are illustrated for the purpose of illustrating the invention and are not to be construed as limiting the scope of the invention.

As shown in fig. 1, the cold accumulation temperature optimization control system of the chilled water cold accumulation air conditioning system comprises a refrigerating unit 1, a cold accumulation tank 2, a chilled water return pipe 4, a chilled water supply pipe 5, a chilled water pump 7, a cold accumulation pump 8, a cold discharge pump 9 and a controller 6, wherein the chilled water return pipe 4, the chilled water pump 7, the refrigerating unit 1, the chilled water supply pipe 5 and a user terminal are sequentially communicated and form a circulating water loop, the chilled water return pipe 4, the cold accumulation tank 2, the cold discharge pump 9, the chilled water supply pipe 5 and the user terminal are sequentially communicated and form a cold discharge loop, the cold accumulation tank 2, the cold accumulation pump 8 and the refrigerating unit 1 are sequentially communicated and form a cold accumulation loop, the chilled water supply pipe 5 is provided with a cold gauge 3, and the refrigerating unit 1, the cold gauge 3, the chilled water pump 7, the cold accumulation pump 8, the cold discharge pump 9 and a temperature measurement cable 10 are respectively and electrically connected with the controller 6.

In practice, if 1 is shown, each pipeline is further provided with an electric valve, so that the controller 6 controls different valve opening and closing states to realize different pipeline switching, and detailed description thereof will not be repeated here.

The cold gauge 3 accumulates the cold energy used by the metering system and sends the cold energy to the controller 6;

The controller 6 obtains the current total-day cold supply amount Qrea l through the difference value of the accumulated cold supply amounts at the same time point of the two days before and after, and assigns the current total-day cold supply amount Qrea l to the predicted cold supply amount Q _next of the next day so as to compare the predicted cold supply amount Q _next of the next day with the theoretical maximum cold storage amount Q _max of the cold storage tank 2 and determine the optimal cold storage temperature t _set of the cold storage tank 2;

The controller 6 is further configured to control the system to enter a cold accumulation mode operation state according to the optimal cold accumulation temperature t _set.

According to the cold accumulation temperature optimization control system of the chilled water cold accumulation air conditioning system, a circulating water loop is formed through the chilled water return pipe 4, the chilled water pump 7, the refrigerating unit 1, the chilled water supply pipe 5 and the user terminal, a cold release loop is formed through the chilled water return pipe 4, the cold accumulation tank 2, the cold release pump 9, the chilled water supply pipe 5 and the user terminal, the cold accumulation tank 2, the cold accumulation pump 8 and the refrigerating unit 1 form the cold accumulation loop, so that the switching between chilled water accumulation and cold release can be realized, the current total-day cold supply quantity Q _real detected by the cold gauge 3 is used, the optimal cold accumulation temperature t _set is further calculated, the required cold quantity in the next day can be just met, the water outlet temperature of the refrigerating unit in cold accumulation working condition can be improved, the COP of the refrigerating unit is improved, the refrigerating unit is ensured to run under the high-efficiency working condition, and the aim of saving energy is achieved. The system has simple structure, stable and reliable operation, can reduce the energy consumption of the system while ensuring the cooling capacity required by users, realizes the energy-saving operation of the chilled water storage air conditioning system, is suitable for the installation and debugging of practical engineering, and can be widely applied to building air conditioning systems.

In one or more embodiments of the present invention, the controller 6 compares the predicted next day cold supply Q _next with the theoretical maximum cold storage Q _max of the cold storage tank 2, and determines the optimal cold storage temperature t _set of the cold storage tank 2 as follows:

if Q _next≥r₁*Q_max, determining that the optimal cold storage temperature t _set is equal to a minimum cold storage temperature threshold t _min;

If r ₂*Q_max＜Q_next＜r₁*Q_max, the optimal cold storage temperature t _set is determined according to the following formula:

t_set＝t_min+3*Q_next/Q_max

If Q _next≤r₂*Q_max, determining that the optimal cold storage temperature t _set is equal to a maximum cold storage temperature threshold t _max;

Wherein Q _max = c ρ V Δt; c is the specific heat capacity of cooling water, 4.2 x 10 ³ J/(kg x ℃) is taken, ρ is the density of water when the minimum cold storage temperature threshold t _min, 10 ³kg/m³, V is the cold storage volume of the cold storage tank 2, Δt is the temperature difference of water at the inlet and outlet of the cold storage tank, 8 ℃ is taken, r ₁ and r ₂ are the first cold storage critical coefficient and the second cold storage critical coefficient respectively, and 1 is more than r ₁＞r₂ is more than 0. In actual engineering, the cold storage volume of the cold storage tank is known, and the theoretical maximum cold storage amount Qmax of the cold storage tank is a constant.

The predicted cold supply quantity Q _next on the next day is compared with the theoretical maximum cold storage quantity Q _max of the cold storage tank 2, and the cold storage tank is divided into different gradients according to the size relation of the predicted cold supply quantity Q _next and the theoretical maximum cold storage quantity Q _max, so that the cold storage temperature reaches maximum rationalization, the cold supply quantity required by the water cold storage on the next day can be met, the excessive cold supply quantity is not caused, the energy waste caused by the loss of the cold supply quantity is avoided, the energy consumption of the system can be reduced while the required cold supply quantity of a user is ensured, and the energy-saving operation of the water cold storage air conditioning system is realized.

In the examples of the present invention, r ₁ was 0.85, r ₂ was 0.625, t _min was 4℃and t _max was 7 ℃.

Since the changes of the cold loads of two adjacent days are not large, the accumulated cold supply quantity Q _real in the whole day predicts that the cold supply quantity Q _next in the next day does not generate larger errors.

In this embodiment, the magnitude relation between the predicted cooling capacity Q _next and the theoretical maximum cooling capacity Q _max of the cooling storage tank 2 on the next day is divided into different gradients, so that different cooling load conditions can be considered, and the cooling storage temperature can be maximally rationalized. wherein the first gradient takes 85% of theoretical maximum cold accumulation quantity Q _max as a critical value, when Q _next>＝0.85Q_max is adopted, cold accumulation is carried out at night according to t _set =4deg.C, due to certain cold accumulation loss in the cold accumulation process, the cold accumulation is carried out according to the cold accumulation temperature of the theoretical maximum cold accumulation quantity, And a certain margin is reserved, so that the partial loss can be counteracted, and the cold accumulation stability is ensured. the second gradient takes 62.5% of theoretical maximum cold accumulation amount Q _max of the cold accumulation tank as the minimum critical value, takes 85% of theoretical maximum cold accumulation amount Q _max of the cold accumulation tank as the maximum critical value, and when 0.625Q _max<Q_next<0.85Q_max is adopted, cold accumulation at night is carried out according to t _set＝4+(3*Q_next/Q_max), At this time, if the cold accumulation temperature set value is 4 ℃, the cold accumulation quantity redundancy is caused, so that the cold accumulation temperature set value is optimized according to the proportion of the actual cold accumulation quantity to the theoretical maximum cold accumulation quantity, the cold accumulation temperature is set in such a way, the cold accumulation quantity required in the next day can be just met, meanwhile, the water outlet temperature of the refrigerating unit during the cold accumulation working condition can be increased, the COP of the refrigerating unit is increased, the refrigerating unit is ensured to operate under the working condition of high efficiency, and the purpose of energy conservation is achieved. The third gradient takes 62.5% of the theoretical maximum cold accumulation quantity Q _max as a critical value, when Q _next<＝0.625Q_max is used, cold accumulation is carried out at night according to t _set =7deg.C, the cold supply quantity required in the next day is smaller, in order to give consideration to the efficiency and load rate of the refrigerating unit and the matching degree of the cold accumulation quantity and the cold supply quantity, And determining to store cold at 7 ℃.

In one or more embodiments of the present invention, a temperature measurement cable 10 is disposed in the cold storage tank 2, for measuring water temperatures at different heights in the cold storage tank 2;

The controller 6 is further configured to calculate an average temperature of water in the cold accumulation tank 2 according to the temperature measurement cable 10 and measure water temperatures at different heights in the cold accumulation tank 2, and control a working state of the circulating cold accumulation loop according to the average temperature and a preset temperature.

The temperature measuring cable 10 is used for measuring the water temperatures at different heights in the cold accumulation tank 2, so that the average temperature of the water in the cold accumulation tank 2 is calculated relatively accurately, and the water in the cold accumulation tank 2 can be controlled dynamically and kept constant within a set range.

Here, the calculation formula of the average temperature t is:

wherein n is an n-layer temperature sensor built in the temperature measuring cable.

In one or more embodiments of the present invention, the controller 6 controls the working state of the circulating cold accumulation circuit according to the average temperature and the preset temperature to specifically implement:

And when the average temperature is equal to the preset temperature, controlling the circulating cold accumulation loop to enter a cold accumulation mode stop state, otherwise, controlling the circulating cold accumulation loop to operate according to the optimal cold accumulation temperature t _set, and keeping the circulating cold accumulation loop in the cold accumulation mode operation state.

By means of the water cold accumulation device, when the average temperature is equal to the preset temperature, water cold accumulation can be suspended, energy consumption is reduced, energy waste is reduced, the water cold accumulation state is switched to again when the average temperature exceeds the preset temperature, energy-saving operation is achieved on the basis of achieving water cold accumulation, the device is suitable for installation and debugging of actual engineering, and the device can be widely applied to building air conditioning systems.

As an example, in the present invention, first, given a theoretical maximum cold accumulation amount Q _max =30000 KWh of the cold accumulation tank, if the predicted cold supply amount Q _next =21000 KWh is the next day, at this time Q _next＝0.7Q_max, at the second gradient, the optimal cold accumulation temperature set value after optimization is t _set＝4+(3*Q_next/Q_max) =6.1 ℃, assuming that the cold accumulation amount in the cold accumulation tank is completely discharged in the same day, the average temperature t=12 ℃ in the cold accumulation tank, the cold accumulation tank starts to accumulate cold, and when t=t _set =6.1 ℃, the cold accumulation is stopped, at this time, the temperature of all water in the cold accumulation tank is 6.1 ℃.

As shown in fig. 2, the invention also provides a cold accumulation temperature optimizing control method of the water cold accumulation air conditioning system, which comprises the following steps:

S1: the cold gauge 3 accumulates the cold energy used by the metering system and sends the cold energy to the controller 6;

S2: the controller 6 calculates the total-day cold supply amount Qrea l according to the accumulated cold quantity difference value of the same time point of the two days before and after, and assigns the total-day cold supply amount Q _real to the next-day predicted cold supply amount Q _next so as to compare the next-day predicted cold supply amount Q _next with the theoretical maximum cold storage amount Q _max of the cold storage tank 2 and determine the optimal cold storage temperature t _set of the cold storage tank 2.

S3: the controller 6 controls the system to enter a cold accumulation mode operation state according to the optimal cold accumulation temperature t _set.

According to the cold accumulation temperature optimization control method of the chilled water storage air conditioning system, the current total-day cold supply quantity Q _real detected by the cold gauge 3 is used, the optimal cold accumulation temperature t _set is further calculated, the cold quantity required in the next day can be just met, meanwhile, the water outlet temperature of a refrigerating unit in the cold accumulation working condition can be increased, the COP of the refrigerating unit is increased, the refrigerating unit is ensured to operate under the working condition of high efficiency, and the purpose of energy conservation is achieved. The system has simple structure, stable and reliable operation, can reduce the energy consumption of the system while ensuring the cooling capacity required by users, realizes the energy-saving operation of the chilled water storage air conditioning system, is suitable for the installation and debugging of practical engineering, and can be widely applied to building air conditioning systems.

In one or more embodiments of the invention, the controller 6 compares the predicted next day cold supply Q _next to the theoretical maximum cold storage Q _max of the cold storage tank 2 to determine an optimal cold storage temperature t _set of the cold storage tank 2. The method specifically comprises the following steps:

if Q _next≥r₁*Q_max, determining that the optimal cold storage temperature t _set is equal to a minimum cold storage temperature threshold t _min;

If r ₂*Q_max＜Q_next＜r₁*Q_max, the optimal cold storage temperature t _set is determined according to the following formula:

t_set＝t_min+3*Q_next/Q_max

If Q _next≤r₂*Q_max, determining that the optimal cold storage temperature t _set is equal to a maximum cold storage temperature threshold t _max;

Wherein Q _max = c ρ V Δt; c is the specific heat capacity of cooling water, ρ is the density of water when the minimum cold storage temperature threshold t _min, V is the cold storage volume of the cold storage tank 2, Δt is the temperature difference of water at the inlet and outlet of the cold storage tank, r ₁ and r ₂ are the first cold storage critical coefficient and the second cold storage critical coefficient respectively, and 1 is more than r ₁＞r₂ is more than 0.

The predicted cold supply quantity Q _next on the next day is compared with the theoretical maximum cold storage quantity Q _max of the cold storage tank 2, and the cold storage tank is divided into different gradients according to the size relation of the predicted cold supply quantity Q _next and the theoretical maximum cold storage quantity Q _max, so that the cold storage temperature reaches maximum rationalization, the cold supply quantity required by the water cold storage on the next day can be met, the excessive cold supply quantity is not caused, the energy waste caused by the loss of the cold supply quantity is avoided, the energy consumption of the system can be reduced while the required cold supply quantity of a user is ensured, and the energy-saving operation of the water cold storage air conditioning system is realized.

Optionally, in one or more embodiments of the present invention, the method for optimally controlling the cold storage temperature of the chilled water storage air conditioning system further includes the following steps:

the temperature measuring cable 10 measures the water temperatures at different heights in the cold accumulation tank 2 in real time, and the controller 6 calculates the average temperature of the water in the cold accumulation tank 2 according to the water temperatures at different heights in the cold accumulation tank 2 and controls the working state of the circulating cold accumulation loop according to the average temperature and a preset temperature.

The temperature measuring cable 10 is used for measuring the water temperatures at different heights in the cold accumulation tank 2, so that the average temperature of the water in the cold accumulation tank 2 is calculated relatively accurately, and the water in the cold accumulation tank 2 can be controlled dynamically and kept constant within a set range.

In one or more embodiments of the present invention, the controller 6 controls the working state of the circulating cold accumulation circuit according to the average temperature and the preset temperature, specifically including the following steps:

And when the average temperature is equal to the preset temperature, controlling the circulating cold accumulation loop to enter a cold accumulation mode stop state, otherwise, controlling the circulating cold accumulation loop to operate according to the optimal cold accumulation temperature t _set, and keeping the circulating cold accumulation loop in the cold accumulation mode operation state.

By making the average temperature equal to the preset temperature, the water cold accumulation can be suspended, the energy consumption is reduced, the energy waste is reduced, and the water cold accumulation state is switched to again when the average temperature exceeds the preset temperature, so that the energy-saving operation is realized on the basis of realizing the water cold accumulation.

The invention also provides a computer readable storage medium, characterized in that it has stored thereon a computer program which, when executed by a processor, implements the method.

The invention also provides cold accumulation temperature optimization control equipment of the chilled water accumulation air conditioning system, which comprises a communication interface, a memory, a communication bus and the controller 6, wherein the controller, the communication interface and the memory are communicated with each other through the communication bus;

The memory is used for storing a computer program;

the controller 6 is configured to implement the method for optimally controlling the cold storage temperature of the chilled water storage air conditioning system when executing the program stored in the memory.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims (10)

1. A cold accumulation temperature optimization control system of a chilled water accumulation air conditioning system is characterized in that: the cold storage device comprises a refrigerating unit (1), a cold storage tank (2), a chilled water return pipe (4), a chilled water supply pipe (5), a chilled water pump (7), a cold storage pump (8), a cold discharge pump (9) and a controller (6), wherein the chilled water return pipe (4), the chilled water pump (7), the refrigerating unit (1), the chilled water supply pipe (5) and a user terminal are sequentially communicated and form a circulating water loop, the chilled water return pipe (4), the cold storage tank (2), the cold discharge pump (9), the chilled water supply pipe (5) and the user terminal are sequentially communicated and form a cold discharge loop, the cold storage tank (2), the cold storage pump (8) and the refrigerating unit (1) are sequentially communicated and form a cold storage loop, a cold gauge (3) is arranged on the chilled water supply pipe (5), and the refrigerating unit (1), the cold gauge (3), the chilled water pump (7), the cold storage pump (8), the cold discharge pump (9) and a temperature measurement cable (10) are respectively electrically connected with the controller (6).

The cold gauge (3) is used for accumulating the using cold energy of the metering system and sending the accumulated using cold energy to the controller (6);

The controller (6) is used for obtaining the current total-day cold supply quantity Qreal through the difference value of the accumulated cold supply quantity at the same time point of the front day and the rear day, assigning the current total-day cold supply quantity Qreal to the predicted cold supply quantity Q _next of the next day, comparing the predicted cold supply quantity Q _next of the next day with the theoretical maximum cold storage quantity Q _max of the cold storage tank (2), and determining the optimal cold storage temperature t _set of the cold storage tank (2);

The controller (6) is also used for controlling the system to enter a cold accumulation mode running state or a stop state according to the optimal cold accumulation temperature t _set.

2. The chilled water storage air conditioning system of claim 1, wherein the chilled water storage temperature optimization control system comprises: the controller (6) compares the predicted cold supply quantity Q _next of the next day with the theoretical maximum cold storage quantity Q _max of the cold storage tank (2), and determines the specific implementation of the optimal cold storage temperature t _set of the cold storage tank (2) as follows:

if Q _next≥r₁*Q_max, determining that the optimal cold storage temperature t _set is equal to a minimum cold storage temperature threshold t _min;

If r ₂*Q_max＜Q_next＜r₁*Q_max, the optimal cold storage temperature t _set is determined according to the following formula:

t_set＝t_min+(3*Q_next/Q_max)

If Q _next≤r₂*Q_max, determining that the optimal cold storage temperature t _set is equal to a maximum cold storage temperature threshold t _max;

Wherein Q _max = c ρ V Δt; c is the specific heat capacity of cooling water, ρ is the density of water when the minimum cold storage temperature threshold t _min, V is the cold storage volume of the cold storage tank (2), Δt is the temperature difference of water at the inlet and outlet of the cold storage tank, r ₁ and r ₂ are a first cold storage critical coefficient and a second cold storage critical coefficient respectively, and 1 is more than r ₁＞r₂ is more than 0.

3. The chilled water storage air conditioning system of claim 1, wherein the chilled water storage temperature optimization control system comprises: a temperature measuring cable (10) is arranged in the cold accumulation tank (2) and is used for measuring water temperatures with different heights in the cold accumulation tank (2);

the controller (6) is also used for calculating the average temperature of water in the cold accumulation tank (2) according to the temperature measurement cable (10) for measuring the water temperatures with different heights in the cold accumulation tank (2), and controlling the working state of the circulating cold accumulation loop according to the average temperature and the preset temperature.

4. The chilled water storage air conditioning system of claim 3, wherein the chilled water storage temperature optimization control system comprises: the controller (6) controls the working state of the circulating cold accumulation loop according to the average temperature and the preset temperature to be as follows:

And when the average temperature is equal to the preset temperature, controlling the circulating cold accumulation loop to enter a cold accumulation mode stop state, otherwise, controlling the circulating cold accumulation loop to operate according to the optimal cold accumulation temperature t _set, and keeping the circulating cold accumulation loop in the cold accumulation mode operation state.

5. A cold storage temperature optimizing control method of a chilled water storage air conditioning system, characterized in that the cold storage temperature optimizing control system of the chilled water storage air conditioning system according to any one of claims 1 to 4 is adopted, and the method comprises the following steps:

the cold gauge (3) accumulates the cold energy used by the metering system and sends the cold energy to the controller (6);

The controller (6) calculates total-day cold supply quantity Qreal through accumulated cold quantity difference values of the same time points of two days before and after, and assigns the total-day cold supply quantity Q _real to the next-day predicted cold supply quantity Q _next so as to compare the next-day predicted cold supply quantity Q _next with the theoretical maximum cold storage quantity Q _max of the cold storage tank (2) and determine the optimal cold storage temperature t _set of the cold storage tank (2);

The controller (6) controls the system to enter a cold accumulation mode operation state according to the optimal cold accumulation temperature t _set.

6. The method of optimizing control of the cold storage temperature of a chilled water storage air conditioning system according to claim 5, wherein the controller (6) compares the predicted next day cold supply amount Q _next with the theoretical maximum cold storage amount Q _max of the cold storage tank (2), and determines the optimal cold storage temperature t _set of the cold storage tank (2) specifically includes the steps of:

if Q _next≥r₁*Q_max, determining that the optimal cold storage temperature t _set is equal to a minimum cold storage temperature threshold t _min;

If r ₂*Q_max＜Q_next＜r₁*Q_max, the optimal cold storage temperature t _set is determined according to the following formula:

t_set＝t_min+(3*Q_next/Q_max)

If Q _next≤r₂*Q_max, determining that the optimal cold storage temperature t _set is equal to a maximum cold storage temperature threshold t _max;

Wherein Q _max = c ρ V Δt; c is the specific heat capacity of cooling water, ρ is the density of water when the minimum cold storage temperature threshold t _min, V is the cold storage volume of the cold storage tank (2), Δt is the temperature difference of water at the inlet and outlet of the cold storage tank, r ₁ and r ₂ are a first cold storage critical coefficient and a second cold storage critical coefficient respectively, and 1 is more than r ₁＞r₂ is more than 0.

7. The method for optimally controlling the cold storage temperature of a chilled water storage air conditioning system according to claim 5, further comprising the steps of:

The temperature measuring cable (10) measures water temperatures at different heights in the cold accumulation tank (2) in real time, and the controller (6) calculates the average temperature of water in the cold accumulation tank (2) according to the water temperatures at different heights in the cold accumulation tank (2) and controls the working state of the circulating cold accumulation loop according to the average temperature and a preset temperature.

8. The cold accumulation temperature optimization control method of the chilled water accumulation air conditioning system as in claim 7 is characterized in that the controller (6) specifically comprises the following steps of:

And when the average temperature is equal to the preset temperature, controlling the circulating cold accumulation loop to enter a cold accumulation mode stop state, otherwise, controlling the circulating cold accumulation loop to operate according to the optimal cold accumulation temperature t _set, and keeping the circulating cold accumulation loop in the cold accumulation mode operation state.

9. A computer readable storage medium, characterized in that a computer program is stored thereon, which computer program, when being executed by a processor, implements the method of any of claims 5 to 8.

10. The utility model provides a cold-storage temperature optimal control equipment of water cold-storage air conditioning system which characterized in that: the device comprises a communication interface, a memory, a communication bus and a controller (6), wherein the controller, the communication interface and the memory are communicated with each other through the communication bus;

The memory is used for storing a computer program;

The controller (6) is configured to implement the method for optimally controlling the cold storage temperature of the chilled water storage air conditioning system according to any one of claims 5 to 8 when executing the program stored in the memory.