CN213574370U - Comprehensive energy conversion device - Google Patents

Abstract

The utility model discloses a comprehensive energy conversion device, its technical scheme main points are including: the energy conversion device comprises a natural gas inlet end, a power grid connecting end, a natural gas demand end, a heat energy demand end, an electric energy demand end, a cold energy demand end, a steam energy demand end and a plurality of energy conversion devices for energy conversion, wherein the natural gas inlet end is directly connected with the natural gas demand end, the grid connecting end is directly connected with the electric energy demand end, the natural gas inlet end is connected with a gas boiler, a gas turbine and a gas internal combustion engine, the power grid connecting end is connected with a heat pump, an electric refrigerator and an electrode boiler, the heat energy demand end is connected with a waste heat boiler and a heat exchanger, a steam lithium bromide refrigerator is connected between the steam energy demand end and the cold energy demand end, the gas turbine, the gas boiler and the gas internal combustion engine are respectively connected with the waste heat boiler, the heat pump, the electric refrigerator and the, Meet the requirements of various areas in the garden.

Description

Comprehensive energy conversion device

Technical Field

The utility model relates to an energy conversion device, more specifically say, it relates to a comprehensive energy conversion device.

Background

The park-level comprehensive energy system aims to realize the refined matching of energy supply and cold, heat, electricity, gas and traffic demands and the balance of global optimization of local system optimization, and the planning problem is a very complex mixed integer optimization problem with multiple targets, multiple constraints and nonlinearity and random uncertainty, is influenced by multiple factors including geographical conditions, climate characteristics, energy consumption density, energy price, policy environment and the like of a planning area, and has high complexity and uncertainty compared with the traditional single energy planning.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a comprehensive energy conversion device, this comprehensive energy conversion device can carry out the efficient energy conversion, satisfy many-sided demand in garden.

In order to achieve the above purpose, the utility model provides a following technical scheme: an integrated energy conversion device, comprising: the system comprises a natural gas inlet end, a power grid connecting end, a natural gas demand end, a heat energy demand end, an electric energy demand end, a cold energy demand end, a steam energy demand end and a plurality of energy conversion devices for energy conversion;

the natural gas inlet end is directly connected with the natural gas demand end and is used for providing energy supply for the natural gas demand end;

the power grid connecting end is directly connected with the electric energy demand end and is used for providing energy supply for the electric energy demand end;

a gas boiler for converting natural gas into steam energy is connected between the natural gas inlet end and the steam energy demand end, a gas turbine for converting natural gas into electric energy is connected between the natural gas inlet end and the electric energy demand end, and a gas internal combustion engine for converting natural gas into heat energy is connected between the natural gas inlet end and the heat energy demand end;

the electric energy conversion device comprises an electric network connecting end, a heat energy demand end, an electric refrigerator, an electrode boiler and a control system, wherein the electric network connecting end and the heat energy demand end are connected with a heat pump for converting electric energy into heat energy, the electric refrigerator for converting electric energy into cold energy is connected between the electric network connecting end and the cold energy demand end, and the electrode boiler for converting electric energy into steam energy is connected between the electric network connecting end and the steam energy demand;

a waste heat boiler for converting heat energy into steam energy and a heat exchanger for converting the steam energy into heat energy are connected between the heat energy demand end and the steam energy demand end, and a steam lithium bromide refrigerator for converting the steam energy into cold energy is connected between the steam energy demand end and the cold energy demand end;

the gas turbine, the gas boiler and the gas internal combustion engine are respectively connected with the waste heat boiler and are used for conveying exhaust gas generated after applying work to the waste heat boiler to be used as an energy source for heating water by the waste heat boiler;

the heat pump, the electric refrigerator and the electrode boiler are respectively connected with the steam lithium bromide refrigerator and used for taking waste gas generated in the power generation process as an energy source of the steam lithium bromide refrigerator.

The utility model discloses further set up to: the waste heat boiler comprises a main air inlet hole, a first air inlet hole, a second air inlet hole and a third air inlet hole, the first air inlet hole is connected with a gas turbine, the second air inlet hole is connected with the gas boiler, the third air inlet hole is connected with a gas internal combustion engine, and a one-way air guide valve and a first gas monitor are arranged on the first air inlet hole, the second air inlet hole and the third air inlet hole.

The utility model discloses further set up to: the steam lithium bromide refrigerator is provided with a fourth air inlet connected with the heat pump, a fifth air inlet connected with the electric refrigerator and a sixth air inlet connected with the electrode boiler, and the fourth air inlet, the fifth air inlet and the sixth air inlet are internally provided with a one-way air valve and a second gas monitor.

The utility model discloses further set up to: the natural gas demand end is including the gas load equipment that is used for responding to user's demand and the gas holder that is used for gas storage, the heat energy demand end is including the heat load equipment that is used for responding to user's demand, the electric energy demand end is including the electric load equipment that is used for responding to user's demand and the battery that is used for storing up electricity, the cold energy demand end is including the cold load equipment that is used for responding to user's demand and the cold-storage jar that is used for storing up cold, the steam energy demand end is including the steam load equipment that is used for responding to user's demand and the heat-retaining groove that is used for.

The utility model discloses further set up to: the electric wire netting link is including commercial power link and renewable power generation link, renewable power generation link is including photovoltaic power generation, wind power generation, light and heat electricity generation.

The utility model discloses further set up to: the park monitoring device comprises an access module, an application module, a data module and a communication module;

the data module comprises a data storage submodule, a data processing submodule and a data calling submodule, and the data storage submodule is used for acquiring data such as the working frequency and the conversion efficiency of each energy conversion device;

the data processing submodule is connected with the data storage submodule and used for generating a corresponding chart according to the acquired data and storing the chart in the data storage submodule again;

the data calling submodule is connected with the data storage submodule and is used for calling data and diagrams;

the access module comprises an administration committee control terminal and a user login terminal;

the communication module comprises a communication backbone main network and a hardware access sub-network;

the application module is connected with the data module and comprises a power prediction sub-module, an optimization calculation sub-module, a control strategy sub-module and an intelligent scheduling sub-module.

The utility model discloses further set up to: the garden monitoring device is characterized by further comprising an environment monitoring module, wherein the environment monitoring module comprises an anemoscope, a temperature meter and a light intensity meter, and the environment monitoring module is connected with the renewable power generation connecting end and used for controlling the on-off of the renewable power generation connecting end.

The utility model discloses further set up to: the data storage submodule is also used for storing various park types and energy reserve states corresponding to various parks, and the intelligent scheduling submodule is used for carrying out corresponding energy reserve operation according to the park.

To sum up, the utility model discloses following beneficial effect has: through setting up equipment module in the garden, through one set of complete equipment system, when introducing natural gas or electric energy, convert the energy that corresponds into through the customer demand, this equipment can satisfy most gardens and use, and the garden type is including hospital garden, traffic hub garden, industry garden, mill garden, data center garden, hotel garden, regional energy center garden, office building garden, commercial garden, community's house garden. Users with different properties have different energy requirements and characteristics, and the method is used as a comprehensive energy project construction and operation main body, and the selection of a proper target user is a primary task. According to the actual conditions of the park, the receiving users are reasonably selected to realize the cascade utilization of energy sources to the maximum extent through the complementation of energy demand, and the load curve of the park with the peak clipping and valley filling is smooth, so that the user demand is met at the lowest cost, and the full utilization of renewable energy sources is facilitated.

Secondly, in the operation process of the equipment, each energy conversion device can transfer waste materials (energy materials which cannot be successfully converted by the equipment) in the conversion process to other equipment with requirements as basic starting energy, so that the resources are reasonably utilized, and the economic effect is improved.

Drawings

FIG. 1 is a schematic view of a structural topology of an integrated energy conversion device;

figure 2 is a schematic block diagram of a campus monitoring apparatus.

Reference numerals: 1. a natural gas inlet end; 11. a gas boiler; 12. a gas turbine; 13. a gas internal combustion engine; 2. a power grid connection end; 21. a heat pump; 22. an electric refrigerator; 23. an electrode boiler; 24. a waste heat boiler; 25. a heat exchanger; 26. a steam lithium bromide refrigerator; 3. a natural gas demand end; 4. a heat energy demand end; 5. an electric energy demand end; 6. a cold energy demand end; 7. a steam energy demand end; 8. a park monitoring device; 81. an access module; 811. the management committee controls the terminal; 812. a user logs in a terminal; 82. an application module; 821. a power prediction sub-module; 822. an optimization calculation submodule; 823. a control strategy sub-module; 824. an intelligent scheduling submodule; 83. a data module; 831. a data storage submodule; 832. a data processing submodule; 833. a data calling submodule; 84. a communication module; 841. a communication backbone main network; 842. hardware access to a subnet; 9. and an environment monitoring module.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

Referring to fig. 1 and 2, in order to achieve the above object, the present invention provides the following technical solutions: an integrated energy conversion device, comprising: the system comprises a natural gas inlet end 1, a power grid connecting end 2, a natural gas demand end 3, a heat energy demand end 4, an electric energy demand end 5, a cold energy demand end 6, a steam energy demand end 7 and a plurality of energy conversion devices for energy conversion;

the natural gas inlet end 1 is directly connected with the natural gas demand end 3 and is used for providing energy supply for the natural gas demand end 3;

the power grid connecting end 2 is directly connected with the electric energy demand end 5 and is used for providing energy supply for the electric energy demand end 5;

a gas boiler 11 for converting natural gas into steam energy is connected between the natural gas inlet end 1 and the steam energy demand end 7, a gas turbine 12 for converting natural gas into electric energy is connected between the natural gas inlet end 1 and the electric energy demand end 5, and a gas internal combustion engine 13 for converting natural gas into heat energy is connected between the natural gas inlet end 1 and the heat energy demand end 4;

the power grid connecting end 2 and the heat energy demand end 4 are connected with a heat pump 21 for converting electric energy into heat energy, an electric refrigerator 22 for converting electric energy into cold energy is connected between the power grid connecting end 2 and the cold energy demand end 6, and an electrode boiler 23 for converting electric energy into steam energy is connected between the power grid connecting end 2 and the steam energy demand end 7;

a waste heat boiler 24 for converting heat energy into steam energy and a heat exchanger 25 for converting the steam energy into heat energy are connected between the heat energy demand end 4 and the steam energy demand end 7, and a steam lithium bromide refrigerator 26 for converting the steam energy into cold energy is connected between the steam energy demand end 7 and the cold energy demand end 6;

the gas turbine 12, the gas boiler 11 and the gas internal combustion engine 13 are respectively connected with the waste heat boiler 24, and are used for conveying exhaust gas generated after work is done to the waste heat boiler 24 to be used as an energy source for heating water by the waste heat boiler 24;

the heat pump 21, the electric refrigerator 22 and the electrode boiler 23 are respectively connected with a steam lithium bromide refrigerator 26 and used for taking waste gas generated in the power generation process as an energy source of the steam lithium bromide refrigerator 26.

The utility model discloses a design, through setting up equipment module in the garden, through one set of complete equipment system, when introducing natural gas or electric energy, convert corresponding energy into through the customer demand, this equipment can satisfy most gardens and use, and the garden type is including hospital garden, traffic hub garden, industry garden, mill garden, data center garden, hotel garden, regional energy center garden, office building garden, commercial garden, community's residence garden. Users with different properties have different energy requirements and characteristics, and the method is used as a comprehensive energy project construction and operation main body, and the selection of a proper target user is a primary task. According to the actual conditions of the park, the receiving users are reasonably selected to realize the cascade utilization of energy sources to the maximum extent through the complementation of energy demand, and the load curve of the park with the peak clipping and valley filling is smooth, so that the user demand is met at the lowest cost, and the full utilization of renewable energy sources is facilitated.

Secondly, in the operation process of the equipment, each energy conversion device can transfer waste materials (energy materials which cannot be successfully converted by the equipment) in the conversion process to other equipment with requirements as basic starting energy, so that the resources are reasonably utilized, and the economic effect is improved.

The exhaust-heat boiler 24 comprises a main air inlet, a first air inlet, a second air inlet and a third air inlet, wherein the first air inlet is connected with the gas turbine 12, the second air inlet is connected with the gas boiler 11, the third air inlet is connected with the gas internal combustion engine 13, and the first air inlet, the second air inlet and the third air inlet are respectively provided with a one-way air guide valve and a first gas monitor.

The steam lithium bromide refrigerator 26 is provided with a fourth air inlet connected with the heat pump 21, a fifth air inlet connected with the electric refrigerator 22 and a sixth air inlet connected with the electrode boiler 23, and the fourth air inlet, the fifth air inlet and the sixth air inlet are respectively provided with a one-way air valve and a second gas monitor.

This first inlet port and second inlet port and third inlet port, the design of fourth inlet port and fifth inlet port and sixth inlet port guarantees that other equipment admit air in-process can not obstruct each other, guarantees that gaseous can not flow everywhere and scurries, mutual interference, in addition the design has one-way pneumatic valve and one-way air guide valve, can avoid gas refluence to cause other gaseous to go to another equipment in, cause the mist, trigger failure.

The first gas monitor and the second gas monitor are designed to immediately perform alarm operation and close the corresponding gas valves when the waste gas amount is abnormal, and a manager can perform maintenance on the corresponding energy conversion device.

The natural gas demand end 3 comprises gas load equipment for responding to user demands and a gas storage tank for storing gas, the heat energy demand end 4 comprises heat load equipment for responding to the user demands, the electric energy demand end 5 comprises electric load equipment for responding to the user demands and a storage battery for storing electricity, the cold energy demand end 6 comprises cold load equipment for responding to the user demands and a cold storage tank for storing cold, and the steam energy demand end 7 comprises steam load equipment for responding to the user demands and a heat storage tank for storing heat.

Such as 1, gas boiler 11: the natural gas is clean, efficient and convenient to transport, and is an ideal primary energy source for the gas boiler 11. The consumption of natural gas is the main operation cost of such gas-fired boilers 11, and the amount of natural gas required to be consumed to generate a certain amount of thermal power can be calculated by the heating coefficient provided by the manufacturer.

2. Electric boiler (heat pump 21): the electric heating device is a typical electric heating device, can be driven by electric energy, can directly convert the electric energy into heat energy, and is a thermal device for heating water to hot water or steam (saturated steam) with pressure. The electric boiler body mainly comprises an electric furnace steel shell, a computer control system, a low-voltage electric system, an electric heating pipe, a water inlet pipe, a water outlet pipe and a testing instrument, does not need a hearth, a flue and a chimney, does not need a field for storing fuel, and greatly reduces pollution caused by a conventional coal-fired boiler. The electric boiler has the characteristics of no pollution, no noise, small occupied area, convenient installation and use, full automation, safety, reliability, high thermal efficiency of more than 98 percent and the like, and is green and environment-friendly equipment. At present, the electric boiler mainly adopts a resistance type tubular electric boiler. The chemical energy of the fuel is converted into electric energy at high temperature (900-; the medium-temperature waste heat can be directly used for further power conversion through the heat pump 21, and can also be used for a cooling system in an absorption type refrigeration mode; the low-temperature waste heat is used for a heat supply system of each park user.

The power grid connecting end 2 comprises a mains supply connecting end and a renewable power generation connecting end, and the renewable power generation connecting end comprises photovoltaic power generation, wind power generation and photo-thermal power generation.

The park monitoring system further comprises a park monitoring device 8, wherein the park monitoring device 8 comprises an access module 81, an application module 82, a data module 83 and a communication module 84;

the data module 83 includes a data storage sub-module 831, a data processing sub-module 832 and a data calling sub-module 833, and the data storage sub-module 831 is configured to collect data such as operating frequency and conversion efficiency of each energy conversion device;

the data processing submodule 832 is connected with the data storage submodule 831 and is used for generating a corresponding chart according to the acquired data and storing the corresponding chart in the data storage submodule 831 again;

the data calling sub-module 833 is connected with the data storage sub-module 831 and is used for calling data and diagrams;

the access module 81 comprises an administration committee control terminal 811 and a user login terminal 812;

the communication module 84 includes a communication backbone main network 841 and a hardware access subnet 842;

the application module 82 is connected to the data module 83, and includes a power prediction sub-module 821, an optimization calculation sub-module 822, a control strategy sub-module 823, and an intelligent scheduling sub-module 824.

The advanced information communication technology is an important key technology for managing and controlling comprehensive energy resources of a park, wherein the information technology comprises data collection, encoding, decoding, conversion, processing, storage, retrieval and other technologies, and the communication technology mainly refers to information transmission, network alternation, mobile communication, wireless transmission and the like. From the aspect of information technology, the park internet needs intelligent measurement and collects various types of energy and load information in real time; from the perspective of a communication architecture, the campus internet is mainly divided into four parts, namely an administration main station, a backbone main network, an access sub-network and a terminal.

The control objects of the comprehensive energy resources of the park are mainly photovoltaic, fans and combined cooling heating and power systems, and power prediction needs to be carried out on photovoltaic power generation and wind power generation in view of controllability of the combined cooling heating and power systems and instability of new energy output so as to complete purchase of medium and long term trading contract electric quantity and optimization control of day-ahead scheduling curves.

Due to the day and night nature of sunlight, photovoltaic power generation has large intermittence and is influenced by weather and environmental conditions, so that the prediction of photovoltaic power needs to be combined with a large amount of historical data and weather prediction data, and can be divided into medium-long term (1-6 months), short term (1-3 days) and ultra-short term (0-4 hours) power prediction on a time scale. Similar to the photovoltaic power prediction technology, the wind power prediction technology with higher volatility is also a problem to be faced by the control of the comprehensive energy of the park.

The optimization calculation technology mainly refers to how to optimize and calculate a control result according to various data by a park central control system under the condition of giving an optimization operation objective function and an operation boundary. The optimization algorithm used must have fast convergence in view of the need to match the real-time scheduling.

With the continuous shortening of the time scale, the precision of the comprehensive energy power prediction is continuously improved, and the cooling, heating and power load requirements can also change, so that the real-time optimization control needs to be completed on the basis of the day-ahead optimization scheduling control. In addition, when the system meets various temporary working conditions such as lightning stroke, voltage flash, heavy load removal, photovoltaic or fan output fluctuation, black start and the like, the corresponding control strategy can quickly respond to maintain the safe operation of the whole park comprehensive system, and the normal production and life of park users cannot be influenced.

According to the actual conditions of the park, the receiving users are reasonably selected to realize the cascade utilization of energy sources to the maximum extent through the complementation of energy demand, and the load curve of the park with the peak clipping and valley filling is smooth, so that the user demand is met at the lowest cost, and the full utilization of renewable energy sources is facilitated.

The garden monitoring device 8 further comprises an environment monitoring module 9, the environment monitoring module 9 comprises an anemoscope, a temperature instrument and a light intensity instrument, and the environment monitoring module 9 is connected with the renewable power generation connecting end and used for controlling the on-off of the renewable power generation connecting end. The environment monitoring module 9 considers local weather information in real time, and opens and closes the renewable power generation connecting end according to the weather condition, so that the effect of saving energy is ensured.

The data storage submodule 831 further stores various park types and energy reserve states corresponding to the various parks, and the intelligent scheduling submodule 824 is configured to perform corresponding energy reserve operations according to the park in which the intelligent scheduling submodule 824 is located. According to the research, the method comprises the following steps: 1. in hospital parks, the heat load demand is high, the cold load demand is high, and the standby power demand is high; 2. in a factory park, the heat load demand is high, the cold load demand is low, and the standby power demand is medium; 3. in a commercial park, the heat load demand is low, the cold load demand is high, and the standby power demand is low. So different parks correspond to different energy requirements.

Above only the utility model discloses an it is preferred embodiment, the utility model discloses a scope of protection not only limits in above-mentioned embodiment, and the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (8)

1. A comprehensive energy conversion device is characterized by comprising: the system comprises a natural gas inlet end (1), a power grid connecting end (2), a natural gas demand end (3), a heat energy demand end (4), an electric energy demand end (5), a cold energy demand end (6), a steam energy demand end (7) and a plurality of energy conversion devices for energy conversion;

the natural gas inlet end (1) is directly connected with the natural gas demand end (3) and is used for providing energy supply for the natural gas demand end (3);

the power grid connection end (2) is directly connected with the electric energy demand end (5) and is used for providing energy supply for the electric energy demand end (5);

a gas boiler (11) for converting natural gas into steam energy is connected between the natural gas inlet end (1) and the steam energy demand end (7), a gas turbine (12) for converting natural gas into electric energy is connected between the natural gas inlet end (1) and the electric energy demand end (5), and a gas internal combustion engine (13) for converting natural gas into heat energy is connected between the natural gas inlet end (1) and the heat energy demand end (4);

the power grid connection end (2) and the heat energy demand end (4) are connected with a heat pump (21) for converting electric energy into heat energy, an electric refrigerator (22) for converting electric energy into cold energy is connected between the power grid connection end (2) and the cold energy demand end (6), and an electrode boiler (23) for converting electric energy into steam energy is connected between the power grid connection end (2) and the steam energy demand end (7);

a waste heat boiler (24) for converting heat energy into steam energy and a heat exchanger (25) for converting the steam energy into heat energy are connected between the heat energy demand end (4) and the steam energy demand end (7), and a steam lithium bromide refrigerator (26) for converting the steam energy into cold energy is connected between the steam energy demand end (7) and the cold energy demand end (6);

the gas turbine (12), the gas boiler (11) and the gas internal combustion engine (13) are respectively connected with the waste heat boiler (24) and used for conveying exhaust gas generated after work is done to the waste heat boiler (24) to be used as an energy source for heating water by the waste heat boiler (24);

the heat pump (21), the electric refrigerator (22) and the electrode boiler (23) are respectively connected with the steam lithium bromide refrigerator (26) and used for taking waste gas generated in the power generation process as an energy source of the steam lithium bromide refrigerator (26).

2. The integrated energy conversion device of claim 1, wherein: the waste heat boiler (24) comprises a main air inlet hole, a first air inlet hole, a second air inlet hole and a third air inlet hole, the first air inlet hole is connected with a gas turbine (12), the second air inlet hole is connected with a gas boiler (11), the third air inlet hole is connected with a gas internal combustion engine (13), and a one-way air guide valve and a first gas monitor are arranged on the first air inlet hole, the second air inlet hole and the third air inlet hole.

3. The integrated energy conversion device of claim 1, wherein: the steam lithium bromide refrigerator (26) is provided with a fourth air inlet connected with the heat pump (21), a fifth air inlet connected with the electric refrigerator (22) and a sixth air inlet connected with the electrode boiler (23), and the fourth air inlet, the fifth air inlet and the sixth air inlet are respectively provided with a one-way air valve and a second gas monitor.

4. The integrated energy conversion device of claim 3, wherein: the natural gas demand end (3) is including the gas load equipment that is used for responding to user's demand and the gas holder that is used for gas storage, heat energy demand end (4) is including the heat load equipment that is used for responding to user's demand, electric energy demand end (5) is including the electric load equipment that is used for responding to user's demand and the battery that is used for the accumulate, cold energy demand end (6) is including the cold load equipment that is used for responding to user's demand and the cold-storage jar that is used for storing up the cold, steam energy demand end (7) is including the steam load equipment that is used for responding to user's demand and the heat-storage tank that is used for the heat-storage.

5. The integrated energy conversion device of claim 1, wherein: the power grid connecting end (2) comprises a mains supply connecting end and a renewable power generation connecting end, and the renewable power generation connecting end comprises photovoltaic power generation, wind power generation and photo-thermal power generation.

6. The integrated energy conversion device of claim 1, wherein: the system is characterized by also comprising a park monitoring device (8), wherein the park monitoring device (8) comprises an access module (81), an application module (82), a data module (83) and a communication module (84);

the data module (83) comprises a data storage submodule (831), a data processing submodule (832) and a data calling submodule (833), and the data storage submodule (831) is used for collecting data such as working frequency and conversion efficiency of each energy conversion device;

the data processing submodule (832) is connected with the data storage submodule (831) and is used for generating a corresponding chart according to the collected data and storing the corresponding chart in the data storage submodule (831) again;

the data calling submodule (833) is connected with the data storage submodule (831) and is used for calling data and diagrams;

the access module (81) comprises an administration committee control terminal (811) and a user login terminal (812);

the communication module (84) comprises a communication backbone main network (841) and a hardware access subnet (842);

the application module (82) is connected with the data module (83) and comprises a power prediction sub-module (821), an optimization calculation sub-module (822), a control strategy sub-module (823) and an intelligent scheduling sub-module (824).

7. The integrated energy conversion device of claim 6, wherein: park monitoring device (8) are still including environment monitoring module (9), environment monitoring module (9) are including anemoscope, thermometer, light intensity appearance, environment monitoring module (9) are connected with the power generation link of can regenerating for the opening and close of control power generation link of regenerating.

8. The integrated energy conversion device of claim 6, wherein: the data storage submodule (831) also stores various park types and energy reserve states corresponding to the various parks, and the intelligent scheduling submodule (824) is used for performing corresponding energy reserve operation according to the park.

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