CN214751387U - Energy manager of comprehensive energy system of cooling, heating and power park - Google Patents

Abstract

The embodiment of the utility model discloses cooling thermal power garden synthesizes energy management ware, include: the system comprises a scheduling control module, an operating equipment control module and an operating load measuring module; the scheduling control module is respectively in communication connection with the operation equipment control module and the operation load measuring module; the scheduling control module is used for receiving external information, generating an external scheduling control instruction based on the external information, and sending a device control instruction to the running device control module based on the external scheduling control instruction; the operation equipment control module is used for responding to the equipment control instruction, controlling the operation of the preset energy supply equipment, acquiring the equipment operation information of the preset energy supply equipment and returning the equipment operation information to the scheduling control module; the operation load measuring module is used for acquiring load operation information and sending the load operation information to the scheduling control module. Through the utility model discloses, the operation of multipotency dispatch of garden comprehensive energy system has been realized.

Description

Energy manager of comprehensive energy system of cooling, heating and power park

Technical Field

The utility model relates to an energy management ware field especially relates to a cold and hot electric park energy system energy management ware of synthesizing.

Background

The comprehensive energy system is an energy system form which realizes complementary utilization and coordinated optimization of various energy sources such as electricity, gas, heat, cold and the like in each link of energy production, transmission, storage, consumption and the like by utilizing advanced technology and management mode in a certain area. In recent years, new energy electric power represented by wind energy and solar energy can be accessed in various forms and is developed and utilized on a large scale, and new renewable energy sources such as geothermal energy and the like can fully utilize shallow geothermal energy which is usually less than 100 meters deep to supply energy, so that the novel energy electric power is popularized vigorously. The integration and optimization of power networks and heat networks including wind energy, solar energy and geothermal energy are necessary ways for realizing the sustainable development of energy.

The park comprehensive energy system is formed by coupling energy networks of a 10kV or lower medium-low voltage intelligent power distribution system, a medium-low voltage natural gas system, a heat supply/cold/water system and the like, is connected with a regional comprehensive energy system and a user energy supply system, and is an important realization way of energy revolution at the consumption side. Meanwhile, the energy transmission, energy conversion and energy storage technologies in the park comprehensive energy system are applied in a large quantity, so that the system is highly coupled among multiple energy forms and multiple energy links.

However, the coupling characteristics and the operation efficiency of various energy sources in the system are different, and the multi-energy scheduling operation is difficult to realize.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model discloses cooling thermal power garden comprehensive energy system energy management ware for solve the technical problem that garden comprehensive energy system is difficult to realize the operation of multipotency dispatch.

The embodiment of the utility model provides a cold and hot electric park comprehensive energy system energy management ware, include: the system comprises a scheduling control module, an operating equipment control module and an operating load measuring module;

the scheduling control module is respectively in communication connection with the operating equipment control module and the operating load measuring module;

the scheduling control module is used for receiving external information, generating an external scheduling control instruction based on the external information, and sending a device control instruction to the running device control module based on the external scheduling control instruction;

the operation equipment control module is used for responding to the equipment control instruction, controlling the operation of preset energy supply equipment, acquiring equipment operation information of the preset energy supply equipment and returning the equipment operation information to the scheduling control module;

the operation load measuring module is used for acquiring the load operation information and sending the load operation information to the scheduling control module; wherein the load operation information includes electrical load operation information, cold load operation information, and heat load operation information.

Alternatively,

the scheduling control module comprises an external information input unit, a load prediction unit, a regulation and control unit, an equipment operation database and a historical operation information database;

the output end of the external information input unit is respectively connected with the input end of the load prediction unit and the input end of the regulation and control unit;

the input end of the load prediction unit is connected with the output end of the historical operation information database; the output end of the load prediction unit is connected with the input end of the regulation and control unit;

the input end of the regulating and controlling unit is connected with the output end of the equipment operation database; the output end of the regulating and controlling unit is connected with the input end of the operating equipment control module;

the input end of the equipment operation database is connected with the output end of the operation equipment control module;

and the input end of the historical operation information database is connected with the output end of the operation load measuring module.

Alternatively,

the running equipment control module comprises an equipment control unit and an equipment measuring unit which are sequentially connected;

the input end of the equipment control unit is connected with the output end of the regulation and control unit; the output end of the equipment control unit is connected with the input end of the equipment measuring unit;

and the output end of the equipment measuring unit is connected with the input end of the equipment operation database.

Alternatively,

the operation load measuring module comprises a load adjusting unit and a load measuring unit which are sequentially connected;

the output end of the load adjusting unit is connected with the input end of the load measuring unit;

and the output end of the load measuring unit is connected with the input end of the historical operation information database.

Alternatively,

the external information input unit is used for receiving external information, generating an external scheduling control instruction based on the external information and sending the external scheduling control instruction to the regulation and control unit;

the load prediction unit is used for acquiring historical load data, performing load prediction based on the external information and the historical load data to generate a load prediction value, and sending the load prediction value to the regulation and control unit;

and the regulation and control unit is used for generating an equipment control instruction according to the load predicted value, the external scheduling control instruction and the equipment state information sent by the equipment operation database, and sending the equipment control instruction to the equipment control unit.

Alternatively,

the equipment control unit is used for responding to the equipment control instruction and controlling the preset energy supply equipment to operate;

and the equipment measuring unit is used for acquiring the equipment operation information of the preset energy supply equipment and sending the equipment operation information to the equipment operation database.

Alternatively,

the load adjusting unit is used for adjusting load requirements, generating actual operation load and sending the actual operation load to the load measuring unit;

and the load measuring unit is used for generating load operation information by adopting the actual operation load and sending the load operation information to the historical operation information database.

Optionally, the external information includes environmental information and temperature information.

Optionally, the device control instruction carries a device contribution plan.

Optionally, the preset energy supply device comprises an electric energy supply device, a hot energy supply device and a cold energy supply device.

According to the technical solution provided by the utility model, the embodiment of the utility model has the following advantage:

the embodiment of the utility model provides a cold and hot electric park comprehensive energy system energy management ware, include: the system comprises a scheduling control module, an operating equipment control module and an operating load measuring module; the scheduling control module is respectively in communication connection with the operation equipment control module and the operation load measuring module; the scheduling control module is used for receiving external information, generating an external scheduling control instruction based on the external information, and sending a device control instruction to the running device control module based on the external scheduling control instruction; the operation equipment control module is used for responding to the equipment control instruction, controlling the operation of the preset energy supply equipment, acquiring the equipment operation information of the preset energy supply equipment and returning the equipment operation information to the scheduling control module; the operation load measuring module is used for acquiring load operation information and sending the load operation information to the scheduling control module; the load operation information comprises electric load operation information, cold load operation information and heat load operation information. Through the embodiment of the utility model provides a, the multipotency dispatch operation of garden comprehensive energy system has been realized.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of an energy device of an integrated energy system for a cooling, heating and power park according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an energy device of an integrated energy system for a cooling, heating and power park according to another embodiment of the present invention.

Detailed Description

The embodiment of the utility model discloses cooling thermal power garden comprehensive energy system energy management ware for solve the technical problem that garden comprehensive energy system is difficult to realize the operation of multipotency dispatch.

Referring to fig. 1, an embodiment of an energy manager for an integrated energy system of a cooling, heating and power park provided in an embodiment of the present invention includes:

a scheduling control module 11, an operation equipment control module 12 and an operation load measuring module 13;

the scheduling control module 11 is respectively in communication connection with the operating equipment control module 12 and the operating load measuring module 13;

the scheduling control module 11 is configured to receive external information, generate an external scheduling control instruction based on the external information, and send an apparatus control instruction to the operating apparatus control module 12 based on the external scheduling control instruction;

the operation device control module 12 is configured to respond to a device control instruction, control the operation of the preset energy supply device, acquire device operation information of the preset energy supply device, and return the device operation information to the scheduling control module 11;

the operation load measuring module 13 is configured to obtain load operation information and send the load operation information to the scheduling control module 11; the load operation information comprises electric load operation information, cold load operation information and heat load operation information.

The utility model discloses a dispatch control module 11 receives external information, generates the outside dispatch control command to energy supply equipment according to external information to make operation equipment control module 12 can respond outside dispatch control command and realize the dispatch and the control to energy supply equipment. Meanwhile, the operation load of the energy supply device is measured by the operation load measuring module 13 to obtain load operation information, and the load operation information is fed back to the scheduling control module 11, so that the load is dynamically adjusted by the scheduling control module 11, wherein the load operation information includes, but is not limited to, electric load operation information, heat load operation information and cold load operation information. The multifunctional scheduling operation of the park comprehensive energy system is realized by scheduling and controlling the operation of various energy loads.

Referring to fig. 2, fig. 2 is a schematic structural diagram of an energy device of a comprehensive energy system for a cooling, heating and power park according to another embodiment of the present invention.

As shown in fig. 2, the scheduling control module 11 includes an external information input unit 111, a load prediction unit 112, a regulation unit 113, an apparatus operation database 114, and a history operation information database 115;

the output end of the external information input unit 111 is respectively connected with the input end of the load prediction unit 112 and the input end of the regulation and control unit 113;

the input end of the load prediction unit 112 is connected with the output end of the historical operation information database 115; the output end of the load prediction unit 112 is connected with the input end of the regulation unit 113;

the input end of the regulation unit 113 is connected with the output end of the equipment operation database 114; the output end of the regulation and control unit 113 is connected with the input end of the operation equipment control module 12;

the input end of the equipment operation database 114 is connected with the output end of the operation equipment control module 12;

the input end of the historical operation information database 115 is connected with the output end of the operation load measuring module 13.

The external information input unit 111 is configured to receive external information, generate an external scheduling control instruction based on the external information, and send the external scheduling control instruction to the control unit 113;

the load prediction unit 112 is configured to obtain historical load data, perform load prediction based on external information and the historical load data, generate a load prediction value, and send the load prediction value to the regulation unit 113;

the regulation and control unit 113 is configured to generate an equipment control instruction according to the load predicted value, the external scheduling control instruction, and the equipment state information sent by the equipment operation database 114, and send the equipment control instruction to the equipment control unit 121.

Further, the operating equipment control module 12 includes an equipment control unit 121 and an equipment measurement unit 122 connected in sequence;

the input end of the device control unit 121 is connected with the output end of the regulation unit 113; the output end of the device control unit 121 is connected to the input end of the device measurement unit 122;

an output of the equipment measurement unit 122 is connected to an input of the equipment operation database 114.

The device control unit 121 is configured to respond to a device control instruction and control the operation of preset energy supply devices;

the device measurement unit 122 is configured to obtain device operation information of a preset energy supply device, and send the device operation information to the device operation database 114.

Further, the operation load measuring module 13 includes a load adjusting unit 131 and a load measuring unit 132 connected in sequence;

the output end of the load adjusting unit 131 is connected with the input end of the load measuring unit 132;

the output of the load measuring unit 132 is connected to the input of the historical operating information database 115.

The load adjusting unit 131 is configured to adjust a load demand, generate an actual operating load, and send the actual operating load to the load measuring unit 132;

and the load measuring unit 132 is configured to generate load operation information by using the actual operation load, and send the load operation information to the historical operation information database 115.

Further, the external information includes environmental information and temperature information.

Further, the equipment control command carries an equipment contribution plan.

Further, the preset energy supply device comprises an electric energy supply device, a hot energy supply device and a cold energy supply device.

The utility model discloses a dispatch control module 11 receives external information, generates the outside dispatch control command to energy supply equipment according to external information to make operation equipment control module 12 can respond outside dispatch control command and realize the dispatch and the control to energy supply equipment. Meanwhile, the operation load of the energy supply device is measured by the operation load measuring module 13 to obtain load operation information, and the load operation information is fed back to the scheduling control module 11, so that the load is dynamically adjusted by the scheduling control module 11, wherein the load operation information includes, but is not limited to, electric load operation information, heat load operation information and cold load operation information. The multifunctional scheduling operation of the park comprehensive energy system is realized by scheduling and controlling the operation of various energy loads.

It is right above the utility model provides a cooling, heating and power garden comprehensive energy resource system energy management ware has carried out detailed introduction, to the general technical personnel in this field, according to the utility model discloses the thought, all has the change part on concrete implementation and range of application, to sum up, this description content should not be understood as the restriction of the utility model discloses.

Claims (10)

1. The utility model provides a cold thermal power garden synthesizes energy system energy management ware which characterized in that includes: the system comprises a scheduling control module, an operating equipment control module and an operating load measuring module;

the scheduling control module is respectively in communication connection with the operating equipment control module and the operating load measuring module;

the scheduling control module is used for receiving external information, generating an external scheduling control instruction based on the external information, and sending a device control instruction to the running device control module based on the external scheduling control instruction;

the operation equipment control module is used for responding to the equipment control instruction, controlling the operation of preset energy supply equipment, acquiring equipment operation information of the preset energy supply equipment and returning the equipment operation information to the scheduling control module;

the operation load measuring module is used for acquiring load operation information and sending the load operation information to the scheduling control module; wherein the load operation information includes electrical load operation information, cold load operation information, and heat load operation information.

2. The energy manager of the combined cooling, heating and power park energy system of claim 1,

the scheduling control module comprises an external information input unit, a load prediction unit, a regulation and control unit, an equipment operation database and a historical operation information database;

the output end of the external information input unit is respectively connected with the input end of the load prediction unit and the input end of the regulation and control unit;

the input end of the load prediction unit is connected with the output end of the historical operation information database; the output end of the load prediction unit is connected with the input end of the regulation and control unit;

the input end of the regulating and controlling unit is connected with the output end of the equipment operation database; the output end of the regulating and controlling unit is connected with the input end of the operating equipment control module;

the input end of the equipment operation database is connected with the output end of the operation equipment control module;

and the input end of the historical operation information database is connected with the output end of the operation load measuring module.

3. The energy manager of the combined cooling, heating and power park energy system of claim 2,

the running equipment control module comprises an equipment control unit and an equipment measuring unit which are sequentially connected;

the input end of the equipment control unit is connected with the output end of the regulation and control unit; the output end of the equipment control unit is connected with the input end of the equipment measuring unit;

and the output end of the equipment measuring unit is connected with the input end of the equipment operation database.

4. The energy manager of the combined cooling, heating and power system according to claim 3,

the operation load measuring module comprises a load adjusting unit and a load measuring unit which are sequentially connected;

the output end of the load adjusting unit is connected with the input end of the load measuring unit;

and the output end of the load measuring unit is connected with the input end of the historical operation information database.

5. The energy manager of the combined cooling, heating and power system according to claim 4,

the external information input unit is used for receiving external information, generating an external scheduling control instruction based on the external information and sending the external scheduling control instruction to the regulation and control unit;

the load prediction unit is used for acquiring historical load data, performing load prediction based on the external information and the historical load data to generate a load prediction value, and sending the load prediction value to the regulation and control unit;

and the regulation and control unit is used for generating an equipment control instruction according to the load predicted value, the external scheduling control instruction and the equipment state information sent by the equipment operation database, and sending the equipment control instruction to the equipment control unit.

6. The energy manager of the combined cooling, heating and power system according to claim 5,

the equipment control unit is used for responding to the equipment control instruction and controlling the preset energy supply equipment to operate;

and the equipment measuring unit is used for acquiring the equipment operation information of the preset energy supply equipment and sending the equipment operation information to the equipment operation database.

7. The energy manager of the combined cooling, heating and power system according to claim 6,

the load adjusting unit is used for adjusting load requirements, generating actual operation load and sending the actual operation load to the load measuring unit;

and the load measuring unit is used for generating load operation information by adopting the actual operation load and sending the load operation information to the historical operation information database.

8. The combined cooling, heating and power campus energy management system of claim 5 wherein said external information includes environmental information and temperature information.

9. The energy manager of the combined cooling, heating and power system according to claim 5, wherein the equipment control command carries an equipment output plan.

10. The combined cooling, heating and power energy management system of claim 7, wherein the predetermined energy supply devices comprise an electric energy supply device, a hot energy supply device and a cold energy supply device.

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