阅读说明：本技术 一种基于gis的多能协同展示方法和装置 (GIS-based multi-energy collaborative display method and device ) 是由 谢瀚阳 彭泽武 温柏坚 裴求根 江疆 梁盈威 苏华权 于 2021-08-03 设计创作，主要内容包括：本发明公开了一种基于GIS的多能协同展示方法和装置,包括：获取能源类的各类别及各类别建模所需的信息；根据各类别建模所需的信息,结合各类别的预设建模规则,建立各类别对应的站内外模型；依次对各类别对应的站内外模型进行建模规则校验处理,将校验通过的模型存储至模型数据库；响应CS客户端或通过WebGIS－API数据接口响应外部系统触发的协同操作,调用校验通过的模型并执行相应的协同功能,实现各能源类数据协同处理,简化处理方式,降低数据融合成本。(The invention discloses a GIS (geographic information system) -based multi-energy collaborative display method and a device, comprising the following steps: acquiring various types of energy types and information required by modeling of the various types; establishing station internal and external models corresponding to each category by combining preset modeling rules of each category according to information required by modeling of each category; carrying out modeling rule checking treatment on the in-station models and the out-station models corresponding to all categories in sequence, and storing the models passing the checking treatment to a model database; and responding to the CS client or responding to the cooperative operation triggered by the external system through the WebGIS-API data interface, calling the verified model and executing the corresponding cooperative function, realizing the cooperative processing of various energy data, simplifying the processing mode and reducing the data fusion cost.)

1. A GIS-based multi-energy collaborative display method is characterized by comprising the following steps:

acquiring various types of energy types and information required by modeling of the various types; wherein each category of the energy class comprises one or more of the following combinations: comprehensive, gas, cooling and heating, metering and electric power;

establishing station internal and external models corresponding to each category by combining preset modeling rules of each category according to information required by modeling of each category; the device information management method comprises the steps that a plurality of devices and device information corresponding to each device are arranged in each model;

responding to a first cooperative operation triggered by a CS client, calling a model stored in the model database according to the first cooperative operation, generating corresponding feedback information, and sending the feedback information to the CS client so that the CS client executes a corresponding first cooperative function according to the feedback information; wherein the first coordination function comprises: a device query function, a topology analysis function, or a graph-model verification function.

2. The GIS-based multi-energy collaborative display method according to claim 1, wherein the station internal and external models corresponding to each category are established according to information required for modeling of each category and in combination with preset modeling rules of each category, specifically:

acquiring icons corresponding to the types of models to be built, and modeling lines, pipelines and equipment in combination with preset off-station modeling rules corresponding to the types of the models to be built to acquire off-station equipment models of the types of the models to be built;

acquiring icons corresponding to the types of the to-be-modeled, and modeling the internal connection lines of the plant station equipment by combining with preset in-station modeling rules corresponding to the types of the to-be-modeled to acquire in-station equipment models of the types of the to-be-modeled;

and linking each device in the in-station device model and the out-station device model through the in-station and out-station linking points to obtain the in-station and out-station models corresponding to the to-be-modeled categories.

3. The GIS-based multifunctional cooperative display method according to any one of claims 1 and 2, wherein after the in-station and out-station models corresponding to each category are established according to the information required for modeling of each category and by combining preset modeling rules of each category, the method further comprises:

checking various types of in-station and out-station models in sequence by combining the modeling rules of various types of equipment data in the rule base, and storing the models passing the checking into the model database;

and if the verification fails, modifying the in-station model and the out-station model according to a model modification instruction input by a user until the modified model passes the verification of the modeling rule.

4. The method according to claim 1, wherein the calling the model stored in the model database according to the first cooperative operation generates corresponding feedback information, and the sending the feedback information to the CS client, so that the CS client executes a corresponding first cooperative function according to the feedback information, specifically:

when the first cooperative function is an equipment query function, calling a model passing the verification in the model database, querying the position and the equipment information of the first equipment, and feeding back the position and the equipment information to the CS client, so that the CS client displays the position and the equipment information of the first equipment to a user to realize equipment query and positioning;

when the first cooperative function is a topology analysis function, calling a model passing the verification in the model database, inquiring the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment, and feeding back the inquiry to the CS client so that the CS client displays the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment to a user to realize equipment topology analysis;

and when the first cooperative function is a graph mode checking function, calling a passed model in the model database, checking the semantics, integrity, topological connectivity and graph mode consistency of the called model, and feeding back a checking result to the CS client, so that the CS client displays the checking result to a user to realize the graph mode checking of the equipment.

5. The GIS-based multifunctional collaborative display method according to claim 1, wherein after the modeling rule verification processing is sequentially performed on the intra-and-post models corresponding to each category, and the models passing the verification are stored in a model database, the method further comprises:

responding to a second cooperative operation triggered by an external system through a WebGIS-API data interface, calling model data stored in the model database according to the second cooperative operation, and sending the called model data to the external system so as to enable the external system to display or apply the called model data.

6. A GIS-based multi-energy collaborative display device is characterized by comprising: the system comprises an acquisition module, a modeling module, a verification module and a calling module;

the acquisition module is used for acquiring various types of energy types and information required by various types of modeling; wherein each category of the energy class comprises one or more of the following combinations: comprehensive, gas, cooling and heating, metering and electric power;

the modeling module is used for establishing an in-station model and an out-station model corresponding to each category according to information required by modeling of each category and by combining preset modeling rules of each category; the device information management method comprises the steps that a plurality of devices and device information corresponding to each device are arranged in each model;

the calling module is used for responding to a first cooperative operation triggered by a CS client, calling the model stored in the model database according to the first cooperative operation, generating corresponding feedback information, and sending the feedback information to the CS client so that the CS client executes a corresponding first cooperative function according to the feedback information; wherein the first coordination function comprises: a device query function, a topology analysis function, or a graph-model verification function.

7. The GIS-based multifunctional cooperative display device according to claim 6, wherein the modeling module is configured to establish the in-station and out-station models corresponding to each category according to information required for modeling of each category and by combining preset modeling rules of each category, specifically:

acquiring icons corresponding to the types of models to be built, and modeling lines, pipelines and equipment in combination with preset off-station modeling rules corresponding to the types of the models to be built to acquire off-station equipment models of the types of the models to be built;

acquiring icons corresponding to the types of the to-be-modeled, and modeling the internal connection lines of the plant station equipment by combining with preset in-station modeling rules corresponding to the types of the to-be-modeled to acquire in-station equipment models of the types of the to-be-modeled;

and linking each device in the in-station device model and the out-station device model through the in-station and out-station linking points to obtain the in-station and out-station models corresponding to the to-be-modeled categories.

8. The GIS-based multifunctional cooperative display device according to any one of claims 6 and 7, wherein after the modeling module is configured to establish the intra-and-out models corresponding to each category according to the information required for modeling of each category and by combining the preset modeling rules of each category, the GIS-based multifunctional cooperative display device further comprises:

sequentially verifying the various types of the in-station and out-station models by combining the modeling rules of the various types of equipment data in the rule base, and storing the verified models into the model database;

and if the verification fails, modifying the in-station model and the out-station model according to a model modification instruction input by a user until the modified model passes the verification of the modeling rule.

9. The GIS-based multi-energy collaborative presentation device of claim 6, wherein the invoking module is configured to respond to a first collaborative operation triggered by a CS client, invoke a model stored in the model database according to the first collaborative operation, generate corresponding feedback information, and send the feedback information to the CS client, so that the CS client executes a corresponding first collaborative function according to the feedback information, specifically:

when the first cooperative function is an equipment query function, calling a model passing the verification in the model database, querying the position and the equipment information of the first equipment, and feeding back the position and the equipment information to the CS client, so that the CS client displays the position and the equipment information of the first equipment to a user to realize equipment query and positioning;

when the first cooperative function is a topology analysis function, calling a model passing the verification in the model database, inquiring the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment, and feeding back the inquiry to the CS client so that the CS client displays the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment to a user to realize equipment topology analysis;

and when the first cooperative function is a graph mode checking function, calling a passed model in the model database, checking the semantics, integrity, topological connectivity and graph mode consistency of the called model, and feeding back a checking result to the CS client, so that the CS client displays the checking result to a user to realize the graph mode checking of the equipment.

10. The GIS based multi-energy collaborative presentation device of claim 6, wherein the calling module is further configured to respond to a second collaborative operation triggered by an external system through a WebGIS-API data interface, and according to the second collaborative operation, call the model data stored in the model database, and send the called model data to the external system, so that the external system presents or applies the called model data.

Technical Field

The invention relates to the field of comprehensive energy equipment, in particular to a GIS-based multi-energy collaborative display method and device.

Background

With the increasing demand of human energy and the rapid development of society, the efficient utilization of integrated energy devices becomes more and more important. The comprehensive energy equipment system enables related technicians to clearly know the operation condition of the system through modeling and displaying different types of energy, and the state of the system is tracked in real time.

The existing power grid equipment data and other energy source data (comprehensive type, gas type, cooling and heating type and metering type) are independent and separated, and are specifically stored in different database tables and have no topological relation. Therefore, the whole is difficult to form comprehensive energy complete data, and the whole analysis and the multi-energy cooperation cannot be carried out on the comprehensive energy complete data. Making the system inefficient and resource intensive.

Disclosure of Invention

The embodiment of the invention provides a GIS-based multi-energy collaborative display method and device, and aims to solve the technical problems that various energy data can be fused and collaborated after modeling, the implementation mode is complex, and the cost is high.

In order to solve the technical problem, an embodiment of the present invention provides a GIS-based multi-energy collaborative display method, including:

acquiring various types of energy types and information required by modeling of the various types; wherein each category of the energy class comprises one or more of the following combinations: comprehensive, gas, cooling and heating, metering and electric power;

establishing station internal and external models corresponding to each category by combining preset modeling rules of each category according to information required by modeling of each category; the device information management method comprises the steps that a plurality of devices and device information corresponding to each device are arranged in each model;

responding to a first cooperative operation triggered by a CS client, calling a model stored in the model database according to the first cooperative operation, generating corresponding feedback information, and sending the feedback information to the CS client so that the CS client executes a corresponding first cooperative function according to the feedback information; wherein the first coordination function comprises: a device query function, a topology analysis function, or a graph-model verification function.

Further, the building of the station internal and external models corresponding to each category according to the information required for modeling of each category and by combining the preset modeling rules of each category specifically includes:

acquiring icons corresponding to the types of models to be built, and modeling lines, pipelines and equipment in combination with preset off-station modeling rules corresponding to the types of the models to be built to acquire off-station equipment models of the types of the models to be built;

acquiring icons corresponding to the types of the to-be-modeled, and modeling the internal connection lines of the plant station equipment by combining with preset in-station modeling rules corresponding to the types of the to-be-modeled to acquire in-station equipment models of the types of the to-be-modeled;

and linking each device in the in-station device model and the out-station device model through the in-station and out-station linking points to obtain the in-station and out-station models corresponding to the to-be-modeled categories.

Further, after the establishing the intra-station and intra-station models corresponding to each category according to the information required for modeling of each category and by combining the preset modeling rules of each category, the method further includes:

checking various types of in-station and out-station models in sequence by combining the modeling rules of various types of equipment data in the rule base, and storing the models passing the checking into the model database;

and if the verification fails, modifying the in-station model and the out-station model according to a model modification instruction input by a user until the modified model passes the verification of the modeling rule.

Further, the invoking a model stored in the model database according to the first cooperative operation generates corresponding feedback information, and sending the feedback information to the CS client, so that the CS client executes a corresponding first cooperative function according to the feedback information, specifically:

when the first cooperative function is an equipment query function, calling a model passing the verification in the model database, querying the position and the equipment information of the first equipment, and feeding back the position and the equipment information to the CS client, so that the CS client displays the position and the equipment information of the first equipment to a user to realize equipment query and positioning;

when the first cooperative function is a topology analysis function, calling a model passing the verification in the model database, inquiring the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment, and feeding back the inquiry to the CS client so that the CS client displays the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment to a user to realize equipment topology analysis;

and when the first cooperative function is a graph mode checking function, calling a passed model in the model database, checking the semantics, integrity, topological connectivity and graph mode consistency of the called model, and feeding back a checking result to the CS client, so that the CS client displays the checking result to a user to realize the graph mode checking of the equipment.

Further, after the modeling rule checking processing is performed on the intra-station and intra-station models corresponding to each category in sequence and the models passing the checking are stored in the model database, the method further includes:

responding to a second cooperative operation triggered by an external system through a WebGIS-API data interface, calling model data stored in the model database according to the second cooperative operation, and sending the called model data to the external system so as to enable the external system to display or apply the called model data.

Correspondingly, the embodiment of the invention also provides a GIS-based multifunctional collaborative display device, which comprises: the system comprises an acquisition module, a modeling module and a calling module;

the acquisition module is used for acquiring various types of energy types and information required by various types of modeling; wherein each category of the energy class comprises one or more of the following combinations: comprehensive, gas, cooling and heating, metering and electric power;

the modeling module is used for establishing an in-station model and an out-station model corresponding to each category according to information required by modeling of each category and by combining preset modeling rules of each category; the device information management method comprises the steps that a plurality of devices and device information corresponding to each device are arranged in each model;

the calling module is used for responding to a first cooperative operation triggered by a CS client, calling the model stored in the model database according to the first cooperative operation, generating corresponding feedback information, and sending the feedback information to the CS client so that the CS client executes a corresponding first cooperative function according to the feedback information; wherein the first coordination function comprises: a device query function, a topology analysis function, or a graph-model verification function.

Further, the modeling module is configured to establish an intra-station model and an extra-station model corresponding to each category according to information required for modeling of each category and by combining preset modeling rules of each category, and specifically includes:

acquiring icons corresponding to the types of models to be built, and modeling lines, pipelines and equipment in combination with preset off-station modeling rules corresponding to the types of the models to be built to acquire off-station equipment models of the types of the models to be built;

acquiring icons corresponding to the types of the to-be-modeled, and modeling the internal connection lines of the plant station equipment by combining with preset in-station modeling rules corresponding to the types of the to-be-modeled to acquire in-station equipment models of the types of the to-be-modeled;

and linking each device in the in-station device model and the out-station device model through the in-station and out-station linking points to obtain the in-station and out-station models corresponding to the to-be-modeled categories.

Further, after the modeling module is configured to establish the intra-and-out-of-station models corresponding to each category according to information required for modeling of each category and by combining preset modeling rules of each category, the method further includes:

sequentially verifying the various types of the in-station and out-station models by combining the modeling rules of the various types of equipment data in the rule base, and storing the verified models into the model database;

and if the verification fails, modifying the in-station model and the out-station model according to a model modification instruction input by a user until the modified model passes the verification of the modeling rule.

Further, the invoking module is configured to respond to a first cooperative operation triggered by a CS client, invoke a model stored in the model database according to the first cooperative operation, generate corresponding feedback information, and send the feedback information to the CS client, so that the CS client executes a corresponding first cooperative function according to the feedback information, specifically:

when the first cooperative function is an equipment query function, calling a model passing the verification in the model database, querying the position and the equipment information of the first equipment, and feeding back the position and the equipment information to the CS client, so that the CS client displays the position and the equipment information of the first equipment to a user to realize equipment query and positioning;

when the first cooperative operation is a topology analysis function, calling a model passing the verification in the model database, inquiring the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment, and feeding back the inquiry to the CS client so that the CS client displays the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment to a user to realize equipment topology analysis;

and when the first cooperative function is a graph mode checking function, calling a passed model in the model database, checking the semantics, integrity, topological connectivity and graph mode consistency of the called model, and feeding back a checking result to the CS client, so that the CS client displays the checking result to a user to realize the graph mode checking of the equipment.

Furthermore, the calling module may be further configured to respond to a second cooperative operation triggered by an external system through a WebGIS-API data interface, call the model data stored in the model database according to the second cooperative operation, and send the called model data to the external system, so that the external system displays or applies the called model data.

The multi-energy collaborative display method and device based on the GIS provided by the embodiment of the invention have the following beneficial effects:

the invention provides a GIS-based multi-energy collaborative display method and a device, which are used for acquiring various categories of energy categories and information required by modeling of the categories; establishing station internal and external models corresponding to each category by combining preset modeling rules of each category according to information required by modeling of each category; carrying out modeling rule checking treatment on the in-station models and the out-station models corresponding to all categories in sequence, and storing the models passing the checking treatment to a model database; and responding to the CS client or responding to the cooperative operation triggered by the external system through the WebGIS-API data interface, calling the verified model and executing the corresponding cooperative function, realizing the cooperative processing of various energy data, simplifying the processing mode and reducing the data fusion cost.

Drawings

FIG. 1: the invention provides an embodiment of the GIS-based multi-energy cooperation method.

FIG. 2: the invention provides another implementation mode of an embodiment of the GIS-based multi-energy cooperation method.

FIG. 3: the invention provides a schematic structural diagram of an embodiment of a GIS-based multi-functional collaborative display device.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

referring to fig. 1, an embodiment of the present invention provides a GIS-based multi-energy coordination method, which includes:

step 101: acquiring various types of energy types and information required by modeling of the various types; wherein each category of the energy class comprises one or more of the following combinations: comprehensive, gas, cooling and heating, metering and electric power.

In this embodiment, the energy source includes one or more of the following: comprehensive, gas, cooling and heating, metering and electric power. Therefore, before unified modeling, specific categories of energy classes need to be determined and information of each category, which mainly includes comprehensive categories, gas categories, cooling and heating categories, metering categories and electric power categories, needs to be obtained, and then models of each category can be established.

Step 102: establishing station internal and external models corresponding to each category by combining preset modeling rules of each category according to information required by modeling of each category; and a plurality of devices and device information corresponding to each device are arranged in each model.

In this embodiment, the in-station and out-of-station modeling includes:

modeling lines, pipelines and equipment by combining preset off-station modeling rules corresponding to the types of the models to be modeled to obtain off-station equipment models of the types of the models to be modeled;

modeling the internal connecting line of the plant station equipment by combining a preset in-station modeling rule corresponding to the category to be modeled to obtain an in-station equipment model of the category to be modeled;

and linking each device in the in-station device model and the out-station device model through the in-station and out-station linking points to obtain the in-station and out-station models corresponding to the category to be modeled.

And after the equipment is modeled, supplementing the machine account of the equipment, and supplementing the attributes of the equipment, wherein the attributes comprise factory names, voltage grades and the like.

In this embodiment, after the modeling is completed, the modeling rules of the various types of equipment data in the intra-and-inter-station models and the rule base are sequentially verified, and each type of energy source has a specific modeling rule requirement. The modeling rules can be imported from a rule base (rule base timing update) according to needs, for example, only icons of one type of energy equipment need to be imported when only one type of energy equipment is needed for modeling. Warehousing the checked model into a model database; and if the verification is not passed, correspondingly modifying the in-station model and the out-station model according to a model modification instruction input by a user until the modified model passes the verification of the modeling rule.

Step 103: responding to a first cooperative operation triggered by a CS client, calling a model stored in the model database according to the first cooperative operation, generating corresponding feedback information, and sending the feedback information to the CS client so that the CS client executes a corresponding first cooperative function according to the feedback information; wherein the first coordination function comprises: a device query function, a topology analysis function, or a graph-model verification function.

In this embodiment, the first coordination function in an implementation manner of step 103 may be an equipment query function, which specifically is: calling a passing verification model in a model database, inquiring the position information of the first equipment on the map and the attribute information of the equipment, and feeding back the position information and the attribute information to the CS client so that the CS client displays the information to a user to realize equipment inquiry and positioning;

the first coordination function further includes a topology analysis function, specifically: calling the passed model in the model database, inquiring the topological relation, the upper-lower level relation and the equipment tree relation of the second equipment according to the model, such as the connection relation of the equipment, whether the equipment is communicated or not, whether isolated equipment exists or not and the like, and feeding back the information to the CS client so that the CS client can show the information to a user to realize topological analysis; the second device and the first device are not particularly specified to a certain device or a certain class of devices, but are used for distinguishing a device query function and a topology analysis function, so that the first device can also use the topology analysis function, and the second device can also complete the device query function;

the first cooperation function further includes a graph-model checking function, which specifically includes: calling the passed model in the model database, verifying the corresponding correctness of the semantics, integrity, topological connectivity and graph model consistency of the called model, and feeding back the verification result to the CS client, so that the CS client displays the verification result to the user, thereby realizing graph model verification.

Referring to fig. 2, another implementation manner of step 4 in this embodiment is specifically as follows:

step 203: responding to a second cooperative operation triggered by an external system through a WebGIS-API data interface, calling model data stored in the model database according to the second cooperative operation, and sending the called model data to the external system so as to enable the external system to display or apply the called model data.

In this embodiment, the WebGIS-API interfaces the data of the integrated energy device and provides a data interface to the outside through a developer center that is displayed in a Demo manner, thereby implementing the multi-energy collaborative and fusion display of various energy types on other systems.

Example two:

referring to fig. 3, fig. 3 is a schematic structural diagram of an embodiment of the GIS-based multi-functional collaborative display device according to the present invention. As shown in fig. 3, the apparatus includes: an acquisition module 301, a modeling module 302, and a calling module 303.

The obtaining module 301 is configured to obtain each category of an energy class and information required for modeling each category; wherein each category of the energy class comprises one or more of the following combinations: comprehensive, gas, cooling and heating, metering and electric power;

the modeling module 302 is configured to establish an intra-station model and an extra-station model corresponding to each category according to information required for modeling of each category and in combination with preset modeling rules of each category; wherein, be provided with a plurality of equipment and the equipment information that each equipment corresponds in every model, specifically be:

acquiring icons corresponding to the types of models to be built, and modeling lines, pipelines and equipment in combination with preset off-station modeling rules corresponding to the types of the models to be built to acquire off-station equipment models of the types of the models to be built;

acquiring icons corresponding to the types of the to-be-modeled, and modeling the internal connection lines of the plant station equipment by combining with preset in-station modeling rules corresponding to the types of the to-be-modeled to acquire in-station equipment models of the types of the to-be-modeled;

linking each device in the in-station device model and the out-station device model through an in-station and out-station linking point to obtain an in-station and out-station model corresponding to the category to be modeled;

after the modeling module 302 is configured to establish the intra-and-out-of-station models corresponding to each category according to the information required for modeling of each category and by combining the preset modeling rules of each category, the method further includes:

checking various types of in-station and out-station models in sequence by combining the modeling rules of various types of equipment data in the rule base, and storing the models passing the checking into the model database;

if the verification is not passed, modifying the in-station model and the out-station model according to a model modification instruction input by a user until the modified model passes the verification of the modeling rule;

the calling module 303 is configured to respond to a first cooperative operation triggered by a CS client, call a model stored in the model database according to the first cooperative operation, generate corresponding feedback information, and send the feedback information to the CS client, so that the CS client executes a corresponding first cooperative function according to the feedback information; wherein the first coordination function comprises: the device query function, the topology analysis function or the graph-model verification function specifically include:

when the first cooperative function is an equipment query function, calling a model passing the verification in the model database, querying the position and the equipment information of the first equipment, and feeding back the position and the equipment information to the CS client, so that the CS client displays the position and the equipment information of the first equipment to a user to realize equipment query and positioning;

when the first cooperative function is a topology analysis function, calling a model passing the verification in the model database, inquiring the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment, and feeding back the inquiry to the CS client so that the CS client displays the topology relation, the superior-inferior relation and the equipment tree relation of the second equipment to a user to realize equipment topology analysis; the second device and the first device are not particularly specified to a certain device or a certain class of devices, but are used for distinguishing a device query function and a topology analysis function, so that the first device can also use the topology analysis function, and the second device can also complete the device query function;

and when the first cooperative function is a graph mode checking function, calling a passed model in the model database, checking the semantics, integrity, topological connectivity and graph mode consistency of the called model, and feeding back a checking result to the CS client, so that the CS client displays the checking result to a user to realize the graph mode checking of the equipment.

The calling module 303 may be further configured to respond to a second cooperative operation triggered by an external system through a WebGIS-API data interface, call the model data stored in the model database according to the second cooperative operation, and send the called model data to the external system, so that the external system displays or applies the called model data.

The multi-energy collaborative display method and device based on the GIS provided by the embodiment of the invention have the following beneficial effects:

the invention provides a GIS-based multi-energy collaborative display method and a device, which are used for acquiring various categories of energy categories and information required by modeling of the categories; establishing station internal and external models corresponding to each category by combining preset modeling rules of each category according to information required by modeling of each category; carrying out modeling rule checking treatment on the in-station models and the out-station models corresponding to all categories in sequence, and storing the models passing the checking treatment to a model database; and responding to the CS client or responding to the cooperative operation triggered by the external system through the WebGIS-API data interface, calling the verified model and executing the corresponding cooperative function, realizing the cooperative processing of various energy data, simplifying the processing mode and reducing the data fusion cost.

The above-mentioned embodiments are provided to further explain the objects, technical solutions and advantages of the present invention in detail, and it should be understood that the above-mentioned embodiments are only examples of the present invention and are not intended to limit the scope of the present invention. It should be understood that any modifications, equivalents, improvements and the like, which come within the spirit and principle of the invention, may occur to those skilled in the art and are intended to be included within the scope of the invention.