Smart park energy-saving diagnostic and management method, apparatus, and electronic equipment

The smart park energy-saving diagnostic management system addresses inefficiencies in energy management by adjusting equipment operation based on environmental data and user interactions, optimizing energy consumption and reducing waste.

JP2026522039APending Publication Date: 2026-07-06THE FIRST COMPARY OF CHINA EIGHTH ENG BUREAU LTD

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
THE FIRST COMPARY OF CHINA EIGHTH ENG BUREAU LTD
Filing Date
2025-04-09
Publication Date
2026-07-06

AI Technical Summary

Technical Problem

Smart parks face challenges in managing energy consumption efficiently due to varying management levels, leading to energy waste, and there is a need for an intelligent energy-saving diagnosis management system that can precisely control energy usage while meeting user requirements.

Method used

A smart park energy-saving diagnostic management system is implemented, comprising a central management module, energy-saving diagnostic module, front-end data collection module, park display module, and communication module, which diagnoses energy consumption, sends control commands to adjust equipment operation based on preset target ranges, and provides energy-saving recommendations.

Benefits of technology

The system accurately controls energy use in smart parks by adjusting equipment operation to meet user demands, reducing energy waste and optimizing energy consumption based on environmental data and user interactions.

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Patent Text Reader

Abstract

This invention discloses a smart park energy-saving diagnostic and management method, apparatus, and electronic equipment. When the energy-saving diagnostic module detects that the energy consumption per unit time in any space exceeds the target energy consumption in the corresponding space, it transmits a command to the control module of the energy-consuming equipment via the communication module to acquire the current energy-consuming equipment control data in the space. It then determines whether there is any target energy-consuming equipment among the currently operating energy-consuming equipment whose control data exceeds a preset target control data range. The target control data range is a preset energy-saving control recommendation data range corresponding to different outdoor environment data. If a target energy-consuming equipment exists, a new control command is transmitted to the control module to bring the control data of the target energy-consuming equipment within the target control data range.
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Description

Technical Field

[0001] The present invention relates to the technical field of smart park management, and particularly to a smart park energy-saving diagnosis management method, device, electronic device, computer-readable storage medium, and computer program product.

Background Art

[0002] A smart park is an intelligent area that utilizes modern information technologies such as IoT, big data, cloud computing, and artificial intelligence to integrally manage various aspects within the park, such as energy usage, security monitoring, and environmental protection. Among these, intelligent management is the core. There are a large number of energy-consuming facilities in a smart park, and the difficulty of management is high, and the management levels vary, resulting in a certain degree of energy waste. Therefore, there is a need for an energy-saving diagnosis management method for smart parks that can control energy usage more intelligently and precisely while meeting the user's usage requirements.

Summary of the Invention

[0003] In view of such a situation, embodiments of the present invention provide a smart park energy-saving diagnosis management method, device, and electronic device, and aim to achieve energy conservation by controlling energy usage more smartly and precisely while meeting the user's usage requirements through an intelligent management approach.

[0004] In a first embodiment, an embodiment of the present invention provides a smart park energy-saving diagnostic management method. This method is applied to a smart park energy-saving diagnostic management system, which includes a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The energy-saving diagnostic module diagnoses the energy consumption of each space in the park based on energy consumption data collected by the front-end data collection module. The park display module displays each space in the park and shows the current energy consumption status. Each space in the smart park is equipped with a control module for the energy-consuming equipment within that space. This method includes the following steps. The energy-saving diagnostic module detects that the energy consumption per unit time in any given space exceeds the target energy consumption corresponding to that space, and sends a command to the control module of the energy-consuming equipment via the communication module to acquire control data for the energy-consuming equipment in the current space. Here, the control data corresponding to each time the energy-consuming equipment is started is generated by the user performing a setting operation using the interaction unit of the control module. A step in determining whether there are any currently operating energy-consuming equipment whose control data exceeds a preset target control data range, based on current outdoor environment data and acquired energy-consuming equipment control data within the space. Here, the target control data range is a preset energy-saving control recommendation data range corresponding to different outdoor environment data. If a target energy consumption facility exists, the step of sending a new control command to the control module and bringing the control data of the target energy consumption facility within the target control data range.

[0005] The smart park energy-saving diagnostic management system may further include an outdoor environment data collection module that detects current temperature and illuminance data within the park. The central management module is provided with a storage unit that stores recommended energy-saving control data ranges for energy-consuming equipment corresponding to spaces in different orientations under different outdoor environment data. The step of determining whether there are any target energy-consuming equipment currently in operation whose control data exceeds a preset target control data range, based on the current outdoor environment data and acquired energy-consuming equipment control data within the current space, includes the steps of matching the recommended energy-saving control data ranges for temperature control equipment and lighting equipment within the space from the storage unit based on the current outdoor temperature and illuminance data and orientation data of the energy-over-consumption space collected by the outdoor environment data collection module, and determining whether the temperature control equipment and lighting equipment currently in operation within the space are target energy-consuming equipment, based on the recommended energy-saving control data range and acquired control data for temperature control equipment and lighting equipment within the current space.

[0006] If a target energy-consuming equipment exists, a new control command is sent to the control module, and after bringing the control data of the target energy-consuming equipment within the target control data range, this method may further include the following steps. The step of operating the target energy consumption equipment according to the user's settings data when the control module detects that it has received a control data setting operation for the target energy consumption equipment from a new user.

[0007] The above method may further include the following steps. If new configuration data exceeds the corresponding target control data under the current outdoor environment data, a step is to send an energy consumption warning to the management terminal for the corresponding space. Here, the energy consumption warning includes the degree of energy consumption excess and the corresponding estimated energy consumption cost.

[0008] After sending an energy consumption warning to the corresponding park space management terminal, the method may further include the following steps: In response to an operation to monitor a communication request from a management terminal, the system determines the type of the communication request if it has been monitored. If the type of communication request is an energy consumption equipment usage consultation type, a data acquisition request is sent to the management terminal. The requested data type corresponding to the data acquisition request includes the number of people in the current space and their locations. Based on the number of people in the current space and their locations, the system sends energy-saving control recommendations for lighting and temperature control equipment to the management terminal.

[0009] The front-end data acquisition module may include an infrared camera acquisition module that detects whether there are people in the current space. The method further includes the following steps: The front-end data acquisition module, upon detecting that a person has entered the space, generates an energy-saving usage strategy for the energy-consuming equipment in the current space based on the current seating positions within the space and the number of people who have entered the space. The front-end data acquisition module then displays the energy-saving usage strategy on the control module's display screen.

[0010] In a second embodiment, an embodiment of the present invention provides a smart park energy-saving diagnostic and management device. This device is applied to a smart park energy-saving diagnostic and management system, the system including a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The energy-saving diagnostic module diagnoses the energy consumption of different spaces within the park based on energy consumption data collected by the front-end data collection module. The park display module displays each space within the park and shows the current energy consumption status. Each space within the smart park is equipped with a control module for the energy-consuming equipment within that space. This device includes a first transmission module, a first determination module, and a second transmission module. The first transmission module is configured to transmit a command to the control module of the energy-consuming equipment via the communication module to acquire control data for the energy-consuming equipment in the current space when the energy-saving diagnostic module detects that the energy consumption per unit time in a given space exceeds the target energy consumption in that space. The corresponding control data is generated each time the energy-consuming equipment is started up by a user performing a setting operation via the interaction unit of the control module. The first determination module is configured to determine, based on the current outdoor environment data and the acquired energy consumption equipment control data within the current space, whether there is any energy consumption equipment currently in operation whose control data exceeds a preset target control data range. The target control data range is a preset energy-saving control recommendation data range corresponding to different outdoor environment data. The second transmission module is configured to transmit a new control command to the control module if a target energy consumption facility exists, and to keep the control data of the target energy consumption facility within the target control data range.

[0011] In a third embodiment, an embodiment of the present invention provides an electronic device which includes a memory and a processor. The memory and the processor are communicated with each other, the memory stores computer instructions, and the processor executes the computer instructions to perform the smart park energy saving diagnostic management method described in the first embodiment or any selectable embodiment of the first embodiment.

[0012] In a fourth embodiment, an embodiment of the present invention provides a computer-readable storage medium in which computer instructions are stored, the computer instructions causing a computer to execute the smart park energy saving diagnostic management method described in the first embodiment or any selectable embodiment of the first embodiment.

[0013] In a fifth embodiment, an embodiment of the present invention provides a computer program product which includes computer instructions which cause a computer to execute the smart park energy saving diagnostic management method described in the first embodiment or any corresponding embodiment described above.

[0014] The smart park energy-saving diagnostic management method provided by an embodiment of the present invention is applied to a smart park energy-saving diagnostic management system, the system including a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The energy-saving diagnostic module is used to diagnose the energy consumption of different spaces within the park based on energy consumption data collected by the front-end data collection module, and the park display module is used to display each space within the park and show the current energy consumption status. Each space within the smart park is equipped with a control module for the energy-consuming equipment within that space, and the central management module is communicated with the energy-saving diagnostic module, the front-end data collection module, the park display module, and the communication module, respectively, and is used to receive data and issue control commands. If the energy-saving diagnostic module detects that the energy consumption per unit time of any space exceeds the target energy consumption for that space, it sends a command to acquire control data for the energy-consuming equipment within that space to the control module of the energy-consuming equipment via the communication module. Each time an energy-consuming piece of equipment is started up, the corresponding control data is generated by a user performing a setting operation via the interaction unit of the control module. Based on the current outdoor environment data and the acquired control data of energy-consuming equipment within the space, the system determines whether any currently operating energy-consuming equipment has control data that exceeds a pre-set target control data range. The target control data range is a pre-set energy-saving control recommendation data range corresponding to different outdoor environment data. If target energy-consuming equipment exists, a new control command is sent to the control module to bring the control data of the target energy-consuming equipment within the target control data range. By installing energy-consuming equipment control modules in each space, users can enter the space, make settings as needed, and satisfy their requests for the use of electrical equipment within the space.If the energy-saving diagnostic module detects that the energy consumption of any space exceeds the standard, it combines the current outdoor environment data, the control data of energy-consuming equipment in the energy-over-consumption space, and a predetermined range of recommended energy-saving control data to determine if there are any target energy-consuming equipment whose control data does not meet the requirements. If such equipment exists, it sends a control command to bring the control data of the target energy-consuming equipment within the target control data range that satisfies the energy-saving requirements, thereby more accurately controlling energy use while meeting the user's usage requirements as much as possible. [Brief explanation of the drawing]

[0015] To more clearly illustrate specific embodiments of the present invention or prior art, the drawings used to describe specific embodiments or prior art are briefly introduced below. Clearly, the drawings described below are some embodiments of the present invention, and those skilled in the art can obtain other drawings based on these without any creative effort. [Figure 1] Figure 1 is a flowchart of a smart park energy-saving diagnostic and management method according to an embodiment of the present invention. [Figure 2] Figure 2 is a structural block diagram of a smart park energy-saving diagnostic and management device according to an embodiment of the present invention. [Figure 3] Figure 3 is a schematic diagram of the hardware structure of an electronic device provided by an embodiment of the present invention. [Modes for carrying out the invention]

[0016] To further clarify the purpose, technical proposal, and advantages of the embodiments of the present invention, the technical proposal of the embodiments of the present invention will be clearly and completely described below in conjunction with the drawings of the embodiments of the present invention. Obviously, the embodiments described are some embodiments of the present invention, not all embodiments. All other embodiments that a person skilled in the art can obtain without creative effort based on the embodiments of the present invention are within the scope of protection of the present invention.

[0017] According to embodiments of the present invention, an embodiment of a smart park energy-saving diagnostic and management method is provided. The steps shown in the flowchart of the drawings can be executed by a computer system such as a set of computer executable instructions, and although the flowchart shows a logical order, the steps may be executed in a different order than those shown or described herein.

[0018] In this embodiment, a smart park energy-saving diagnostic management method is provided and applied to a smart park energy-saving diagnostic management system. The system includes a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The energy-saving diagnostic module is used to diagnose energy consumption in different spaces within the park based on energy consumption data collected by the front-end data collection module. The park display module is used to display each space within the park and show the current energy consumption status. The park display module is installed in the park management center so that park managers can monitor the energy consumption status of each space within the park at any time. Each space within the smart park is equipped with a control module for the energy-consuming equipment within that space, which may be a control module fixed to the wall of the space or a movable control module such as a remote control. The front-end data collection module may be any power monitor capable of collecting power usage data for the space. In this embodiment, the front-end data collection module may be installed in each space. As shown in Figure 1, the flow includes the following steps.

[0019] In step S101, if the energy-saving diagnostic module detects that the energy consumption per unit time in any space exceeds the target energy consumption in that space, it transmits a command to the control module of the energy-consuming equipment via the communication module to acquire control data for the energy-consuming equipment in that space. Each time the energy-consuming equipment is started up, the corresponding control data is generated by the user performing a setting operation via the interaction unit of the control module.

[0020] For example, energy-consuming equipment within each space is automatically closed by the system when no one is in the space, and when the system detects that someone has entered the space, the control data for the energy-consuming equipment is manually set in the control module. The energy-saving diagnostic module can be activated when the system detects that someone has entered the space. The energy-saving diagnostic module communicates with the front-end data collection module and diagnoses the energy consumption of each space. The target energy consumption for each space may be the maximum energy consumption per unit time set for each space in the park, based on the quantity and attribute parameters (type, power, etc.) of energy-consuming equipment within each space, and in accordance with the park's energy-saving usage standards, in order to achieve the maximum energy-saving effect under conditions that meet the user's usage requirements. In this embodiment, the length of the unit time is not limited, but one hour can be selected to ensure a good user experience. Energy-consuming equipment in each space may include lighting equipment, temperature control equipment, etc. In this embodiment, the type of energy-consuming equipment in each space is not limited. Energy consumption can be calculated by combining operating time and operating power. If the energy-saving diagnostic module detects that the energy consumption per unit time in any space exceeds the target energy consumption for that space, it sends a command to the control module of the energy-consuming equipment via the communication module to acquire control data for the energy-consuming equipment in that space. By sending this command, the user can obtain the control data for each energy-consuming equipment that they have currently set up.

[0021] Step S102: Based on the current outdoor environment data and the control data of the energy-consuming equipment in the current space that has been acquired, determine whether there is a target energy-consuming equipment among the currently operating energy-consuming equipment whose control data exceeds the preset target control data range. The target control data range is the energy-saving control recommended data range preset corresponding to different outdoor environment data.

[0022] For example, by acquiring the control data previously set by the user for the energy-consuming equipment, the user's usage requirements can be grasped. For example, since the current outdoor environment temperature is high, the user sets a low temperature for the temperature control equipment, which may increase the power consumption of the temperature control equipment and increase the energy consumption of the space. The outdoor environment data includes outdoor environment temperature data, outdoor illuminance data, etc., and this outdoor environment data can be acquired through communication with the meteorological system. The higher the outdoor environment temperature, the greater the user's usage requirements for the temperature control equipment, and the lower the outdoor illuminance, the more the user will increase the usage requirements for the indoor lighting equipment. Therefore, different energy-saving control recommended data ranges are preset for different outdoor environment data. For example, when the outdoor environment temperature is 35 degrees, the recommended temperature range for the indoor temperature control equipment can be set to 25-27 degrees, etc. This application does not limit the energy-saving control recommended data ranges corresponding to different outdoor environment temperatures, and those skilled in the art can set them based on air conditioning usage standards, etc. By acquiring the outdoor environment data, the energy-saving control recommended data range corresponding to the outdoor environment data can be matched, and based on the matched energy-saving control recommended data range, determine whether there is a target energy-consuming equipment among the operating energy-consuming equipment.

[0023] Step S103: If there is a target energy-consuming equipment, send a new control command to the control module so that the control data of the target energy-consuming equipment falls within the target control data range.

[0024] For example, the target control data range can be set to the optimal range value that meets the current outdoor environment usage demand. If a target energy consumption facility exists, the control data included in the control command transmitted to the control module can be any value within the optimal range value. The specific value can be determined based on the current outdoor temperature. If the outdoor temperature is high, the lowest temperature value within the range can be selected as the new control data for the temperature control equipment to ensure a good user experience. If the outdoor illuminance is low, the power of the lighting equipment can be set as high as possible. In addition, indoor environment parameters can be further combined to determine the optimal control data. For example, in the case of temperature data, after determining the recommended energy-saving control data range corresponding to the temperature control equipment based on the current outdoor environment data, the optimal control data for the temperature control equipment can be determined by further combining it with the current indoor environment temperature. If the indoor environment temperature is high, the lowest temperature within the recommended energy-saving control data range can be selected as the control data for the temperature control equipment.

[0025] The smart park energy-saving diagnostic management method provided by an embodiment of the present invention involves installing energy consumption equipment control modules in each space, so that after a user enters the space, the system can be set according to demand to meet the usage demand of electrical equipment within the space. When the energy-saving diagnostic module detects an excess of energy consumption in any space, it combines the current outdoor environment data, the energy consumption equipment control data in the space with the excess energy consumption, and a predetermined energy-saving control recommendation data range to determine whether there are any target energy consumption equipment whose control data does not meet the requirements. If target energy consumption equipment exists, a control command is sent to ensure that the control data of the target energy consumption equipment falls within the target control data range that satisfies the energy-saving requirement, thereby more accurately controlling energy use while meeting the user's usage demands as much as possible.

[0026] As one optional embodiment of the present invention, the smart park energy-saving diagnostic management system further includes an outdoor environment data collection module used to detect current temperature and illuminance data within the park. This outdoor environment data collection module may be installed in the central area of ​​the park or multiple modules may be installed in different orientations of the park. The central management module is equipped with a storage unit for storing energy-saving control recommendation data ranges for energy-consuming equipment corresponding to spaces in different orientations under different outdoor environment data.

[0027] Step S102 matches the recommended energy-saving control data range for the temperature control equipment and lighting equipment in the space from the storage unit based on the current outdoor temperature data and illuminance data collected by the outdoor environment data collection module, and the orientation data of the space with excess energy consumption. Based on the recommended energy-saving control data range and the acquired control data for the temperature control equipment and lighting equipment in the current space, it is determined whether the temperature control equipment and lighting equipment currently operating in the space are target energy-consuming equipment. By pre-storing the recommended energy-saving control data range for energy-consuming equipment corresponding to different outdoor environmental temperatures and spaces with different orientations, it is possible to avoid situations such as shading at different time periods affecting incorrect estimations of parameters such as illuminance at spatial locations with different orientations, thereby avoiding an impact on the user experience. The orientation of the space with excess energy consumption per unit time can be determined after the communication module communicates with the control module of the corresponding space, and the control module reports its physical location.

[0028] In one selectable embodiment of the present invention, if a target energy consumption facility exists, the method transmits a new control command to the control module so that the control data of the target energy consumption facility falls within the target control data range, and then, if the control module detects that it has received a setting operation for the control data of the target energy consumption facility from a new user, the method operates the target energy consumption facility according to the user's setting data.

[0029] For example, if a user performs a new setting operation on a target energy consumption equipment through the control module, the system will indicate that the control parameters set based on the energy-saving control recommended data range referenced by the system cannot meet the user's usage needs. To ensure a satisfactory user experience, the system will operate the target energy consumption equipment according to the user's setting data, and the central management module will not perform any further intelligent intervention. In the case of temperature control equipment, if the intelligent control of the central management module cannot meet the user's usage experience, it will send information indicating confirmation of the airtightness of the room to the management terminal of the corresponding space, thereby preventing energy waste due to incorrect use of the temperature control equipment.

[0030] In one optional embodiment of the present invention, the method further transmits an energy consumption warning to a corresponding space management terminal if new setting data exceeds target control data corresponding to current outdoor environment data. The energy consumption warning includes the degree of energy consumption excess and the corresponding estimated energy consumption cost. By transmitting an energy consumption warning to the space management terminal, the space management terminal can be prompted to take timely action on the space's energy consumption. For example, it can promptly check whether there are situations in the space where use has stopped but energy-consuming equipment has not yet been shut down.

[0031] In one embodiment of the present invention, after transmitting an energy consumption warning to a management terminal of a corresponding park space, the method further responds to an operation to monitor a communication request from the management terminal, and if it has monitored the communication request from the management terminal, it determines the type of the communication request, and if the type of the communication request is an energy consumption equipment usage consultation type, it transmits a data acquisition request to the management terminal. The request data type corresponding to the data acquisition request includes the number of people and the location of the people in the current space, and based on the number of people and the location of the people in the current space, it transmits energy-saving control recommendations for lighting equipment and temperature control equipment to the management terminal.

[0032] For example, if a space with excessive energy consumption is still in use and the excess situation exists, an energy consumption warning can be sent to the management terminal of the corresponding space, and then the operation to monitor the management terminal's communication requests can be enabled. If the management terminal's request type is monitored to be a consultation type regarding the use of energy-consuming equipment, the central management module will not perform intelligent intervention in order to guarantee the user's customized user experience. At this time, a request is sent to the management terminal to obtain the current number of people in the space and the location of the personnel. Based on the obtained information on the current number of people and location of personnel in the space, and combined with the geographic location of the energy-consuming equipment in the space, an energy-saving control recommendation for lighting and temperature control equipment is sent to the management terminal as a reference for the management terminal to customize its settings. In this embodiment, the energy-saving control recommendation includes a plan to selectively activate one or more lighting and / or temperature control equipment in the corresponding direction, or to activate the corresponding energy-consuming equipment according to time intervals, thereby avoiding energy waste as much as possible.

[0033] In one optional embodiment of the present invention, the front-end data acquisition module includes an infrared camera acquisition module used to detect whether there are people in the current space. If the method detects that people have entered the space, it further generates an energy-saving usage strategy for energy-consuming equipment in the current space based on the seating positions in the current space and the number of people in the space, and displays the energy-saving usage strategy on the display interface of the control module.

[0034] For example, if it is detected that no personnel are using a space, the communication module and control module will promptly shut down the energy-consuming equipment in the space. If it is detected that new personnel have entered the space, the seating positions in the space can be determined using a pre-acquired BIM model of the space. Furthermore, by combining the number of seating positions and the number of personnel who may enter the space, an energy-saving usage strategy for the current energy-consuming equipment in the space is generated. The number of personnel who may enter the space can provide multiple possible ranges, and energy-saving usage strategies can be set for each different range value. Users can adaptively select based on the number of people they are aware of through the display interface. For example, if the seating positions in the space are located near windows and there are 10 seats, energy-saving usage strategies for 1-5 people, 6-10 people, and more than 10 people can be set. By displaying these strategies on the control module's display interface, users can select and set control data with energy-saving targets in mind when configuring through the control module. For example, an energy-saving strategy offered for 1-5 users could activate the air conditioning corresponding to the area where the seats are located and further suggest the air conditioning temperature based on the outside temperature.

[0035] In one optional embodiment of the present invention, the smart park energy-saving diagnostic management system further includes a spatial state collection module used to collect changes in the spatial size of the space in which it is located. In the embodiment of the present application, this spatial state collection module is a rangefinder that collects spatial size according to a target interval time and transmits the collected size to a central management module so that the central management module can grasp the changes in spatial status within the park in a timely manner and update the energy-saving strategy, thereby preventing space users from independently changing the spatial layout and affecting the effective use of the energy-saving strategy.

[0036] In this embodiment, a type of smart park energy-saving diagnostic and management device is further provided, which is used to implement the above-described embodiments and preferred embodiments, and the content already described will not be repeated. The term "module" as used below can implement a combination of software and / or hardware that implements a predetermined function. The devices described in the following embodiments are preferably implemented in software, but can also be implemented in hardware, or a combination of software and hardware, and are conceived.

[0037] This embodiment provides a type of smart park energy-saving diagnostic management device, which is applied to a smart park energy-saving diagnostic management system, the smart park energy-saving diagnostic management system including a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The energy-saving diagnostic module is used to diagnose energy consumption in different spaces within the park based on energy consumption data collected by the front-end data collection module, and the park display module is used to display each space within the park and show the current energy consumption status. Each space within the smart park is equipped with a control module for the energy-consuming equipment in that space. As shown in Figure 2, this includes the following: The first transmission module 201 is configured such that, when the energy saving diagnostic module detects that the energy consumption per unit time in any given space exceeds the target energy consumption in that space, it transmits a command to the control module of the energy consumption equipment via the communication module to acquire the current energy consumption equipment control data for that space. The corresponding control data is generated each time the energy consumption equipment is started up by a user performing a setting operation via the interaction unit of the control module. The first determination module 202 is configured to determine, based on the current outdoor environment data and the acquired energy consumption equipment control data within the current space, whether there is any energy consumption equipment currently in operation whose control data exceeds a preset target control data range. The target control data range is a recommended energy-saving control data range that has been set in advance to correspond to different outdoor environment data. The second transmission module 203 is configured to transmit a new control command to the control module when a target energy consumption facility exists, and to keep the control data of the target energy consumption facility within the target control data range. A detailed explanation is provided in the related descriptions corresponding to the above-described method embodiments and will not be repeated here.

[0038] The smart park energy saving diagnostic management device in this embodiment is presented in the form of a functional unit, where the unit refers to an ASIC circuit, a processor and memory that execute one or more software or fixed programs, and / or other devices that can provide the functions described above.

[0039] The smart park energy-saving diagnostic management device provided in this embodiment installs an energy consumption equipment control module in each space, allowing the user to set the settings according to their needs after entering the space, thereby meeting the usage requirements of electrical equipment within the space. When the energy-saving diagnostic module detects an excess of energy consumption in any space, it combines the current outdoor environment data, the energy consumption equipment control data within the excess space, and a predetermined energy-saving control recommendation data range to determine whether there are any target energy consumption equipment whose control data does not meet the requirements. If target energy consumption equipment exists, a control command is sent to ensure that the control data of the target energy consumption equipment falls within the target control data range that satisfies the energy-saving requirement, thereby more accurately controlling energy use while meeting the user's usage needs as much as possible.

[0040] In one selectable embodiment of the present invention, the smart park energy-saving diagnostic management system further includes an outdoor environment data collection module used to detect current temperature and illuminance data within the park. The central management module is equipped with a storage unit for storing recommended energy-saving control data ranges for energy-consuming equipment corresponding to spaces in different orientations under different outdoor environment data. The first determination module further includes a matching unit used to match recommended energy-saving control data ranges for temperature control and lighting equipment within a space from the storage unit based on the current outdoor temperature and illuminance data and orientation data of the energy-over-consumption space collected by the outdoor environment data collection module. The determination unit is used to determine whether the temperature control and lighting equipment currently running within the space is the target energy-consuming equipment, based on the recommended energy-saving control data range and the acquired control data for the temperature control and lighting equipment within the space.

[0041] In one optional embodiment of the present invention, the apparatus further includes a control module, which is used to operate the target energy consumption equipment according to the user's setting data when the control module detects that it has received a setting operation for control data of the target energy consumption equipment from a new user.

[0042] In one optional embodiment of the present invention, the apparatus further includes a third transmission module used to transmit an energy consumption warning to a corresponding space management terminal when new configuration data exceeds target control data corresponding to current outdoor environment data. The energy consumption warning includes the degree of energy consumption excess and the corresponding estimated energy consumption cost.

[0043] In one optional embodiment of the present invention, the apparatus further includes a monitoring module used to respond to operations that monitor communication requests from the management terminal. A second confirmation module is used to determine the type of communication request when it has monitored the communication request from the management terminal. A fourth transmission module is used to send a data acquisition request to the management terminal if the type of communication request is an energy consumption equipment usage consultation type. The request data type corresponding to the data acquisition request includes the number of people and the location of the personnel in the current space. A fifth transmission module is used to send energy-saving control recommendations for lighting and temperature control equipment to the management terminal based on the number of people and the location of the personnel in the current space.

[0044] In one selectable embodiment of the present invention, the front-end data acquisition module includes an infrared camera acquisition module used to detect whether there are people in the current space. The device further includes a generation module, which, if it detects that people have entered the space, is used to generate an energy-saving usage strategy for energy-consuming equipment in the current space based on the seating positions in the current space and the number of people who have entered the space. A display module is used to display the energy-saving usage strategy on the display interface of the control module.

[0045] Further functional descriptions of each of the above modules are the same as those of the corresponding embodiments described above and will not be repeated here.

[0046] Embodiments of the present invention further provide electronic equipment equipped with the smart park energy-saving diagnostic and management device shown in Figure 2 above.

[0047] Please refer to Figure 3. Figure 3 is a schematic diagram showing the structure of an apparatus provided by an optional embodiment of the present invention. As shown in Figure 3, the apparatus may include at least one processor 601 (e.g., a Central Processing Unit, CPU), at least one communication interface 603, memory 604, and at least one communication bus 602. Here, the communication bus 602 is used to enable connection communication between these components. The communication interface 603 may include a display, a keyboard, and optionally the communication interface 603 may further include a standard wired interface, a wireless interface. The memory 604 may be high-speed volatile random access memory (RAM), non-volatile memory, and may be, for example, at least one disk memory. The memory 604 may optionally further include at least one storage device located away from the aforementioned processor 601. The processor 601 may be combined with the apparatus described in Figure 2, the memory 604 may store an application, and the processor 601 is used to invoke the program code stored in the memory 604 to execute any of the method steps described above.

[0048] Here, the communication bus 602 may be a peripheral component interconnect (PCI) bus or an extended industry standard architecture (EISA) bus, etc. The communication bus 602 is divided into an address bus, a data bus, a control bus, etc. For the sake of visual convenience, it is represented by a single thick line in Figure 3, but this does not mean that there is only one bus or only one type of bus.

[0049] Here, memory 604 may include volatile memory, such as random-access memory (RAM). Memory may further include non-volatile memory, such as flash memory, hard disk drive (HDD), or solid-state drive (SSD). Memory 604 may also include combinations of the above types of memory.

[0050] Here, the processor 601 may be a central processing unit (CPU), a network processor (NP), or a combination of a CPU and an NP.

[0051] Here, the processor 601 may further include hardware chips. The aforementioned hardware chips may be application-specific integrated circuits (ASICs), programmable logic devices (PLDs), or a combination thereof. The aforementioned PLDs may be complex programmable logic devices (CPLDs), field-programmable gate arrays (FPGAs), generic array logic (GALs), or any combination thereof.

[0052] Selectively, memory 604 is used to store additional program instructions. The processor 601 can invoke the program instructions to implement the smart park energy saving diagnostic management method shown in the embodiment of Figure 1 of the present application.

[0053] Embodiments of the present invention further provide a non-temporary computer storage medium in which computer executable instructions are stored, and these computer executable instructions can execute the processing method of the smart park energy saving diagnostic management method in any of the above-described method embodiments. Here, the storage medium may be a magnetic disk, an optical disk, read-only memory (ROM), random access memory (RAM), flash memory, a hard disk drive (HDD), or a solid-state drive (SSD), etc. The storage medium may further include a combination of the above-described types of memory.

[0054] Part of the present invention is applicable as a computer program product, for example, a computer program instruction, which, when executed by a computer, can be called or provided through the operation of the computer in accordance with the methods and / or technical solutions of the present invention. Those skilled in the art should understand that the form in which a computer program instruction exists on a computer-readable medium is not limited to source files, executable files, installation package files, etc., and correspondingly, the way in which a computer program instruction is executed by a computer is not limited to the computer directly executing the instruction, or the computer compiling the instruction and then executing the corresponding compiled program, or the computer reading and executing the instruction, or the computer reading and installing the instruction and then executing the corresponding installed program, etc., where the computer-readable medium may be any available computer-readable storage or communication medium accessible to the computer.

[0055] While embodiments of the present invention have been described in conjunction with the drawings, those skilled in the art can make various edits and modifications without departing from the spirit and scope of the invention, all such edits and modifications are included within the scope defined by the appended claims.

Claims

1. A smart park energy-saving diagnostic and management method, Applicable to the Smart Park Energy Saving Diagnostic Management System, The smart park energy-saving diagnostic management system includes a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The aforementioned energy-saving diagnostic module is used to diagnose the energy consumption of each space within the park based on the energy consumption data collected by the front-end data collection module. The aforementioned park display module is used to display each space within the park and to display the current energy consumption status. Each space within the aforementioned smart park is equipped with a control module for the energy consumption equipment within that space. This method is a smart park energy-saving diagnostic and management method characterized by including the following steps. The energy-saving diagnostic module detects that the energy consumption per unit time in any given space exceeds the target energy consumption corresponding to that space, and the communication module transmits a command to the control module of the energy-consuming equipment to acquire control data for the energy-consuming equipment in the current space, wherein the control data corresponding to each time the energy-consuming equipment is started is generated by a user performing a setting operation using the interaction unit of the control module. A step of determining whether there is any energy-consuming equipment currently in operation whose control data exceeds a predetermined target control data range, based on current outdoor environment data and acquired control data of energy-consuming equipment in the current space, wherein the target control data range is a recommended energy-saving control data range that has been set in advance to correspond to different outdoor environment data. If a target energy consumption facility exists, the step of sending a new control command to the control module and bringing the control data of the target energy consumption facility within the target control data range.

2. The smart park energy-saving diagnostic management system further includes an outdoor environment data collection module that detects current temperature and illuminance data within the park. The central management module is equipped with a storage unit that stores recommended data ranges for energy-saving control of energy-consuming equipment corresponding to spaces in different orientations under different outdoor environmental data. Based on the current outdoor environment data and the acquired energy consumption equipment control data within the current space, the step of determining whether there is any energy consumption equipment currently in operation whose control data exceeds a predetermined target control data range is: Based on the current outdoor temperature data and illuminance data collected by the outdoor environment data collection module, as well as the orientation data of the space with excess energy consumption, the memory unit matches the recommended data range for energy-saving control of the temperature control equipment and lighting equipment within that space. The method according to claim 1, comprising the step of determining whether the temperature control equipment and lighting equipment currently operating in the space are target energy consumption equipment, based on the energy-saving control recommended data range and the acquired control data of the temperature control equipment and lighting equipment in the space at the time of operation.

3. The method according to claim 1, characterized in that, if a target energy consumption facility exists, a new control command is transmitted to the control module, and after the control data of the target energy consumption facility is brought within the target control data range, the method further includes the following steps. If the control module detects that it has received a control data setting operation for the target energy consumption equipment from a new user, the step of operating the target energy consumption equipment according to the user's setting data.

4. The method according to the present invention further comprises the following steps. If new setting data exceeds corresponding target control data under current outdoor environment data, the step of sending an energy consumption warning to the corresponding space management terminal, wherein the energy consumption warning includes the degree of energy consumption excess and the corresponding estimated energy consumption cost.

5. The method according to 4, characterized in that, after transmitting an energy consumption warning to the corresponding park space management terminal, the method further includes the following steps. A step of responding to an operation to monitor a communication request from the management terminal, When monitoring the communication requests of the management terminal, the step of determining the type of the communication request, If the type of the communication request is an energy consumption equipment usage consultation type, the step is to send a data acquisition request to the management terminal, wherein the request data type corresponding to the data acquisition request includes the number of people in the current space and the location of the people. A step of transmitting energy-saving control recommendations for lighting equipment and temperature control equipment to the management terminal based on the number of people and their locations within the current space.

6. The method according to claim 1, wherein the front-end data acquisition module includes an infrared camera acquisition module used to detect whether there is a person in the current space, and the method further comprises the following steps. When it is detected that a person has entered the space, the system generates an energy-saving usage strategy for the energy-consuming equipment in the space based on the current seating positions in the space and the number of people who have entered the space. The step of displaying the energy-saving usage strategy on the display screen of the control module.

7. Smart park energy saving diagnostic and management device, Applicable to the Smart Park Energy Saving Diagnostic Management System, The smart park energy-saving diagnostic management system includes a central management module, an energy-saving diagnostic module, a front-end data collection module, a park display module, and a communication module. The aforementioned energy-saving diagnostic module is used to diagnose the energy consumption of different spaces within the park based on the energy consumption data collected by the front-end data collection module. The aforementioned park display module is used to display each space within the park and to display the current energy consumption status. Each space within the aforementioned smart park is equipped with a control module for the energy consumption equipment within that space. This device includes a first transmission module, a first determination module, and a second transmission module. The first transmission module is configured such that, when the energy saving diagnostic module detects that the energy consumption per unit time in any given space exceeds the target energy consumption in that space, it transmits a command to the control module of the energy consumption equipment via the communication module to acquire the current energy consumption equipment control data in that space. The corresponding control data is generated each time the energy consumption equipment is started by the user performing a setting operation via the interaction unit of the control module. The first determination module is configured to determine, based on the current outdoor environment data and the acquired energy consumption equipment control data within the current space, whether there is any energy consumption equipment currently in operation whose control data exceeds a preset target control data range, wherein the target control data range is a preset energy-saving control recommendation data range corresponding to different outdoor environment data. The smart park energy-saving diagnostic and management device is characterized in that the second transmission module transmits a new control command to the control module when a target energy-consuming equipment exists, and is configured to keep the control data of the target energy-consuming equipment within the target control data range.

8. It is an electronic device, Including memory and processor, The electronic device is characterized in that the memory and the processor are connected to each other in communication, the memory stores computer instructions, and the processor executes the smart park energy saving diagnostic management method according to any one of claims 1 to 6 by executing the computer instructions.

9. A computer-readable storage medium, The computer-readable storage medium is characterized in that it stores computer instructions, and the computer instructions cause a computer to execute the smart park energy saving diagnostic management method described in any one of claims 1 to 6.

10. A computer program product, The product is a computer program product characterized in that it includes computer instructions, the computer instructions cause a computer to execute the smart park energy saving diagnostic management method described in any one of claims 1 to 6.