CN118971325A

CN118971325A - A UPS power supply and intelligent power supply method thereof

Info

Publication number: CN118971325A
Application number: CN202411420176.2A
Authority: CN
Inventors: 黄国军
Original assignee: Shenzhen Lehui Emergency Technology Co ltd
Current assignee: Shenzhen Lehui Emergency Technology Co ltd
Priority date: 2024-10-12
Filing date: 2024-10-12
Publication date: 2024-11-15
Anticipated expiration: 2044-10-12
Also published as: CN118971325B

Abstract

The invention discloses a UPS power supply and an intelligent power supply method thereof, comprising a base, a power supply module arranged on the base, a UPS module arranged on the base and electrically connected with the power supply module, and a winding assembly arranged at one side of the base and used for managing the winding and unwinding of cables; the sensor module comprises a temperature sensor for monitoring the environment and the equipment temperature and a current sensor for monitoring the power consumption data of each load; the UPS module is responsible for power management and switching to ensure uninterrupted power supply, a temperature sensor and a current sensor in the sensor module monitor the ambient temperature and the power consumption data of each load in real time, and the data are transmitted to the intelligent control system so as to analyze and adjust the power supply strategy in real time; the stability and the high efficiency of the system under different environmental conditions are ensured, so that the system is suitable for various occasions, different power requirements are met, and the continuous power supply of key loads is ensured.

Description

UPS power supply and intelligent power supply method thereof

Technical Field

The invention relates to the technical field of power supplies, in particular to a UPS power supply and an intelligent power supply method thereof.

Background

With the rapid development of electronic devices and information technology, the need for Uninterruptible Power Supplies (UPS) in various industries is increasing. UPS systems play an important role in securing the continuous power supply to computers, communications equipment, and other critical equipment, particularly in the fields of data centers, medical facilities, and industrial control. Modern UPS systems need not only provide stable power output, but also intelligent management capabilities to accommodate dynamically changing load demands and environmental conditions.

Existing UPS systems typically employ fixed installations, relying on traditional cable management and basic load monitoring approaches, which have limitations in power stability, particularly in complex and changing environments where it is difficult to quickly respond to load changes and fluctuations in ambient temperature. Due to the lack of flexible cable management and a real-time intelligent monitoring system, the traditional UPS equipment cannot effectively adjust a power supply strategy when facing variable power consumption demands, so that power resource waste and unstable power supply of key loads are caused. This limitation directly affects the overall efficiency and reliability of the device, and there is a strong need for an intelligent UPS system that can be monitored and adjusted in real-time to overcome these deficiencies.

In view of this, there is a need for improvements in the UPS system power technology of the prior art to address the situation where the power supply is unstable due to load variations.

Disclosure of Invention

The invention aims to provide a UPS and an intelligent power supply method thereof, which solve the technical problems.

To achieve the purpose, the invention adopts the following technical scheme:

A UPS power source, comprising:

A base, a base seat and a base seat,

The power supply module is arranged on the base and used for providing power output;

The UPS module is arranged on the base, is electrically connected with the power supply module and is used for carrying out uninterrupted power supply management and switching on the power supply module;

The coiling assembly is arranged at one side part of the base and is used for managing the winding and unwinding of the cable;

The sensor module comprises a temperature sensor for monitoring the environment and the equipment temperature and a current sensor for monitoring the power consumption data of each load.

Optionally, the UPS power source further includes a track assembly, where the track assembly is disposed on a lower end surface of the base, and is configured to drive the UPS power source to move;

the crawler belt assembly comprises crawler belt bodies arranged at intervals, a first driving motor is arranged on one side of each crawler belt body, a storage space is arranged between each crawler belt body, and a folding slope assembly is arranged in each storage space.

Optionally, the folding slope assembly comprises two folding slopes which are arranged in parallel, and the two folding slopes are connected through a telescopic hinge;

The folding slope comprises a main body supporting plate, a first folding plate and a second folding plate which are respectively connected to two end parts of the main body supporting plate in a rotating mode, and guide inclined planes are respectively arranged at one ends of the first folding plate and the second folding plate.

Optionally, the winding assembly comprises a supporting frame, a reel is rotatably connected to the supporting frame, and a second driving motor is arranged on one side of the reel;

The lower part of the reel is provided with a pressing assembly, the pressing assembly comprises a pressing plate, the first end of the pressing plate is provided with a rotating shaft, and the pressing plate is rotationally connected to the supporting frame through the rotating shaft; the second end of the pressing plate is provided with an arc-shaped part for pressing the cable;

The middle part of the compacting plate is provided with a connecting shaft, the connecting shaft is connected with an extension spring, one end of the extension spring is connected with the supporting frame, and the extension spring is used for pushing the compacting plate to rotate towards the direction close to the reel.

The invention also provides an intelligent power supply method which is applied to the UPS, and comprises the following steps:

A temperature sensor and a current sensor are configured on a UPS, and the current sensor is used for monitoring and acquiring power consumption data of each load of a power consumption area in real time and acquiring temperature data of environment and equipment temperature;

The power consumption data of all loads are combined, load demands of a power consumption area are evaluated, a load predicted value is generated, when the load predicted value exceeds or is lower than a preset power supply range, the intelligent control system starts a power supply scheduling mechanism, the output power and a power supply path of the UPS module are adjusted, and a power supply adjustment strategy is generated;

Carrying out temperature compensation on the load predicted value through the temperature data so as to optimize the power supply adjustment strategy, and dynamically adjusting the power supply adjustment strategy according to the change condition of the temperature data;

And according to the power supply adjustment strategy, the intelligent control system controls the track assembly of the UPS power supply to adjust the position of the UPS power supply so as to optimize the power supply path.

Optionally, in combination with electricity consumption data of each load, load demands of the electricity consumption area are evaluated, and a load predicted value is generated, which specifically includes:

Collecting a current electricity data set of an electricity utilization area through the electricity utilization data of each load monitored in real time, and recording an electricity utilization change mode in a short period;

carrying out trend analysis on the collected electricity data set by using a statistical analysis method to generate a load predicted value of the current electricity utilization area;

and comparing the generated load predicted value with a preset power supply range, and identifying the condition of insufficient power supply or overload.

Optionally, the intelligent control system starts a power supply scheduling mechanism to adjust the output power and the power supply path of the UPS module, and generates a power supply adjustment policy, which specifically includes:

according to the load predicted value, the intelligent control system calculates the total power demand of the electricity utilization area, evaluates the priority and the demand of each load, and identifies the key load and the secondary load;

The available power capacity of the current UPS module is estimated by combining the current data measured in real time and the total power demand;

Distributing the output power of each load based on the power requirement of each load and the available power capacity of the UPS module, and adjusting a power supply path to generate a preliminary power supply adjustment strategy;

And the initial power supply adjustment strategy is applied to the UPS module through the intelligent control system, and the output power and the power supply path are adjusted in real time.

Optionally, temperature compensating the load predicted value through the temperature data to optimize the power supply adjustment strategy, which specifically includes:

Analyzing the temperature data, determining the influence of temperature change on each load power, and calculating a temperature compensation value to correct a load predicted value;

comparing the corrected load predicted value with the original value, and updating the load demand;

and according to the updated load demand, the intelligent control system optimizes a power supply adjustment strategy, and dynamically adjusts the UPS output power and the power supply path to optimize the power supply adjustment strategy.

Optionally, according to the power supply adjustment policy, the intelligent control system controls the track assembly of the UPS power source to adjust a position of the UPS power source to optimize a power supply path, and then further includes:

And providing real-time power supply state information and power supply strategy adjustment options through a user interface, receiving user input and feedback, and further optimizing the power supply adjustment strategy.

Compared with the prior art, the invention has the following beneficial effects: the UPS power supply provides power output through the power supply module on the base, the UPS module is responsible for power management and switching, uninterrupted power supply is ensured, the winding assembly is used for flexibly managing the winding and unwinding of cables, the movement and deployment of equipment are facilitated, the temperature sensor and the current sensor in the sensor module monitor the environmental temperature and the power consumption data of each load in real time, and the data are transmitted to the intelligent control system so as to perform real-time analysis and adjust a power supply strategy; the stability and the high efficiency of the system under different environmental conditions are ensured, so that the system is suitable for various occasions, different power requirements are met, and the continuous power supply of key loads is ensured.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.

The structures, proportions, sizes, etc. shown in the drawings are shown only in connection with the present disclosure, and are not intended to limit the scope of the invention, since any modification, variation in proportions, or adjustment of the size, etc. of the structures, proportions, etc. should be considered as falling within the spirit and scope of the invention, without affecting the effect or achievement of the objective.

Fig. 1 is a schematic diagram of the overall structure of a UPS power source according to the first embodiment;

Fig. 2 is a schematic front view of a UPS power source according to the first embodiment;

fig. 3 is a schematic structural diagram of a folding ramp assembly of a UPS power source according to the first embodiment;

fig. 4 is a schematic structural diagram of a winding assembly of a UPS power source according to the first embodiment.

Detailed Description

In order to make the objects, features and advantages of the present invention more comprehensible, the technical solutions in the embodiments of the present invention are described in detail below with reference to the accompanying drawings, and it is apparent that the embodiments described below are only some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "top", "bottom", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. It is noted that when one component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present.

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

Embodiment one:

Referring to fig. 1 to 4, an embodiment of the present invention provides a UPS power source, which includes a base 10, a power supply module 20, a UPS module 30, a coil assembly 40, and a sensor module 50. The power supply module 20 is arranged on the base 10 and is used for providing power output; the UPS module 30 is disposed on the base 10 and electrically connected to the power supply module 20, for performing uninterrupted power management and switching on the power supply module 20; the winding assembly 40 is disposed at a side portion of the base 10 for managing the winding and unwinding of the cable; the sensor module 50 includes temperature sensors to monitor the environment and equipment temperature, and current sensors to monitor the power usage data of each load.

The working principle of the invention is as follows: the UPS power supply provides power output through the power supply module 20 on the base 10, the UPS module 30 is responsible for power management and switching, uninterrupted power supply is ensured, the wire winding assembly 40 is used for flexibly managing the winding and unwinding of cables, the movement and deployment of equipment are facilitated, the temperature sensor and the current sensor in the sensor module 50 monitor the environmental temperature and the power consumption data of each load in real time, and the data are transmitted to the intelligent control system so as to perform real-time analysis and adjust the power supply strategy; the stability and the high efficiency of the system under different environmental conditions are ensured, so that the system is suitable for various occasions, different power requirements are met, and the continuous power supply of key loads is ensured.

In this embodiment, the UPS power source further includes a track assembly 60, where the track assembly 60 is disposed on a lower end surface of the base 10, and is used to drive the UPS power source to move; the track assembly 60 includes two sets of track bodies 61 disposed at intervals, a first driving motor is disposed at one side of the track bodies 61, a storage space is disposed between the two sets of track bodies 61, and a folding ramp assembly 70 is disposed in the storage space.

It should be noted that this design allows the UPS power source to be flexibly moved over various terrains to accommodate different deployment environments. The storage space between track bodies 61 is used to accommodate folding ramp assembly 70, ensuring ease of transport and deployment of the apparatus.

In this embodiment, the folding ramp assembly 70 includes two folding ramps 71 arranged in parallel, and the two folding ramps 71 are connected by a telescopic hinge 72; the folding ramp 71 includes a body support plate 711, and first and second folding plates 712 and 713 rotatably coupled to both ends of the body support plate 711, respectively, one ends of the first and second folding plates 712 and 713 being provided with guide slopes 714, respectively.

One end of the first folding plate 712 and the second folding plate 713 is provided with a guide slope 714 to facilitate the unfolding and storage of the slope. This design enables the UPS power source to be quickly deployed when it needs to be handled, without the need for additional tools or equipment. The flexibility and ease of folding ramp assembly 70 improves the deployment efficiency of the UPS system, particularly in applications where frequent movement and adjustment are required, significantly enhancing the utility and ease of operation of the device.

In this embodiment, the winding assembly 40 includes a supporting frame 41, a reel 42 is rotatably connected to the supporting frame 41, and a second driving motor is disposed on one side of the reel 42; a pressing assembly is arranged below the reel 42, the pressing assembly comprises a pressing plate 43, a rotating shaft 44 is arranged at the first end of the pressing plate 43, and the pressing plate 43 is rotatably connected to the supporting frame 41 through the rotating shaft 44; wherein the second end of the compacting plate 43 is provided with an arc-shaped part for compacting the cable; the middle part of the compacting plate 43 is provided with a connecting shaft 45, the connecting shaft 45 is connected with a tension spring 46, one end of the tension spring 46 is connected with the supporting frame 41, and the tension spring 46 is used for pushing the compacting plate 43 to rotate towards the direction close to the reel 42.

The reel 42 rotates by the second driving motor to reel the cable; the pressing assembly is located below the reel 42 and comprises a pressing plate 43, one end of the pressing plate 43 is connected with the supporting frame 41 through a rotating shaft 44, and the other end of the pressing plate is provided with an arc-shaped portion for pressing the cable. The middle part of the compacting plate 43 is connected to the tension spring 46 through the connecting shaft 45, one end of the tension spring 46 is fixed on the supporting frame 41, and the other end pushes the compacting plate 43 to rotate towards the reel 42, so that the design ensures that the cable keeps proper tension and arrangement in the winding process, and the cable is prevented from winding and damaging. Through this structure, the winding assembly 40 can efficiently manage the winding and unwinding of the cable, improves the operation convenience of the device and the service life of the cable, and is suitable for application scenes of frequent movement and deployment.

Embodiment two:

the invention also provides an intelligent power supply method which is applied to the UPS according to the first embodiment, and comprises the following steps:

s1, configuring a temperature sensor and a current sensor on a UPS power supply, and respectively monitoring power utilization data of each load in a power utilization area in real time through the current sensor and acquiring temperature data of environment and equipment temperature through the temperature sensor;

and a temperature sensor and a current sensor are arranged on the UPS, the power consumption data of each load in the power consumption area are monitored in real time through the current sensor, and meanwhile, the temperature data of the environment and equipment are obtained through the temperature sensor. The configuration ensures the comprehensive monitoring of the running state of the system, and the electricity consumption and temperature data collected in real time provide a basis for subsequent intelligent regulation and control, so that the system is helped to respond to the changing load demands and environmental conditions in time.

S2, evaluating the load demand of the power utilization area by combining the power utilization data of each load, generating a load predicted value, and when the load predicted value exceeds or is lower than a preset power supply range, starting a power supply scheduling mechanism by the intelligent control system, adjusting the output power and a power supply path of the UPS module 30, and generating a power supply adjustment strategy; the process ensures reasonable distribution of power resources, avoids overload or insufficient power supply, and improves the response speed and the power supply efficiency of the system.

S3, carrying out temperature compensation on the load predicted value through temperature data to optimize a power supply adjustment strategy, and dynamically adjusting the power supply adjustment strategy according to the change condition of the temperature data;

and carrying out temperature compensation on the load predicted value through the temperature data so as to optimize a power supply adjustment strategy, and dynamically adjusting the power supply strategy according to the change condition of the temperature data. The temperature compensation considers the influence of the environment on the load, ensures the accuracy and adaptability of the power supply strategy, helps the system to keep stable operation under different temperature conditions, and improves the overall power supply reliability.

S4, controlling the crawler belt assembly 60 of the UPS power supply to adjust the position of the UPS power supply by the intelligent control system according to the power supply adjustment strategy so as to optimize the power supply path.

According to the power adjustment strategy, the intelligent control system controls the track assembly 60 to adjust the position of the UPS power source to optimize the power supply path. The UPS power supply can flexibly move in different occasions, ensures that the key load area always obtains preferential power supply, further improves the flexibility and the power supply efficiency of the system, and adapts to changeable power consumption requirements.

The working principle of the invention is as follows: according to the method, a temperature sensor and a current sensor are configured on a UPS power supply system, load electricity data and environment temperature data of an electricity consumption area are monitored in real time, an intelligent control system evaluates load demands to generate a load predicted value, when the load predicted value exceeds a preset power supply range, the system starts a power supply scheduling mechanism, the output power and a power supply path of a UPS module 30 are adjusted, and a power supply adjustment strategy is generated and dynamically optimized; controlling the track assembly 60 to adjust the position of the UPS power supply according to the optimized strategy so as to realize the optimization of the power supply path; through real-time monitoring and data analysis, intelligent power supply management of the UPS system is realized, the response capability and stability of the system are improved through temperature compensation and dynamic strategy adjustment, the power supply path is optimized, the power supply efficiency is improved, the power consumption requirements of different occasions are met, and the flexibility and the reliability of the system are enhanced.

In this embodiment, it is specifically described that step S2 specifically includes:

S21, collecting a power consumption data set of a current power consumption area through power consumption data of each load monitored in real time, and recording a power consumption change mode in a short period; through the step, accurate grasp of the electricity utilization trend is ensured, and a reliable data base is provided for subsequent analysis.

S22, carrying out trend analysis on the collected electricity data set by using a statistical analysis method to generate a load predicted value of the current electricity utilization area; by analyzing the electricity consumption mode, the system can identify electricity consumption peaks and valleys, forecast future electricity consumption demands and ensure the accuracy and timeliness of a power supply plan.

S23, comparing the generated load predicted value with a preset power supply range, and identifying the condition of insufficient power supply or overload.

And comparing the generated load predicted value with a preset power supply range, and identifying the condition of insufficient power supply or overload. The step is to quickly identify abnormal power supply through comparative analysis, ensure that the system can take measures in time and avoid power supply interruption or overload.

In this embodiment, it is further explained that step S23 further includes:

S24, according to the load predicted value, the intelligent control system calculates the total power demand of the electricity utilization area, evaluates the priority and the demand of each load, and identifies the key load and the secondary load; by priority evaluation, the system can preferentially ensure the power supply of the key load under the condition, and ensure the continuous operation of the core equipment.

S25, evaluating the available power capacity of the current UPS module 30 by combining the current data measured in real time and the total power demand; this step ensures that the system knows the current power supply capability, avoids overload operation, and improves the power supply safety.

S26, distributing output power of each load based on the power requirement of each load and the available power capacity of the UPS module 30, and adjusting a power supply path to generate a preliminary power supply adjustment strategy; by reasonably distributing power resources and optimizing a power supply path, the system improves the overall power supply efficiency and reliability.

S27, the preliminary power supply adjustment strategy is applied to the UPS module 30 through the intelligent control system, and the output power and the power supply path are adjusted in real time. And the power supply strategy is dynamically adjusted, stable power supply is maintained, and the power supply system is suitable for different power utilization environments.

In this embodiment, it is specifically described that step S3 specifically includes:

S31, analyzing the temperature data, determining the influence of temperature change on each load power, and calculating a temperature compensation value to correct a load predicted value;

and analyzing the temperature data, determining the influence of temperature change on each load power, and calculating a temperature compensation value to correct the load predicted value. By analyzing the effect of temperature on device performance, the system identifies load power fluctuations that may be caused by temperature changes.

S32, comparing the corrected load predicted value with the original value, and updating the load demand; the comparison analysis helps to identify the prediction deviation caused by the temperature factors, and the system updates the load demand accordingly, so that the power supply strategy can accurately reflect the current power utilization condition. This process ensures dynamic adjustment of the power supply plan, meeting the actual requirements.

And S33, the intelligent control system optimizes a power supply adjustment strategy according to the updated load demand, and dynamically adjusts the UPS output power and the power supply path to optimize the power supply adjustment strategy.

The system optimizes the power supply strategy according to the latest load demand, and ensures that each load is supplied with the adapted power. The output power and the power supply path are dynamically adjusted, so that the power supply efficiency and reliability are improved, and the stable operation of the system under various environmental conditions is ensured.

In this embodiment, it is further explained that step S4 further includes:

S5, providing real-time power supply state information and power supply strategy adjustment options through a user interface, receiving user input and feedback, and further optimizing a power supply adjustment strategy. And remote monitoring and management of the UPS system are realized.

The above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims

1. A UPS power source, comprising:

A base, a base seat and a base seat,

2. The UPS power source of claim 1 further comprising a track assembly disposed on a lower end face of the base for driving movement of the UPS power source;

3. The UPS of claim 2, wherein the folding ramp assembly includes two folding ramps disposed in parallel, the two folding ramps being connected by a telescoping hinge;

4. The UPS of claim 1, wherein the reel assembly includes a support frame, a reel rotatably connected to the support frame, and a second drive motor provided on one side of the reel;

5. A smart power supply method applied to the UPS power source as claimed in any one of claims 1 to 4, the smart power supply method comprising:

6. The intelligent power supply method according to claim 5, wherein the load demand of the power consumption area is evaluated in combination with the power consumption data of each load to generate the load prediction value, specifically comprising:

7. The intelligent power supply method according to claim 6, wherein the intelligent control system starts a power supply scheduling mechanism to adjust the output power and the power supply path of the UPS module, and generates a power supply adjustment policy, and specifically includes:

8. The intelligent power supply method according to claim 5, wherein the temperature compensation is performed on the load predicted value by the temperature data to optimize the power supply adjustment strategy, specifically comprising:

9. The intelligent power supply method according to claim 8, wherein the intelligent control system controls the track assembly of the UPS power source to adjust the position of the UPS power source to optimize the power supply path according to the power supply adjustment strategy, and further comprising: