CN220120963U - Power supply monitoring hardware module - Google Patents

Abstract

The utility model discloses a power supply monitoring hardware module, which comprises a shell, wherein a control panel and a display screen are arranged on the inner side of the shell, the display screen is embedded on the front side wall of the shell, data communication is established between the control panel and the display screen, the display screen is convenient for human-computer interaction and data storage and viewing, an operator can intuitively and rapidly view the running state and running data of a battery through a display interface on the display screen, and the control panel acquires the relevant running data of the battery in real time and transmits the data to the display screen for display and interactive operation of the human-computer interface; the control panel is electrically connected with the voltage collector and the current collector, the voltage collector and the current collector are electrically connected with a power supply to be tested, the voltage collector and the current collector are respectively used for collecting the voltage and the current of the battery, a switching power supply is arranged between the control panel and the voltage collector, a switching power supply is arranged between the control panel and the current collector, and the switching power supply outputs the voltage and the current to realize the charging and repairing functions of the battery.

Description

Power supply monitoring hardware module

Technical Field

The utility model relates to the technical field of power supply detection, in particular to a power supply monitoring hardware module.

Background

With the increasing demand for power cells, the increasing amount of traffic is also becoming more and more important for the management of cells. At present, the supervision working procedure of the large-batch batteries stored among the batteries is still carried out in a traditional mode. That is, custodian regularly charges, inspects, supplements and carries the supervision behaviors such as the large batch battery of stock, and work is loaded down with trivial details and inefficiency, consumes a large amount of manpower and materials.

Disclosure of Invention

The present utility model is directed to a power monitoring hardware module, which solves the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the power supply monitoring hardware module comprises a shell, a control panel and a display screen are arranged on the inner side of the shell, the display screen is embedded on the front side wall of the shell, data communication is established between the control panel and the display screen, the display screen is convenient for human-computer interaction and data storage and viewing, an operator can intuitively and rapidly view the running state and running data of a battery through a display interface on the display screen, and the control panel acquires the relevant running data of the battery in real time and transmits the data to the display screen for display and interactive operation of the human-computer interface; the control panel is electrically connected with the voltage collector and the current collector, the voltage collector and the current collector are electrically connected with a power supply to be tested, the voltage collector and the current collector are respectively used for collecting the voltage and the current of the battery, a switching power supply is arranged between the control panel and the voltage collector, a switching power supply is arranged between the control panel and the current collector, and the switching power supply outputs voltage and current to realize the charging and repairing functions of the battery.

The hardware module is specially designed for single-path alternating current power supply electric energy management, can accurately measure three-phase current, power and electric power, and can give an alarm in time when the design capacity is reached. The method has the advantages of high reliability, strong pertinence, perfect management function, multi-serial communication, dry access point input and output signal detection and the like. The intelligent power distribution cabinet is particularly suitable for the requirements of power monitoring, power management and the like of various intelligent power distribution and alternating current power distribution cabinets. The device can measure voltage, current, electric power, power factor, reactive power, apparent power, reactive power and other parameters, and simultaneously provides various voltage and current harmonic waves for reference; 2 paths of main access point alarms and 1 path of alternating voltage switching value signals can be simultaneously accessed to provide 2 paths of 485 communication interfaces, and the communication protocol adopts a Modbus communication protocol, so that a great deal of labor cost can be saved.

Preferably, the auxiliary heating device further comprises an auxiliary heating element, the auxiliary heating element is controlled by the auxiliary heating switch, the auxiliary heating switch is disconnected, the auxiliary heating element stops working and is connected with the auxiliary heating switch, the auxiliary heating element is started, the auxiliary heating element can provide an ideal operation condition for equipment in a low-temperature environment, the low-temperature performance and reliability of the equipment are improved, if auxiliary heating function is not needed, the auxiliary heating switch can be disconnected, an auxiliary heating system is thoroughly stopped, energy consumption is reduced, and the auxiliary heating switch is opened in the environment needing the auxiliary heating function.

Preferably, a temperature control switch is arranged between the auxiliary heating element and the auxiliary heating switch, the temperature control switch is connected with the auxiliary heating element under the condition that the ambient temperature is lower than the set temperature, and is disconnected with the auxiliary heating element under the condition that the ambient temperature is higher than the set temperature, so that the working state of the auxiliary heating element is controllable, and the working state of the auxiliary heating element is automatically controlled according to the ambient temperature.

Preferably, the auxiliary heating element is a fan heater.

Preferably, the input power source is AC220V, and the input power source supplies power to the control panel, the display screen, the switching power supply and the auxiliary heating element through power lines.

Preferably, the input power supply is provided with a power circuit breaker and a power switch, the power circuit breaker realizes the protection function of the equipment, and once the equipment fails, overcurrent occurs, the power circuit breaker can automatically cut off the power switch to prevent further damage. The power switch can be disconnected by staff when the equipment is not used, so that the energy loss and the service life of the module are further optimized.

Preferably, the shell is uniformly provided with ventilation holes.

Compared with the prior art, the utility model has the beneficial effects that:

(1) The display screen is convenient for human-computer interaction and data storage and viewing, an operator can intuitively and rapidly view the running state and running data of the battery through a display interface on the display screen, and the control panel acquires the relevant running data of the battery in real time and sends the data to the display screen for display and interactive operation of the human-computer interface; the control panel is electrically connected with the voltage collector and the current collector, the voltage collector and the current collector are electrically connected with a power supply to be tested, the voltage collector and the current collector are respectively used for collecting the voltage and the current of the battery, a switching power supply is arranged between the control panel and the voltage collector, a switching power supply is arranged between the control panel and the current collector, and the switching power supply outputs the voltage and the current to realize the charging and repairing functions of the battery.

(2) The hardware module is specially designed for single-path alternating current power supply electric energy management, can accurately measure three-phase current, power and electric power, and can give an alarm in time when the design capacity is reached. The method has the advantages of high reliability, strong pertinence, perfect management function, multi-serial communication, dry access point input and output signal detection and the like. The intelligent power distribution cabinet is particularly suitable for the requirements of power monitoring, power management and the like of various intelligent power distribution and alternating current power distribution cabinets. The device can measure voltage, current, electric power, power factor, reactive power, apparent power, reactive power and other parameters, and simultaneously provides various voltage and current harmonic waves for reference; 2 paths of main access point alarms and 1 path of alternating voltage switching value signals can be simultaneously accessed to provide 2 paths of 485 communication interfaces, and the communication protocol adopts a Modbus communication protocol, so that a great deal of labor cost can be saved.

Drawings

FIG. 1 is a schematic view of the present utility model;

FIG. 2 is a circuit diagram of the present utility model;

FIG. 3 is a wiring diagram of the present utility model.

In the figure: 1-control panel, 2-display screen, 3-voltage collector, 4-current collector, 5-switching power supply, 6-auxiliary heating element, 7-auxiliary heating switch, 8-temperature control switch, 9-input power supply, 10-power circuit breaker, 11-power switch, 12-shell, 13-ventilation hole.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples: referring to fig. 1-3, the present utility model provides the following technical solutions: the power supply monitoring hardware module comprises a shell 12, a control panel 1 and a display screen 2 are arranged on the inner side of the shell 12, the display screen 2 is embedded on the front side wall of the shell 12, data communication is established between the control panel 1 and the display screen 2, the display screen 2 is convenient for human-computer interaction and data storage and viewing, an operator can intuitively and rapidly view the running state and running data of a battery through a display interface on the display screen 2, and the control panel 1 acquires relevant running data of the battery in real time and transmits the data to the display screen 2 for display and interactive operation of the human-computer interface; the control panel 1 is electrically connected with the voltage collector 3 and the current collector 4, the voltage collector 3 and the current collector 4 are electrically connected with a power supply to be tested, the voltage collector 3 and the current collector 4 are respectively used for collecting the voltage and the current of a battery, a switching power supply 5 is arranged between the control panel 1 and the voltage collector 3, a switching power supply 5 is arranged between the control panel 1 and the current collector 4, and the switching power supply 5 outputs voltage and current to realize the charging and repairing functions of the battery.

The hardware module is specially designed for single-path alternating current power supply electric energy management, can accurately measure three-phase current, power and electric power, and can give an alarm in time when the design capacity is reached. The method has the advantages of high reliability, strong pertinence, perfect management function, multi-serial communication, dry access point input and output signal detection and the like. The intelligent power distribution cabinet is particularly suitable for the requirements of power monitoring, power management and the like of various intelligent power distribution and alternating current power distribution cabinets. The device can measure voltage, current, electric power, power factor, reactive power, apparent power, reactive power and other parameters, and simultaneously provides various voltage and current harmonic waves for reference; 2 paths of main access point alarms and 1 path of alternating voltage switching value signals can be simultaneously accessed to provide 2 paths of 485 communication interfaces, and the communication protocol adopts a Modbus communication protocol, so that a great deal of labor cost can be saved.

Specifically, the auxiliary heating element 6 is controlled by the auxiliary heating switch 7, the auxiliary heating switch 7 is disconnected, the auxiliary heating element 6 stops working and is connected with the auxiliary heating switch 7, the auxiliary heating element 6 is started, the auxiliary heating element 6 can provide an ideal running condition for equipment in a low-temperature environment, the low-temperature performance and reliability of the equipment are improved, if auxiliary heating function is not needed, the auxiliary heating switch 7 can be disconnected, an auxiliary heating system is thoroughly stopped, energy consumption is reduced, and the auxiliary heating switch 7 is opened in the environment where the auxiliary heating function is needed.

Specifically, a temperature control switch 8 is disposed between the auxiliary heating element 6 and the auxiliary heating switch 7, the temperature control switch 8 is connected to the auxiliary heating element 6 under the condition that the ambient temperature is lower than the set temperature, and is disconnected from the auxiliary heating element 6 under the condition that the ambient temperature is higher than the set temperature, the working state of the auxiliary heating element 6 is controllable by the temperature control switch 8, and the working state of the auxiliary heating element 6 is automatically controlled according to the ambient temperature.

Specifically, the auxiliary heating element 6 is a fan heater.

Specifically, the input power supply 9 is AC220V, and the input power supply 9 supplies power to the control panel 1, the display screen 2, the switching power supply 5, and the auxiliary heating element 6 via power lines.

Specifically, the power breaker 10 and the power switch 11 are arranged at the input power supply 9, the power breaker 10 realizes the protection function of equipment, and once the equipment fails and overcurrent occurs, the power breaker 10 automatically cuts off the power switch 11 to prevent further damage. The power switch 11 can be turned off by a worker when the apparatus is not in use, further optimizing the energy consumption and the module lifetime.

Specifically, the housing 12 is uniformly provided with ventilation holes 13.

Working principle: the shell 12 is arranged, the control panel 1 and the display screen 2 are arranged on the inner side of the shell 12, the display screen 2 is embedded on the front side wall of the shell 12, data communication is established between the control panel 1 and the display screen 2, the display screen 2 is convenient for human-computer interaction and data storage and viewing, an operator can intuitively and rapidly view the running state and running data of a battery through a display interface on the display screen 2, and the control panel 1 acquires the relevant running data of the battery in real time and transmits the data to the display screen 2 for display and interactive operation of the human-computer interface; the control panel 1 is electrically connected with the voltage collector 3 and the current collector 4, the voltage collector 3 and the current collector 4 are electrically connected with a power supply to be tested, the voltage collector 3 and the current collector 4 are respectively used for collecting the voltage and the current of a battery, the switching power supply 5 is arranged between the control panel 1 and the voltage collector 3, the switching power supply 5 is arranged between the control panel 1 and the current collector 4, and the switching power supply 5 outputs voltage and current to realize the charging and repairing functions of the battery.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (7)

1. The power monitoring hardware module, its characterized in that: including shell (12), shell (12) inboard is provided with control panel (1) and display screen (2), display screen (2) are inlayed on the preceding lateral wall of shell (12), control panel (1) with establish data communication between display screen (2), control panel (1) are connected with voltage collector (3) and current collector (4) electricity, voltage collector (3) with current collector (4) all are connected with the power electricity that awaits measuring, control panel (1) with set up switching power supply (5) between voltage collector (3), control panel (1) with set up switching power supply (5) between current collector (4).

2. The power monitoring hardware module of claim 1, wherein: the solar energy heating device is characterized by further comprising an auxiliary heating element (6), wherein the auxiliary heating element (6) is controlled by an auxiliary heating switch (7), the auxiliary heating switch (7) is disconnected, the auxiliary heating element (6) stops working and is connected with the auxiliary heating switch (7), and the auxiliary heating element is started.

3. The power monitoring hardware module of claim 2, wherein: a temperature control switch (8) is arranged between the auxiliary heating element (6) and the auxiliary heating switch (7), the auxiliary heating element (6) is connected under the condition that the ambient temperature is lower than the set temperature, and the auxiliary heating element is disconnected under the condition that the ambient temperature is higher than the set temperature.

4. A power monitoring hardware module according to claim 2 or 3, characterized in that: the auxiliary heating element (6) is a warm air blower.

5. A power monitoring hardware module according to claim 3, wherein: the input power supply (9) is AC220V, and the input power supply (9) supplies power to the control panel (1), the display screen (2), the switching power supply (5) and the auxiliary heating element (6) through power lines.

6. The power monitoring hardware module of claim 5, wherein: the input power supply (9) is provided with a power circuit breaker (10) and a power switch (11).

7. The power monitoring hardware module of claim 6, wherein: the shell (12) is uniformly provided with ventilation holes (13).