CN218825193U - Power communication rack temperature self-adaptation control device - Google Patents

Abstract

The application provides a power communication rack temperature self-adaptation control device, including shell, toper line concentration device, control command output interface, power input interface, external signal input interface, integrated control integrated circuit board, signal processing module, power module, temperature control module, temperature sensing processing module, scalable temperature sensor and data storage module, wherein: the integrated control board card, the signal processing module, the power module, the temperature control module, the temperature sensing processing module, the telescopic temperature sensor and the data storage module are arranged in the shell. Through the application of this application, can effectively solve traditional mode temperature control unreasonable, not energy-conserving and effect subalternation problem to reduce the communication abnormity and the life-span damage that improper temperature control caused in the electric power communication rack.

Description

Power communication rack temperature self-adaptation control device

Technical Field

The application relates to the technical field of power equipment design, in particular to a temperature self-adaptive control device for a power communication cabinet.

Background

With the deep construction of smart grids and novel power systems, the requirements on the safe operation capacity and reliability of power communication equipment and facilities are higher and higher. Due to the increase of the scale of the power system, the data volume and the information volume of power production, operation, monitoring, dispatching and management are also increased by times, so that certain heat can be emitted by power communication equipment in the operation process, the temperature in a communication cabinet is too high or exceeds the standard, the stable operation of the power communication equipment is influenced, and even abnormal communication, equipment damage and power accidents occur.

Traditional electric power communication rack mainly realizes the control of temperature through the radiating mode of the continuous power frequency operation of small-size fan in the rack, but its effect is relatively poor, and breaks down and damages easily for long-time continuous operation. The traditional cabinet internal temperature control mode cannot respond to the change of the cabinet internal temperature constantly, is not reasonable, is not energy-saving and environment-friendly, and influences the performance and the service life of the current power communication equipment.

SUMMERY OF THE UTILITY MODEL

The application provides a power communication cabinet temperature self-adaptive control device to solve the problem that the traditional power communication cabinet internal temperature control mode can not respond to the change of the cabinet internal temperature all the time, is neither reasonable nor energy-saving and environment-friendly, and influences the performance and the service life of the current power communication equipment.

The application provides a power communication rack temperature self-adaptation control device, including shell, toper line concentration device, control command output interface, power input interface, external signal input interface, integrated control integrated circuit board, signal processing module, power module, temperature control module, temperature sensing processing module, scalable temperature sensor and data storage module, wherein:

the integrated control board card, the signal processing module, the power module, the temperature control module, the temperature sensing processing module, the telescopic temperature sensor and the data storage module are arranged inside the shell.

Optionally, the shape of toper line concentration device is the narrow cone-shaped body in preceding wide back, the material of toper line concentration device is plastics, control command output interface, power input interface and external signal input interface have been inlayed to the front end of toper line concentration device, control command output interface's shape is the rectangle, power input interface's shape is circular, external signal input interface's shape is the square.

Optionally, the left side of the integrated control board is provided with a signal processing module, a power supply module and a data storage module, the central position of the integrated control board is provided with a temperature control module, and the right side of the temperature control module is provided with a temperature sensing processing module.

Optionally, the number of the telescopic temperature sensors is two, the two telescopic temperature sensors are respectively fixed on the upper side and the lower side of the integrated control board card, and the telescopic temperature sensors can extend outwards from the right holes of the shell.

Optionally, the retractable temperature sensor is configured to collect temperature data in the cabinet in real time, transmit the temperature data to the temperature sensing processing module for processing, transmit the temperature data to the temperature control module for arithmetic processing, generate processed information and control instructions, and output the processed information and control instructions through the tapered line concentrator to drive the external fan or the heat dissipation device.

Optionally, the data storage module is configured to store the in-cabinet temperature data acquired by the telescopic temperature sensor, the information processed by the temperature sensing processing module, and the control instruction processed by the temperature control module in real time.

The flow of the adaptive control of the temperature of the electric power communication cabinet is as follows: the temperature data in the electric power communication cabinet is collected in real time through two sets of telescopic temperature sensors, then the temperature data are sent to the temperature sensing processing module and the temperature control module, the temperature sensing processing module and the temperature control module upload the real-time temperature data to the data storage module for storage, meanwhile, the real-time temperature data are processed through the signal processing module, the processed real-time temperature data are sent to the conical wire collecting device, the conical wire collecting device is connected with the power supply module and supplies power to the power supply module, the conical wire collecting device outputs the processed real-time temperature data to the external power supply, the external fan or the heat dissipation device, and therefore the temperature in the cabinet is effectively controlled, the problems that the traditional mode is unreasonable in temperature control, energy is not saved, the effect is poor and the probability of communication abnormity, service life damage and the like caused by improper temperature control in the electric power communication cabinet is reduced.

According to the technical scheme provided above, the application provides a power communication rack temperature self-adaptation control device, including shell, toper line concentration device, control command output interface, power input interface, external signal input interface, integrated control integrated circuit board, signal processing module, power module, temperature control module, temperature sensing processing module, scalable temperature sensor and data storage module, wherein: the integrated control board card, the signal processing module, the power module, the temperature control module, the temperature sensing processing module, the telescopic temperature sensor and the data storage module are arranged inside the shell.

According to the power communication cabinet temperature self-adaptive control device, the temperature in the cabinet is collected in real time through the temperature sensing processing module, and real-time temperature data are transmitted to the temperature control module; the temperature control module performs operation according to the conditions of amplitude, temperature rise rate and the like of temperature change in the cabinet and sends a control instruction to the heat dissipation or control device according to an operation result; the heat dissipation device automatically adjusts power based on the instruction of the temperature control module, so that the temperature in the cabinet is effectively controlled. Through the application of this application, can effectively solve traditional mode temperature control unreasonable, not energy-conserving and effect subalternation problem to reduce the communication abnormity and the life-span damage that improper temperature control caused in the electric power communication rack.

Drawings

In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic overall structural diagram of a temperature adaptive control device for an electric power communication cabinet provided in the present application;

fig. 2 is a schematic diagram of a connection relationship between modules of a temperature adaptive control device for an electric power communication cabinet provided in the present application.

Illustration of the drawings:

the device comprises a device shell, a 2-conical line concentration device, a 3-control instruction output interface, a 4-power input interface, a 5-external signal input interface, a 6-integrated control board card, a 7-signal processing module, an 8-power module, a 9-temperature control module, a 10-temperature sensing processing module, an 11-telescopic temperature sensor and a 12-data storage module.

Detailed Description

Reference will now be made in detail to embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following examples do not represent all embodiments consistent with the present application. But merely as exemplifications of systems and methods consistent with certain aspects of the application, as recited in the claims.

A power communication cabinet is a freestanding or self-supporting enclosure for housing electrical or electronic equipment. Power communication cabinets are typically configured with doors, removable or non-removable side panels and back panels. The power communication cabinet is an indispensable component in electrical equipment, is a carrier of electrical control equipment, and is generally made of cold-rolled steel plates or alloys. Can provide the protection functions of water resistance, dust prevention, electromagnetic interference resistance and the like for the storage equipment. For the electrical equipment itself, the power communication cabinet also has an important auxiliary function as the UPS power supply, and a good power communication cabinet means that the electrical equipment can be ensured to operate in a good environment. Therefore, the power communication cabinet plays an important role, and systematically solves the difficult problems of high-density heat dissipation, large-amount cable attachment and management, high-capacity power distribution and comprehensive compatibility of rack-mounted equipment of different manufacturers in the application of electrical equipment, so that the electrical equipment can operate in a high-stability environment.

The self-adaptive temperature control device for the power communication cabinet has the remarkable advantages of simple process, good temperature control effect, wide application range, low manufacturing cost, environmental protection and the like, has self-adaptive control function, can automatically, quickly and accurately control the temperature according to the change of the amplitude and the temperature rise rate of the temperature in the cabinet, and also has the advantages of energy conservation and environmental protection.

The power dispatching communication cabinet can be used for a power dispatching communication cabinet, a transformer substation communication cabinet, a distribution room communication cabinet and a general communication cabinet, and can also be used for power automation, information networks or secondary equipment cabinets. Through the application of the device, the problems that the temperature control is unreasonable, energy is not saved, the effect is poor and the like in the traditional mode can be effectively solved, and communication abnormity, service life damage and the like caused by improper temperature control in the power communication cabinet are reduced.

Referring to fig. 1, for the overall structure schematic diagram of the temperature adaptive control device for the power communication cabinet provided by the present application, the overall structure schematic diagram includes a housing 1, a tapered line concentrator 2, a control instruction output interface 3, a power input interface 4, an external signal input interface 5, an integrated control board card 6, a signal processing module 7, a power module 8, a temperature control module 9, a temperature sensing processing module 10, a scalable temperature sensor 11, and a data storage module 12, wherein:

the conical line concentrator 2, the control instruction output interface 3, the power input interface 4 and the external signal input interface 5 are arranged outside the shell 1, and the integrated control board card 6, the signal processing module 7, the power module 8, the temperature control module 9, the temperature sensing processing module 10, the telescopic temperature sensor 11 and the data storage module 12 are arranged inside the shell 1.

Further, the shape of toper concentrator 2 is the taper body that the back is narrow wide before, the material of toper concentrator 2 is plastics, control command output interface 3, power input interface 4 and external signal input interface 5 have been inlayed to the front end of toper concentrator 2, control command output interface 3's shape is the rectangle, power input interface 4's shape is circular, external signal input interface 5's shape is the square.

The shape of the tapered concentrator 2 helps to amplify the signal, making the signal transmission of the present application more stable.

Further, the left side of the integrated control board 6 is provided with a signal processing module 7, a power supply module 8 and a data storage module 12, the center of the integrated control board 6 is provided with a temperature control module 9, and the right side of the temperature control module 9 is provided with a temperature sensing processing module 10.

Furthermore, the number of the telescopic temperature sensors 11 is two, the two telescopic temperature sensors 11 are respectively fixed on the upper side and the lower side of the integrated control board card 6, and the telescopic temperature sensors 11 can extend outwards from the right holes of the shell 1.

Two sets scalable temperature sensor 11's setting makes this application can monitor temperature everywhere in the electric power communication rack comprehensively, and more comprehensive to the temperature grasp in the cabinet, the adaptive control instruction of making accords with the demand of electric power communication rack more.

Further, the telescopic temperature sensor 11 is configured to collect temperature data in the cabinet in real time, transmit the temperature data to the temperature sensing processing module 10 for processing, transmit the temperature data to the temperature control module 9 for arithmetic processing, generate processed information and control instructions, and output the processed information and control instructions through the tapered line concentrator 2 to drive an external fan or a heat dissipation device.

This application gathers the temperature data in the electric power communication rack through two sets of scalable temperature sensor 11 in real time, sends temperature data for temperature sensing processing module 10 and temperature control module 9 afterwards, temperature sensing processing module 10 and temperature control module 9 are handled real-time temperature data through signal processing module 7, and the real-time temperature data who will handle the completion sends to toper collection line device 2, toper collection line device 2 is connected with power module 8, is its power supply through power module 8, toper collection line device 2 exports the real-time temperature data who handles the completion to external power source, external fan or heat abstractor.

Further, the data storage module 12 is configured to store, in real time, the in-cabinet temperature data acquired by the telescopic temperature sensor 11, the information processed by the temperature sensing processing module 10, and the control instruction processed by the temperature control module 9.

The temperature sensing processing module 10 and the temperature control module 9 upload the real-time temperature data to the data storage module 12 for storage, so that the safety of the data is ensured.

Referring to fig. 2, for a schematic diagram of a module connection relationship of a temperature adaptive control device of an electric power communication cabinet provided by the present application, a flow of performing the temperature adaptive control of the electric power communication cabinet according to the present application is as follows: the temperature data in the electric power communication cabinet is collected in real time through two sets of telescopic temperature sensors 11, then the temperature data are sent to a temperature sensing processing module 10 and a temperature control module 9, the temperature sensing processing module 10 and the temperature control module 9 upload the real-time temperature data to a data storage module 12 for storage, meanwhile, the real-time temperature data are processed through a signal processing module 7, the processed real-time temperature data are sent to a conical wire concentration device 2, the conical wire concentration device 2 is connected with a power module 8 and supplies power to the power module 8, and the conical wire concentration device 2 outputs the processed real-time temperature data to an external power supply, an external fan or a heat dissipation device, so that the temperature in the cabinet is effectively controlled, the problems that the traditional mode temperature control is unreasonable, energy is not saved, the effect is poor and the like are solved, and the probability of communication abnormity, service life damage and the like caused by improper temperature control in the electric power communication cabinet is reduced.

The electric power communication cabinet temperature monitoring system can also have the functions of overtemperature short message warning or acousto-optic warning and the like, namely the telescopic temperature sensor 11 can acquire temperature data in the electric power communication cabinet, when the temperature data is sent to the temperature sensing processing module 10 and the temperature control module 9, the temperature sensing processing module 10 judges that the temperature in the cabinet exceeds the warning threshold value at the moment, and the signal processing module 7 processes the real-time temperature data and outputs warning information to the warning module. The method for outputting the alarm information is not limited, and the alarm information can be sent to the mobile terminal of the user in a short message mode or can be directly reminded of the user in an acousto-optic mode.

The application provides a power communication rack temperature self-adaptation controlling means includes shell 1, toper concentrator 2, control command output interface 3, power input interface 4, external signal input interface 5, integrated control integrated circuit board 6, signal processing module 7, power module 8, temperature control module 9, temperature sensing processing module 10, scalable temperature sensor 11 and data storage module 12, wherein: the conical line concentrator 2, the control instruction output interface 3, the power input interface 4 and the external signal input interface 5 are arranged outside the shell 1, and the integrated control board card 6, the signal processing module 7, the power module 8, the temperature control module 9, the temperature sensing processing module 10, the telescopic temperature sensor 11 and the data storage module 12 are arranged inside the shell 1.

According to the self-adaptive control device for the temperature of the power communication cabinet, the temperature in the cabinet is collected in real time through the temperature sensing processing module 10, and real-time temperature data are transmitted to the temperature control module 9; the temperature control module 9 performs calculation according to the conditions of the amplitude of the temperature change in the cabinet, the temperature rise rate and the like, and sends a control instruction to the heat dissipation or control device according to the calculation result; the heat dissipation device automatically adjusts power based on the instruction of the temperature control module, so that the temperature in the cabinet is effectively controlled. Through the application of this application, can effectively solve traditional mode temperature control unreasonable, not energy-conserving and effect subalternation problem to reduce the probability that communication abnormality and life-span damage scheduling problem that the improper temperature control caused in the electric power communication rack appear.

It should be noted that the structures, ratios, sizes, and the like shown in the drawings attached to the present specification are only used for matching the disclosure of the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions that the present application can be implemented, so that the present application has no technical essence, and any structural modification, ratio relationship change, or size adjustment should still fall within the scope of the disclosure of the present application without affecting the efficacy and the achievable purpose of the present application. In addition, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for clarity of description, and are not intended to limit the scope of the application, and changes or modifications in the relative relationship may be made without substantial technical changes, and may be regarded as the scope of the application.

While there have been shown and described what are at present considered to be the fundamental principles and essential features of the application, and advantages thereof, it will be apparent to those skilled in the art that the application is not limited to the details of the foregoing illustrative embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present specification describes embodiments, not every embodiment includes only a single embodiment, and such description is for clarity purposes only, and it is to be understood that all embodiments may be combined as appropriate by one of ordinary skill in the art to form other embodiments as will be apparent to those of skill in the art from the description herein.

The embodiments provided in the present application are only a few examples of the general concept of the present application, and do not limit the scope of the present application. Any other embodiments extended according to the scheme of the present application without inventive efforts will be within the scope of protection of the present application for a person skilled in the art.

Claims (6)

1. The utility model provides a power communication rack temperature adaptive control device, its characterized in that includes shell (1), toper concentrator (2), control command output interface (3), power input interface (4), external signal input interface (5), integrated control integrated circuit board card (6), signal processing module (7), power module (8), temperature control module (9), temperature sensing processing module (10), scalable temperature sensor (11) and data storage module (12), wherein:

the cone-shaped concentrator is characterized in that the cone-shaped concentrator (2), the control instruction output interface (3), the power input interface (4) and the external signal input interface (5) are arranged outside the shell (1), and the integrated control board card (6), the signal processing module (7), the power module (8), the temperature control module (9), the temperature sensing processing module (10), the telescopic temperature sensor (11) and the data storage module (12) are arranged inside the shell (1).

2. The adaptive control device for the temperature of the power communication cabinet according to claim 1,

the shape of toper concentrator (2) is the narrow conical body in preceding wide back, the material of toper concentrator (2) is plastics, control command output interface (3), power input interface (4) and external signal input interface (5) have been inlayed to the front end of toper concentrator (2), the shape of control command output interface (3) is the rectangle, the shape of power input interface (4) is circular, the shape of external signal input interface (5) is the square.

3. The adaptive control device for the temperature of the power communication cabinet according to claim 1,

the left side of integrated control integrated circuit board (6) is equipped with signal processing module (7), power module (8) and data storage module (12), the central point of integrated control integrated circuit board (6) puts and is equipped with temperature control module (9), the right side of temperature control module (9) is equipped with temperature sensing processing module (10).

4. The adaptive control device for the temperature of the power communication cabinet according to claim 1,

the number of the telescopic temperature sensors (11) is two, the two telescopic temperature sensors (11) are respectively fixed on the upper side and the lower side of the integrated control board (6), and the telescopic temperature sensors (11) can extend outwards from the right hole of the shell (1).

5. The adaptive control device for the temperature of the power communication cabinet according to claim 1,

the telescopic temperature sensor (11) is configured to collect temperature data in the cabinet in real time, transmit the temperature data to the temperature sensing processing module (10) for processing, transmit the temperature data to the temperature control module (9) for operation processing, generate processed information and control instructions, and output the processed information and control instructions outwards through the conical line concentrating device (2) to drive an external fan or a heat dissipation device.

6. The adaptive control device for the temperature of the power communication cabinet according to claim 1,

the data storage module (12) is configured to store the in-cabinet temperature data collected by the telescopic temperature sensor (11), the information processed by the temperature-sensing processing module (10) and the control instruction processed by the temperature control module (9) in real time.

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