CN216252272U

CN216252272U - Power transmission and distribution system electric power energy consumption monitoring and collecting device

Info

Publication number: CN216252272U
Application number: CN202122611277.6U
Authority: CN
Inventors: 李林; 朱晓明
Original assignee: Shidian Technology Jiangsu Co ltd
Current assignee: Shidian Technology Jiangsu Co ltd
Priority date: 2021-10-28
Filing date: 2021-10-28
Publication date: 2022-04-08
Anticipated expiration: 2031-10-28

Abstract

The utility model discloses a power transmission and distribution system power consumption monitoring and collecting device, which comprises a shell and a monitoring and collecting assembly, wherein the shell is provided with a plurality of monitoring and collecting modules; the top surface of the shell is provided with a power supply assembly, the two sides of the shell are symmetrically provided with heat dissipation assemblies, and a dehumidification assembly is arranged inside the shell; the monitoring acquisition assembly comprises a support, a current acquisition module, an electric energy metering module and a wireless communication module, the support is arranged on the inner bottom surface of the shell, and the current acquisition module, the electric energy metering module and the wireless communication module are all arranged on the surface of the support; the intelligent power supply device is characterized by further comprising a single chip microcomputer arranged on the side face of the shell, wherein the input end of the single chip microcomputer is electrically connected with the output ends of the current acquisition module and the electric energy metering module respectively, and the single chip microcomputer is electrically connected with the wireless communication module in a two-way mode. This transmission and distribution system electric power energy consumption monitoring collection system has better self-protection ability, can effectively prolong in open air life.

Description

Power transmission and distribution system electric power energy consumption monitoring and collecting device

Technical Field

The utility model relates to the technical field of power transmission and distribution, in particular to a power consumption monitoring and collecting device for a power transmission and distribution system.

Background

The section of the system from the outlet of the step-down distribution substation to the user side in the power system is called a distribution system, electric energy generated by the power generation system is transmitted through the transmission system and is finally distributed to each user by the distribution system, and in order to better know the transmission and distribution conditions of the electric power, energy consumption data need to be monitored and collected in real time in the transmission and distribution system.

Most of the existing electric power energy consumption monitoring and collecting devices of part of power transmission and distribution systems are installed outdoors, the self-protection capability is poor, and the lines are easy to age in high-temperature and humid environments for a long time, so that the service life is shortened. Therefore, the power consumption monitoring and collecting device for the power transmission and distribution system is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the existing defects and provides the power energy consumption monitoring and collecting device for the power transmission and distribution system, which has better self-protection capability, can effectively prolong the service life outdoors, has stronger practicability and can effectively solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a power transmission and distribution system power consumption monitoring and collecting device comprises a shell and a monitoring and collecting assembly;

the top surface of the shell is provided with a power supply assembly, the two sides of the shell are symmetrically provided with heat dissipation assemblies, and a dehumidification assembly is arranged inside the shell;

the monitoring and collecting assembly comprises a support, a current collecting module, an electric energy metering module and a wireless communication module, wherein the support is arranged on the inner bottom surface of the shell, and the current collecting module, the electric energy metering module and the wireless communication module are all arranged on the surface of the support;

the intelligent monitoring device is characterized by further comprising a single chip microcomputer, the single chip microcomputer is arranged on the side face of the shell, the input end of the single chip microcomputer is electrically connected with the output ends of the current acquisition module and the electric energy metering module respectively, the single chip microcomputer is electrically connected with the wireless communication module in a two-way mode, and the wireless communication module is wirelessly connected with an external monitoring terminal.

Further, the power supply assembly comprises a mounting rack, a solar panel, a solar controller, a storage battery and an inverter, the mounting rack is arranged on the top surface of the shell, the solar cell panels are symmetrically arranged on two sides of the top of the mounting rack, the solar controller, the storage battery and the inverter are all arranged on the top surface of the mounting rack, the input end of the solar controller is electrically connected with the output end of the solar panel, the output end of the solar controller is electrically connected with the input end of the storage battery, the output end of the storage battery is electrically connected with the output end of the inverter, and the output of dc-to-ac converter is connected with the input electricity of singlechip, and the usable solar cell panel of power supply unit converts solar energy into the electric energy, stores in the battery through solar controller, and the electric energy in the battery is carried for each load through the dc-to-ac converter, can realize independently supplying power.

Further, radiator unit includes side slot, mounting panel and heat dissipation fan, the both sides of casing are seted up to the side slot symmetry, the mounting panel inlays in the side slot, the heat dissipation fan is located on the mounting panel, and the air-out direction of heat dissipation fan outwards, the input of heat dissipation fan is connected with the output electricity of singlechip.

Further, radiator unit still includes ventiduct and protection network, the side of casing is located to the ventiduct, and the one end and the side channel of ventiduct correspond, the other end of ventiduct is located to the protection network, and the usable heat dissipation fan of radiator unit can discharge the inside heat of casing under the effect of ventilation pipe, realizes the heat dissipation, and under the effect in wind channel, can effectively reduce outside impurity and get into in the casing from heat dissipation fan, utilize the protection network can avoid outside insect impurity to get into.

Further, the dehumidification subassembly includes fixing base, electric heat bar, mount pad and temperature and humidity sensor, the medial surface of casing is located to the fixing base, the electric heat bar is located on the fixing base, the inside bottom surface of casing is located to the mount pad, temperature and humidity sensor locates on the mount pad, the input of electric heat bar is connected with the output electricity of singlechip, temperature and humidity sensor's output is connected with the input electricity of singlechip, and the dehumidification subassembly can be when temperature and humidity sensor monitors that casing internal humidity is higher, and the automatic start electric heat bar makes the inside intensification of casing, makes the inside moisture evaporation of casing, reduces humidity, utilizes radiator unit simultaneously, can discharge the casing with the vapor that produces to, when temperature and humidity sensor monitored the temperature is higher, can the work of automatic start heat dissipation fan.

Furthermore, still include ventilation pipe and dust screen, the top surface of casing is located to the ventilation pipe symmetry, the dust screen inlays in the top of ventilation pipe, and the ventilation cooling of casing inside can be realized to the ventilation pipe, utilizes the dust screen can avoid dust impurity to get into in the casing from the tuber pipe.

Based on the technical scheme, the utility model has the beneficial effects that:

1. the heat dissipation assembly can automatically dissipate heat in the shell when the temperature and humidity sensor monitors that the temperature in the shell is higher, the heat dissipation assembly can discharge the heat in the shell under the cooperation of the ventilation pipe to realize heat dissipation, external impurities can be effectively reduced from entering the shell from the heat dissipation fan under the action of the air duct, and the external insect impurities can be prevented from entering the shell by using the protective net;

2. the dehumidification assembly can automatically start the electric heating rod when the temperature and humidity sensor monitors that the humidity in the shell is higher, so that the temperature in the shell is raised, the moisture in the shell is evaporated, the humidity is reduced, meanwhile, the heat dissipation assembly can be used for discharging generated steam out of the shell, and in addition, when the temperature and humidity sensor monitors that the temperature is higher, the heat dissipation fan can be automatically started to work;

3. the usable solar cell panel of power supply unit converts solar energy into the electric energy, stores in the battery through solar controller, and the electric energy in the battery is carried for each load through the dc-to-ac converter, can realize independently supplying power, and is more energy-concerving and environment-protective, realizes the continuity monitoring simultaneously.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic diagram of the longitudinal cross-sectional structure of the present invention.

In the figure: 1. the solar energy dehumidification system comprises a shell, 11 parts of a single chip microcomputer, 12 parts of wire holes, 2 parts of a monitoring acquisition assembly, 21 parts of a support, 22 parts of a current acquisition module, 23 parts of an electric energy metering module, 24 parts of a wireless communication module, 3 parts of a power supply assembly, 31 parts of a mounting frame, 32 parts of a solar cell panel, 33 parts of a solar energy controller, 34 parts of a storage battery, 35 parts of an inverter, 4 parts of a ventilation pipe, 41 parts of a dustproof net, 5 parts of a heat dissipation assembly, 51 parts of side grooves, 52 parts of a mounting plate, 53 parts of a heat dissipation fan, 54 parts of a ventilation pipe, 55 parts of a protective net, 6 parts of a dehumidification assembly, 61 parts of a fixed seat, 62 parts of an electric heating rod, 63 parts of a mounting seat and 64 parts of a temperature and humidity sensor.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

As shown in fig. 1 to 3, the monitoring and collecting device for power consumption of the power transmission and distribution system provided by the present embodiment includes a housing 1 and a monitoring and collecting assembly 2; the device also comprises a singlechip 11 arranged on the side surface of the shell 1; the dust-proof device further comprises a ventilation pipe 4 and a dust-proof net 41, wherein the ventilation pipe 4 is symmetrically arranged on the top surface of the shell 1, and the dust-proof net 41 is embedded in the top of the ventilation pipe 4.

Wherein: casing 1's top surface is equipped with power supply unit 3, power supply unit 3 includes mounting bracket 31, solar cell panel 32, solar controller 33, battery 34 and inverter 35, mounting bracket 31 locates casing 1's top surface, mounting bracket 31's top both sides are located to solar cell panel 32 symmetry, solar controller 33, battery 34 and inverter 35 all locate mounting bracket 31's top surface, and solar controller 33's input is connected with solar cell panel 32's output electricity, solar controller 33's output is connected with battery 34's input electricity, battery 34's output is connected with inverter 35's output electricity, and inverter 35's output is connected with singlechip 11's input electricity.

The heat dissipation assembly 5 is symmetrically arranged on two sides of the shell 1, the heat dissipation assembly 5 comprises side grooves 51, mounting plates 52 and heat dissipation fans 53, the side grooves 51 are symmetrically arranged on two sides of the shell 1, the mounting plates 52 are embedded in the side grooves 51, the heat dissipation fans 53 are arranged on the mounting plates 52, the air outlet direction of the heat dissipation fans 53 faces outwards, and the input ends of the heat dissipation fans 53 are electrically connected with the output ends of the single chip microcomputer 11; the heat dissipation assembly 5 further includes an air duct 54 and a protection net 55, the air duct 54 is disposed on the side of the housing 1, one end of the air duct 54 corresponds to the side groove 51, and the protection net 55 is disposed at the other end of the air duct 54.

The dehumidifying component 6 is arranged in the shell 1, the dehumidifying component 6 comprises a fixed seat 61, an electric heating rod 62, a mounting seat 63 and a temperature and humidity sensor 64, the fixed seat 61 is arranged on the inner side surface of the shell 1, the electric heating rod 62 is arranged on the fixed seat 61, the mounting seat 63 is arranged on the inner bottom surface of the shell 1, the temperature and humidity sensor 64 is arranged on the mounting seat 63, the input end of the electric heating rod 62 is electrically connected with the output end of the single chip microcomputer 11, and the output end of the temperature and humidity sensor 64 is electrically connected with the input end of the single chip microcomputer 11;

wherein: the monitoring acquisition assembly 2 comprises a support 21, a current acquisition module 22, an electric energy metering module 23 and a wireless communication module 24, wherein the support 21 is arranged on the inner bottom surface of the shell 1, and the current acquisition module 22, the electric energy metering module 23 and the wireless communication module 24 are all arranged on the surface of the support 21; the input end of the single chip microcomputer 11 is respectively electrically connected with the output ends of the current acquisition module 22 and the electric energy metering module 23, the single chip microcomputer 11 is electrically connected with the wireless communication module 24 in a bidirectional mode, and the wireless communication module 24 is wirelessly connected with an external monitoring terminal. The current acquisition module 22 and the electric energy metering module 23 are respectively connected to the transmission and distribution circuit system, the data of a plurality of electric parameters such as voltage, current, power, electric energy and the like can be measured and acquired by using the current acquisition module 22, and the energy consumption in the transmission and distribution circuit can be monitored in real time by using the electric energy metering module 23.

The working principle of the utility model is as follows:

firstly, a current acquisition module 22 and an electric energy metering module 23 are respectively connected into a transmission and distribution circuit system, the current acquisition module 22 can be used for measuring and acquiring data of a plurality of electric parameters such as voltage, current, power, electric energy and the like, and the electric energy metering module 23 can be used for monitoring energy consumption in the transmission and distribution circuit in real time;

secondly, the solar panel 32 is utilized to convert solar energy into electric energy, the electric energy is stored in the storage battery 34 through the solar controller 33, the electric energy in the storage battery 34 is regulated and transmitted to each load through the inverter 35, and then autonomous power supply can be realized;

when the temperature and humidity sensor 64 monitors that the temperature in the casing 1 is high, the automatic heat dissipation fan 53 can discharge the heat in the casing 1 under the cooperation of the ventilation pipe 4 to realize heat dissipation, external impurities can be effectively reduced from entering the casing 1 from the heat dissipation fan 53 under the action of the air duct 54, and the external insect impurities can be prevented from entering by using the protective net 55;

when the temperature and humidity sensor 64 monitors that the humidity in the shell 1 is high, the electric heating rod 62 is automatically started to heat the inside of the shell, the moisture in the shell 1 is evaporated through heating, the humidity is reduced, and meanwhile, the generated water vapor can be discharged out of the shell 1 by utilizing the heat dissipation assembly 5.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a power transmission and distribution system electric power energy consumption monitoring collection system which characterized in that: comprises a shell (1) and a monitoring acquisition assembly (2);

the top surface of the shell (1) is provided with a power supply assembly (3), the two sides of the shell (1) are symmetrically provided with heat dissipation assemblies (5), and a dehumidification assembly (6) is arranged inside the shell (1);

the monitoring acquisition assembly (2) comprises a support (21), a current acquisition module (22), an electric energy metering module (23) and a wireless communication module (24), the support (21) is arranged on the inner bottom surface of the shell (1), and the current acquisition module (22), the electric energy metering module (23) and the wireless communication module (24) are arranged on the surface of the support (21);

still include singlechip (11), the side of casing (1) is located in singlechip (11), the input of singlechip (11) is connected with the output electricity of current acquisition module (22) and electric energy metering module (23) respectively, just singlechip (11) is connected with wireless communication module (24) both way electricity, wireless communication module (24) and outside monitoring terminal wireless connection.

2. The power consumption monitoring and collecting device of the power transmission and distribution system according to claim 1, characterized in that: power supply unit (3) are including mounting bracket (31), solar cell panel (32), solar control ware (33), battery (34) and inverter (35), the top surface of casing (1) is located in mounting bracket (31), the top both sides of mounting bracket (31) are located to solar cell panel (32) symmetry, the top surface of mounting bracket (31) is all located in solar control ware (33), battery (34) and inverter (35), and the input of solar control ware (33) is connected with the output electricity of solar cell panel (32), and the output of solar control ware (33) is connected with the input electricity of battery (34), the output of battery (34) is connected with the output electricity of inverter (35), and the output of inverter (35) is connected with the input electricity of singlechip (11).

3. The power consumption monitoring and collecting device of the power transmission and distribution system according to claim 1, characterized in that: radiator unit (5) are including side slot (51), mounting panel (52) and heat dissipation fan (53), the both sides in casing (1) are seted up to side slot (51) symmetry, mounting panel (52) inlay in side slot (51), heat dissipation fan (53) are located on mounting panel (52), and the air-out direction of heat dissipation fan (53) outwards, the input of heat dissipation fan (53) is connected with the output electricity of singlechip (11).

4. The power consumption monitoring and collecting device of the power transmission and distribution system according to claim 3, characterized in that: radiator unit (5) still include air channel (54) and protection network (55), the side of casing (1) is located in air channel (54), and the one end and the side groove (51) of air channel (54) correspond, the other end of air channel (54) is located in protection network (55).

5. The power consumption monitoring and collecting device of the power transmission and distribution system according to claim 1, characterized in that: dehumidification subassembly (6) are including fixing base (61), electric heat bar (62), mount pad (63) and temperature and humidity sensor (64), the medial surface of casing (1) is located in fixing base (61), electric heat bar (62) are located on fixing base (61), the inside bottom surface of casing (1) is located in mount pad (63), temperature and humidity sensor (64) are located on mount pad (63), the input of electric heat bar (62) is connected with the output electricity of singlechip (11), the output of temperature and humidity sensor (64) is connected with the input electricity of singlechip (11).

6. The power consumption monitoring and collecting device of the power transmission and distribution system according to claim 1, characterized in that: the dustproof cover is characterized by further comprising a ventilation pipe (4) and a dustproof net (41), wherein the ventilation pipe (4) is symmetrically arranged on the top surface of the shell (1), and the dustproof net (41) is embedded in the top of the ventilation pipe (4).