CN218162614U - High-efficient intelligent distribution monitoring device - Google Patents

Abstract

The utility model discloses a high-efficiency intelligent power distribution monitoring device, which comprises a power distribution monitoring assembly, wherein the power distribution monitoring assembly comprises a monitoring casing, a supporting frame, a dust cover, a monitoring body and an electric cabinet; the auxiliary cleaning mechanism comprises a speed reducing motor, a gear ring, a driving motor, a limiting groove, an arc-shaped plate body and bristles; and a monitoring machine body is arranged at the bottom of the inner side wall of the monitoring machine shell. The utility model discloses a driving motor drives arc plate body and brush hair and rotates around the dust cover, then utilizes the gear to drive the ring gear through gear motor and rotate, and the pivoted ring gear drives the dust cover and rotates, and the pivoted dust cover utilizes the brush hair to scrub its surperficial adhesion's dust to avoided the dust to cause the influence to the light transmissivity of dust cover, guaranteed monitoring effect, and need not the staff and manually clean, made the clean mode more intelligent, made the utility model discloses can efficient control.

Description

High-efficient intelligent distribution monitoring device

The technical field is as follows:

the utility model relates to a distribution substation monitors technical field, specifically is a high-efficient intelligent distribution monitoring device.

Background art:

the so-called power distribution station receives, distributes, controls and protects the electric energy, does not transform the electric energy, and the transformer station and the power distribution station are important components of the power grid, and the rationality of the design has obvious influence on the improvement of the power supply quality; meanwhile, the intelligent monitoring equipment is also a very common and very important work in engineering construction, the standardization and the technology are very strong, and the intelligent monitoring equipment of the power distribution station mainly monitors images in the power distribution room through a monitoring probe so as to find various faults in the power distribution room in time;

traditional intelligent distribution monitoring equipment of distribution station is when using, the dust in the distribution room is very easy adhesion on supervisory equipment's dust cover to lead to distribution supervisory equipment to be after long-time use, the light transmissivity of dust cover reduces along with the increase of the volume of adhesion dust gradually, and then has influenced the monitoring effect, and supervisory equipment installs the eminence usually, increased the manual clear degree of difficulty of staff to the dust cover, for this reason, provide a high-efficient intelligent distribution monitoring device.

The utility model has the following contents:

an object of the utility model is to provide a high-efficient intelligent distribution monitoring device to solve one of the problem that proposes in the above-mentioned background art.

The utility model discloses implement by following technical scheme: an efficient intelligent power distribution monitoring device comprises

The power distribution monitoring assembly comprises a monitoring shell, a supporting frame, a dust cover, a monitoring machine body and an electric cabinet;

the auxiliary cleaning mechanism comprises a speed reducing motor, a gear ring, a driving motor, a limiting groove, an arc-shaped plate body and bristles;

the utility model discloses a monitoring machine for the internal wall of motor, including control casing, gear motor, driving motor's output shaft fixed connection, the inside wall of control casing is installed to the inside wall bottom of control casing, the bottom cover of control casing is equipped with the dust cover, the one end fixedly connected with ring gear of dust cover, the inside wall of ring gear rotates through the bearing and connects in the inside wall of control casing, the top meshing of ring gear is connected with the gear, gear motor is installed to outside wall one side of control casing, gear motor's output shaft fixed connection is in one side of gear, driving motor is installed to the outside wall opposite side of control casing, driving motor's output shaft runs through inside wall and the fixedly connected with arc plate body of control casing, the inside wall fixedly connected with brush hair of arc plate body.

As further preferable in the present technical solution: the limiting groove has been seted up to the bottom of control casing, the lateral wall sliding connection of arc plate body is in the inside wall of limiting groove, the lateral wall one side of arc plate body articulates in inside wall one side of limiting groove through the pivot.

As further preferable in the present technical solution: the top of the inner side wall of the monitoring casing is fixedly connected with an electric cabinet, and the top of the outer side wall of the monitoring casing is fixedly connected with a support frame.

As further preferable in the present technical solution: the monitoring device comprises a monitoring shell and is characterized in that a detection box is fixedly connected to one side of the outer side wall of the monitoring shell, and a temperature and humidity sensor is installed in the middle of one side of the detection box.

As further preferable in the present technical solution: the lower surface mid-mounting of detection case has outer light intensity sensor, the PLC controller is installed to inside wall one side of electric cabinet, the relay is evenly installed to the inside wall opposite side of electric cabinet.

As further preferable in the present technical solution: an infrared thermal imaging probe is installed on one side of the monitoring machine body, and an internal illuminance sensor is installed at the bottom of the monitoring machine body.

As a further preferred aspect of the present invention: the signal output ends of the monitoring body, the infrared thermal imaging probe, the internal illuminance sensor, the temperature and humidity sensor and the external illuminance sensor are electrically connected to the signal input end of the PLC through a lead.

As a further preferred aspect of the present invention: the electrical output end of the PLC controller is electrically connected to the electrical input end of the relay through a wire, and the electrical output end of the relay is electrically connected to the electrical input ends of the speed reducing motor and the driving motor through a wire.

The utility model has the advantages that: the utility model discloses an outer light intensity sensor and interior light intensity sensor are poor to the light intensity data detection and calculate light transmissivity data, when the data difference that detects is greater than the threshold value, drive arc plate body and brush hair around the dust cover rotation through PLC controller intelligent control driving motor, then utilize the gear to drive the ring gear rotation through gear motor, the pivoted ring gear drives the dust cover and rotates, the pivoted dust cover utilizes the brush hair to scrub its surperficial adhesion's dust, thereby avoided the dust to cause the influence to the light transmissivity of dust cover, the monitoring effect has been guaranteed, and it is manual clean to need not the staff, make clean mode more intelligent, make the utility model discloses can the efficient control.

Description of the drawings:

in order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a half-section structure of the present invention;

FIG. 3 is a schematic side sectional view of the present invention;

fig. 4 is a schematic view of the monitoring body of the present invention.

In the figure: 1. a power distribution monitoring assembly; 2. an auxiliary cleaning mechanism; 101. monitoring the housing; 102. a support frame; 103. a dust cover; 104. monitoring the machine body; 105. an electric cabinet; 201. a reduction motor; 202. a gear; 203. a toothed ring; 204. a drive motor; 205. a limiting groove; 206. an arc-shaped plate body; 207. brushing; 41. a PLC controller; 42. a relay; 43. an internal illuminance sensor; 44. a detection box; 45. a temperature and humidity sensor; 46. an infrared thermal imaging probe; 47. an external illuminance sensor.

The specific implementation mode is as follows:

the technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

Referring to fig. 1-4, the present invention provides a technical solution: an efficient intelligent power distribution monitoring device comprises

The power distribution monitoring assembly 1 comprises a monitoring shell 101, a supporting frame 102, a dust cover 103, a monitoring machine body 104 and an electric cabinet 105;

the auxiliary cleaning mechanism 2 comprises a speed reducing motor 201, a gear 202, a toothed ring 203, a driving motor 204, a limiting groove 205, an arc-shaped plate body 206 and bristles 207;

monitoring machine body 104 is installed to the inside wall bottom of control casing 101, the bottom cover of monitoring machine body 104 is equipped with dust cover 103, the one end fixedly connected with ring gear 203 of dust cover 103, the inside wall of ring gear 203 rotates through the bearing and connects in the inside wall of control casing 101, the top meshing of ring gear 203 is connected with gear 202, gear motor 201 is installed to outside wall one side of control casing 101, gear motor 201's output shaft fixed connection is in one side of gear 202, driving motor 204 is installed to the outside wall opposite side of control casing 101, driving motor 204's output shaft runs through inside wall and the fixedly connected with arc plate body 206 of control casing 101, the inside wall fixedly connected with brush hair 207 of arc plate body 206.

In this embodiment, specifically: a limit groove 205 is formed at the bottom of the monitoring casing 101, the outer side wall of the arc-shaped plate body 206 is connected to the inner side wall of the limit groove 205 in a sliding manner, and one side of the outer side wall of the arc-shaped plate body 206 is hinged to one side of the inner side wall of the limit groove 205 through a rotating shaft; the arc-shaped plate body 206 is accommodated and limited through the limiting groove 205, and the interference of the arc-shaped plate body 206 and the brush bristles 207 on the monitoring image of the monitoring machine body 104 is avoided.

In this embodiment, specifically: the top of the inner side wall of the monitoring shell 101 is fixedly connected with an electric cabinet 105, and the top of the outer side wall of the monitoring shell 101 is fixedly connected with a support frame 102; the monitoring housing 101 is installed at a designated position in the distribution room by bolts through the support bracket 102.

In this embodiment, specifically: a detection box 44 is fixedly connected to one side of the outer side wall of the monitoring casing 101, and a temperature and humidity sensor 45 is installed in the middle of one side of the detection box 44; the temperature and humidity data in the power distribution room are detected by the temperature and humidity sensor 45.

In this embodiment, specifically: an external illuminance sensor 47 is installed in the middle of the lower surface of the detection box 44, a PLC controller 41 is installed on one side of the inner side wall of the electric cabinet 105, a relay 42 is evenly installed on the other side of the inner side wall of the electric cabinet 105, an infrared thermal imaging probe 46 is installed on one side of the monitoring machine body 104, an internal illuminance sensor 43 is installed at the bottom of the monitoring machine body 104, the infrared thermal imaging probe 46, the internal illuminance sensor 43, the signal output ends of the temperature and humidity sensor 45 and the external illuminance sensor 47 are electrically connected to the signal input end of the PLC controller 41 through wires, the electrical output end of the PLC controller 41 is electrically connected to the electrical input end of the relay 42 through wires, and the electrical output end of the relay 42 is electrically connected to the electrical input ends of the speed reducing motor 201 and the driving motor 204 through wires; the PLC controller 41 receives data from the monitoring body 104, the infrared thermal imaging probe 46, the internal illuminance sensor 43, the temperature and humidity sensor 45, and the external illuminance sensor 47, and the relay 42 controls the on/off of the reduction motor 201 and the driving motor 204.

In this embodiment, specifically: the PLC controller 41 is DF-96D in model; the models of the inner illuminance sensor 43 and the outer illuminance sensor 47 are TBQ-6; the temperature and humidity sensor 45 is model ZW-ST100.

Working principle or structural principle: when the intelligent monitoring cabinet is used, the monitoring shell 101 is installed at a designated position in the power distribution room through the support frame 102 by using bolts, then image data of the power distribution room is collected through the monitoring body 104, infrared image data in the power distribution room is collected through the infrared thermal imaging probe 46, so that workers can quickly find an unknown heat source in the power distribution room by using infrared thermal imaging, then temperature and humidity data in the power distribution room are detected through the temperature and humidity sensor 45, then the data of the monitoring body 104, the temperature and humidity sensor 45 and the infrared thermal imaging probe 46 are received through the PLC 41, the data are transmitted to a remote control terminal through the PLC 41 by using a wire, so that the workers can check the monitoring image data, the infrared thermal imaging data and the temperature and humidity data in the power distribution room, and then the illuminance data in the power distribution room are detected through the external illuminance sensor 47, then, the illuminance data in the dust cover 103 is detected by the internal illuminance sensor 43, then the PLC controller 41 receives the data detected by the external illuminance sensor 47 and the internal illuminance sensor 43 and calculates a data difference, so as to determine the light transmittance of the currently monitored machine body 104 according to the data difference, when the detected data difference is greater than a threshold value, the PLC controller 41 starts the reduction motor 201 and the driving motor 204 by using the relay 42, the output shaft of the driving motor 204 drives the arc-shaped plate 206 to move around the dust cover 103, the moving arc-shaped plate 206 drives the bristles 207 to move, then the output shaft of the reduction motor 201 drives the gear 202 to rotate, the rotating gear 202 drives the dust cover 103 to rotate by using the toothed ring 203, the rotating dust cover 103 brushes the dust adhered to the surface by using the bristles 207, thereby avoiding the influence of the dust on the light transmittance of the dust cover 103, guaranteed the monitoring effect, and it is clean to need not the staff hand, make clean mode more intelligent, cleaning efficiency has been improved, when the data difference that detects is less than the threshold value, utilize relay 42 to close gear motor 201 through PLC controller 41, make dust cover 103 stall, and restart driving motor 204 work, driving motor 204's output shaft drives arc plate body 206 reverse motion, thereby withdraw arc plate body 206 the inside of spacing groove 205, the monitoring image of arc plate body 206 and brush hair 207 to monitoring organism 104 has been avoided causing the interference.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. An efficient intelligent power distribution monitoring device is characterized by comprising

The power distribution monitoring assembly (1), the power distribution monitoring assembly (1) comprises a monitoring shell (101), a supporting frame (102), a dust cover (103), a monitoring machine body (104) and an electric cabinet (105);

the auxiliary cleaning mechanism (2) comprises a speed reducing motor (201), a gear (202), a gear ring (203), a driving motor (204), a limiting groove (205), an arc-shaped plate body (206) and bristles (207);

monitor organism (104) is installed to the inside wall bottom of control casing (101), the bottom cover of control organism (104) is equipped with dust cover (103), one end fixedly connected with ring gear (203) of dust cover (103), the inside wall of ring gear (203) passes through the bearing and rotates to be connected in the inside wall of control casing (101), the top meshing of ring gear (203) is connected with gear (202), gear motor (201) is installed to the lateral wall one side of control casing (101), the output shaft fixed connection of gear motor (201) is in one side of gear (202), driving motor (204) are installed to the lateral wall opposite side of control casing (101), the output shaft of driving motor (204) runs through inside wall and the fixedly connected with arc plate body (206) of control casing (101), the inside wall fixedly connected with brush hair (207) of arc plate body (206).

2. The efficient intelligent power distribution monitoring device according to claim 1, wherein: the bottom of control casing (101) has seted up spacing groove (205), the lateral wall sliding connection of arc plate body (206) is in the inside wall of spacing groove (205), lateral wall one side of arc plate body (206) articulates in inside wall one side of spacing groove (205) through the pivot.

3. The efficient intelligent power distribution monitoring device of claim 1, wherein: the top of the inner side wall of the monitoring shell (101) is fixedly connected with an electric cabinet (105), and the top of the outer side wall of the monitoring shell (101) is fixedly connected with a support frame (102).

4. The efficient intelligent power distribution monitoring device of claim 1, wherein: the outer side wall of the monitoring casing (101) is fixedly connected with a detection box (44), and a temperature and humidity sensor (45) is installed in the middle of one side of the detection box (44).

5. The efficient intelligent power distribution monitoring device of claim 4, wherein: the lower surface mid-mounting of detection case (44) has outer illuminance sensor (47), PLC controller (41) are installed to the inside wall one side of electric cabinet (105), relay (42) are evenly installed to the inside wall opposite side of electric cabinet (105).

6. The efficient intelligent power distribution monitoring device of claim 5, wherein: one side of the monitoring body (104) is provided with an infrared thermal imaging probe (46), and the bottom of the monitoring body (104) is provided with an internal illuminance sensor (43).

7. The efficient intelligent power distribution monitoring device of claim 6, wherein: the signal output ends of the monitoring machine body (104), the infrared thermal imaging probe (46), the internal illuminance sensor (43), the temperature and humidity sensor (45) and the external illuminance sensor (47) are electrically connected to the signal input end of the PLC (41) through a lead.

8. The efficient intelligent power distribution monitoring device of claim 5, wherein: the electrical output end of the PLC (41) is electrically connected to the electrical input end of the relay (42) through a wire, and the electrical output end of the relay (42) is electrically connected to the electrical input ends of the speed reducing motor (201) and the driving motor (204) through wires.

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