CN115090571A - Wisdom fortune dimension electric power monitored control system - Google Patents

Abstract

The invention relates to the technical field of intelligent operation and maintenance, and discloses an intelligent operation and maintenance electric power monitoring system, wherein a supporting structure comprises a supporting tube, the left side of the supporting tube is fixedly connected with a control box, the inner bottom wall of the control box is fixedly connected with a motor, the output shaft of the motor is fixedly connected with a rotating rod, the right end of the rotating rod is provided with a transmission belt, the inside of the supporting tube is movably connected with a coupling rod, the right side of the coupling rod is fixedly connected with a first helical gear, the inner bottom wall of the supporting tube is movably connected with a rotating rod, and the outer side of the bottom end of the rotating rod is fixedly connected with a second helical gear. This wisdom fortune dimension electric power monitored control system has set up the limiting plate in the left side of control body, has set up the semicircle board in the inside of limiting plate, has set up perpendicular gear in the left side of semicircle board, has set up the runner on the right side of intermediate lamella, runner and frid top swing joint, perpendicular gear and frid top meshing have set up telescopic cylinder at the back of frid.

Description

Wisdom fortune dimension electric power monitored control system

Technical Field

The invention relates to the technical field of intelligent operation and maintenance, in particular to an intelligent operation and maintenance power monitoring system.

Background

The intelligent traffic is a traffic-oriented service system which fully utilizes modern electronic information technologies such as Internet of things, cloud computing, artificial intelligence, automatic control, mobile internet and the like in the traffic field, and on the basis of the intelligent traffic, the technology of internet of things, cloud computing, internet, artificial intelligence, automatic control, mobile internet and the like is fully applied in the traffic field, the traffic information is collected through high and new technology, the traffic system carries out management and control support on all aspects of traffic fields such as traffic management, transportation, public trip and the like and the whole process of traffic construction management, so that the traffic system has the capabilities of perception, interconnection, analysis, prediction, control and the like in areas and cities or even in a larger space-time range, the method fully ensures traffic safety, exerts the efficiency of traffic infrastructure, improves the operation efficiency and the management level of a traffic system, and provides services for smooth public and sustainable economic development.

At present, some intelligent operation and maintenance power monitoring systems cannot be well cleaned when stains appear on monitoring equipment, and therefore an intelligent operation and maintenance power monitoring system is urgently needed.

Disclosure of Invention

In order to achieve the purpose, the invention provides the following technical scheme: an intelligent operation and maintenance power monitoring system comprises a supporting structure, wherein a cleaning structure is arranged at the top of the supporting structure;

the supporting structure comprises a supporting pipe, a control box is fixedly connected to the left side of the supporting pipe, a motor is fixedly connected to the bottom wall of the control box, a rotating rod is fixedly connected to an output shaft of the motor, a transmission belt is arranged at the right end of the rotating rod, a linkage rod is movably connected to the inside of the supporting pipe, a first helical gear is fixedly connected to the right side of the linkage rod, a rotating rod is movably connected to the inner bottom wall of the supporting pipe, and a second helical gear is fixedly connected to the outer side of the bottom end of the rotating rod;

the clearance structure includes the roof, roof bottom fixedly connected with riser, the positive fixedly connected with telescopic cylinder of riser, telescopic cylinder openly is fixed with the frid, roof bottom fixedly connected with control board, control board bottom fixed mounting has the control body, control body left side fixedly connected with limiting plate, the inside swing joint of limiting plate has the semicircle board, roof bottom fixedly connected with intermediate lamella, the perpendicular gear of semicircle board right side fixedly connected with, intermediate lamella right side swing joint has the runner.

Preferably, the semicircular plate comprises a spring hole, a spring is arranged in the spring hole, a supporting rod is fixedly connected to one end of the spring, and a cleaning plate is fixedly connected to one side, far away from the spring, of the supporting rod.

Preferably, one side of the spring, which is far away from the supporting rod, is fixedly connected with the bottom of the spring hole, and one side of the cleaning plate, which is far away from the supporting rod, is lapped with the outer side of the monitoring body.

The spring hole is formed in the semicircular plate, the spring is arranged in the spring hole, the supporting rod is arranged on one side of the spring, the cleaning plate is arranged at the other end of the supporting rod and is in lap joint with the outer side of the monitoring body, and when the semicircular plate moves, stains on the surface can be well cleaned between the cleaning plate and the semicircular plate.

Preferably, the number of the supporting rods is multiple, and the supporting rods are symmetrically distributed inside the semicircular plate.

Preferably, the top end of the rotating rod penetrates through the top of the support tube and extends to the outer side of the top of the support tube, the top end of the rotating rod is fixedly connected with the bottom of the top plate, and the top of the top plate is convex.

Preferably, the circular rod at the right end of the semicircular plate penetrates through the middle plate and extends to the right side of the middle plate, and the circular rod at the right side of the semicircular plate is movably connected with the inside of the middle plate.

Preferably, the bottom of the groove plate is provided with tooth marks, and the vertical gear is meshed with the tooth marks at the bottom of the groove plate.

Preferably, the top of the groove plate is provided with a groove, and the rotating wheel is movably connected with the groove at the top of the groove plate.

An operation method of an intelligent operation and maintenance power monitoring system comprises the following operation steps:

when the monitoring angle is rotated:

s1: primary signal transmission: the server transmits the signal to a receiving block;

s2: secondary signal transmission: the receiving block receives a signal to control the motor to operate;

s3: and (3) starting to work: the motor operates to control the rotation of the rotating rod of the transmission belt, and the top plate and the monitoring body rotate along with the rotation of the rotating rod;

when the monitoring outer side needs to be cleaned:

s1; primary signal transmission: the server transmits the signal to the monitoring detection equipment;

s2: and (3) detection: the monitoring detection equipment detects whether stains exist on the outer side of the monitoring equipment;

s3: secondary signal transmission: if the dirt exists, starting the telescopic cylinder to work, and if the dirt does not exist, returning a signal to the server;

s4: and (3) return signal transmission: and after cleaning, carrying out secondary detection, if no stain exists, returning a signal to the server, and if the stain also exists, carrying out secondary cleaning.

Compared with the prior art, the invention provides an intelligent operation and maintenance power monitoring system, which has the following beneficial effects:

1. this wisdom fortune dimension electric power monitored control system, bottom through at the roof has set up the riser, intermediate lamella and control board, bottom at the control board has set up the control body, the limiting plate has been set up in the left side of control body, the semicircle board has been set up in the inside of limiting plate, the vertical gear has been set up in the left side of semicircle board, right side at the intermediate lamella has set up the runner, runner and frid top swing joint, vertical gear and frid top meshing, telescopic cylinder has been set up at the back of frid, telescopic cylinder activity drives frid seesaw, because the effect of meshing, it is semicircle back and forth movement to drive the semicircle board, the convenience is cleared up control body surface.

2. This wisdom fortune dimension electric power monitored control system, control box has been set up through the left side at the stay tube, motor has been set up in the inside of control box, the dwang has been set up at the output of motor, drive belt has been set up at the right-hand member of dwang, the drive belt other end has set up the trace, helical gear has been set up No. one at the right-hand member of trace, the bull stick has been set up in the inside of stay tube, helical gear No. two in the bottom outside of bull stick, helical gear and No. two helical gear intermeshing, the top of bull stick has set up the roof, when needs angle regulation, starter motor, drive belt drives the trace and a helical gear rotates, make bull stick and roof rotate thereupon, the effect of convenient adjustment control visual angle has been reached.

3. This wisdom fortune dimension electric power monitored control system has set up the spring hole through the inside at the semicircle board, has set up the spring in the inside in spring hole, has set up the support rod in one side of spring, has set up the cleaning plate at the other end of support rod, the outside overlap joint of cleaning plate and control body, and the semicircle board is when the motion, can be fine between cleaning plate and the semicircle board clear up surperficial spot, has reached the effect of convenient clearance.

Drawings

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

FIG. 2 is a front view of the present invention;

FIG. 3 is a schematic view of the interior of the support tube according to the present invention;

FIG. 4 is an enlarged view of the structure at A in the drawings of the present invention;

FIG. 5 is a schematic view of the telescopic cylinder of the present invention;

FIG. 6 is a schematic view of the construction of the trough plate of the present invention;

FIG. 7 is a schematic view of a semicircular plate structure according to the present invention;

FIG. 8 is a schematic view of the inner structure of the semicircular plate according to the present invention;

FIG. 9 is a schematic view of the engagement structure of the vertical gear and the bottom of the slot plate according to the present invention;

FIG. 10 is a diagram of the steps of the method of operation of the present invention.

Wherein: 1. a support structure; 101. supporting a tube; 102. a control box; 103. a motor; 104. rotating the rod; 105. a drive belt; 106. a linkage rod; 107. a first bevel gear; 108. a rotating rod; 109. a second bevel gear; 2. cleaning the structure; 201. a top plate; 202. a vertical plate; 203. a telescopic cylinder; 204. a groove plate; 205. a monitor board; 206. monitoring the body; 207. a limiting plate; 208. a semicircular plate; 209. a middle plate; 210. a vertical gear; 211. a rotating wheel; 2081. a spring hole; 2082. a spring; 2083. a support rod; 2084. and (6) cleaning the plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1-10, an intelligent operation and maintenance power monitoring system includes a supporting structure 1, a cleaning structure 2 disposed on the top of the supporting structure 1;

example one

Embodiment of support structure of intelligent operation and maintenance power monitoring system

Specifically, the supporting structure 1 comprises a supporting tube 101, a control box 102 is fixedly connected to the left side of the supporting tube 101, a motor 103 is fixedly connected to the bottom wall of the control box 102, an output shaft of the motor 103 is fixedly connected with a rotating rod 104, a transmission belt 105 is arranged at the right end of the rotating rod 104, a linkage rod 106 is movably connected inside the supporting tube 101, a first helical gear 107 is fixedly connected to the right side of the linkage rod 106, a rotating rod 108 is movably connected to the bottom wall of the supporting tube 101, and a second helical gear 109 is fixedly connected to the outer side of the bottom end of the rotating rod 108;

specifically, the top end of the rotating rod 108 penetrates through the top of the support tube 101 and extends to the outside of the top of the support tube 101, the top end of the rotating rod 108 is fixedly connected with the bottom of the top plate 201, and the top of the top plate 201 is convex.

Through the technical scheme, the internal circuit connection of the motor 103 is the prior art, the motor is an external power supply, the electrifying effect is mainly operated through a receiving block inside the control box 102, the signal connection is the prior art, the linkage rod 106 is positioned inside the support pipe 101, the transmission belt 105 is positioned inside the support pipe 101, the linkage rod 106 is positioned inside the support pipe 101, the transmission belt 105 can completely drive the rotation rod 108 to move by the pulling force of the transmission belt 105, the rotation rod 108 can well rotate inside the support pipe 101, the control box 102 is arranged on the left side of the support pipe 101, the motor 103 is arranged inside the control box 102, the rotation rod 104 is arranged at the output end of the motor 103, the transmission belt 105 is arranged at the right end of the rotation rod 104, the linkage rod 106 is arranged at the other end of the transmission belt 105, the first helical gear 107 is arranged at the right end of the linkage rod 106, the rotation rod 108 is arranged inside the support pipe 101, a second bevel gear 109 is arranged on the outer side of the bottom end of the rotating rod 108, the first bevel gear 107 is meshed with the second bevel gear 109, a top plate 201 is arranged at the top end of the rotating rod 108, when the angle needs to be adjusted, the motor 103 is started, and the transmission belt 105 drives the rotating rod 104 and the first bevel gear 107 to rotate, so that the rotating rod 108 and the top plate 201 rotate along with the rotating rod.

Example two

Embodiment of cleaning structure of intelligent operation and maintenance power monitoring system

Specifically, clearance structure 2 includes roof 201, roof 201 bottom fixedly connected with riser 202, riser 202 is the flexible cylinder 203 of fixedly connected with openly, flexible cylinder 203 is openly fixed with frid 204, roof 201 bottom fixedly connected with control board 205, control board 205 bottom fixed mounting has control body 206, control body 206 left side fixedly connected with limiting plate 207, the inside swing joint of limiting plate 207 has semicircle board 208, roof 201 bottom fixedly connected with intermediate lamella 209, semicircle board 208 right side fixedly connected with erects gear 210, intermediate lamella 209 right side swing joint has runner 211.

Specifically, a round rod at the right end of the semicircular plate 208 penetrates through the middle plate 209 and extends to the right side of the middle plate 209, and the round rod at the right side of the semicircular plate 208 is movably connected with the inside of the middle plate 209.

Specifically, the bottom of the groove plate 204 is provided with teeth marks, and the vertical gear 210 is meshed with the teeth marks at the bottom of the groove plate 204.

Through the technical scheme, the internal circuit connection of the telescopic cylinder 203 is the prior art, the telescopic cylinder is mainly controlled by a monitoring system in the control box 102, the signal transmission is the prior art, the number of tooth marks arranged at the bottom of the groove plate 204 can well control the vertical gear 210 to rotate, the number of tooth marks arranged on the vertical gear 210 can just enable the semicircular plate 208 to move in a circular plate back and forth manner, the calibration technology is the prior art, the bottom of the top plate 201 is provided with the vertical plate 202, the middle plate 209 and the monitoring plate 205, the bottom of the monitoring plate 205 is provided with the monitoring body 206, the left side of the monitoring body 206 is provided with the limiting plate 207, the semicircular plate 208 is arranged in the limiting plate 207, the vertical gear 210 is arranged at the left side of the semicircular plate 208, the right side of the middle plate 209 is provided with the rotating wheel 211, the rotating wheel 211 is movably connected with the top of the groove plate 204, the vertical gear 210 is meshed with the top of the groove plate 204, set up telescopic cylinder 203 at the back of frid 204, telescopic cylinder 203 activity drives frid 204 seesaw, because the effect of meshing drives semicircle board 208 and is semicircle back and forth movement, conveniently clears up control body 206 surface.

EXAMPLE III

Embodiment of semicircular plate of intelligent operation and maintenance power monitoring system

Specifically, the semicircular plate 208 includes a spring hole 2081, a spring 2082 is disposed in the spring hole 2081, one end of the spring 2082 is fixedly connected with a support rod 2083, and one side of the support rod 2083, which is far away from the spring 2082, is fixedly connected with a cleaning plate 2084.

Specifically, one side of the spring 2082, which is far away from the support rod 2083, is fixedly connected with the bottom of the spring hole 2081, and one side of the cleaning plate 2084, which is far away from the support rod 2083, is in lap joint with the outer side of the monitoring body 206.

Specifically, a plurality of support bars 2083 are provided, and a plurality of support bars 2083 are symmetrically disposed inside the semicircular plate 208.

Specifically, the top of the groove plate 204 is provided with a groove, and the rotating wheel 211 is movably connected with the groove at the top of the groove plate 204.

Through the technical scheme, the spring hole 2081 is formed in the semicircular plate 208, the spring 2082 is formed in the spring hole 2081, the supporting rod 2083 is arranged on one side of the spring 2082, the cleaning plate 2084 is arranged at the other end of the supporting rod 2083, the cleaning plate 2084 is in lap joint with the outer side of the monitoring body 206, the semicircular plate 208 can well clean stains on the surface between the cleaning plate 2084 and the semicircular plate 208 when moving, the cleaning plate 2084 is made of soft materials, and the materials of the cleaning plate 2084 are in the prior art.

Example four

Embodiment of operation method of intelligent operation and maintenance power monitoring system

Specifically, the operation steps are as follows:

when rotating the monitoring angle:

s1: primary signal transmission: the server transmits the signal to a receiving block;

s2: secondary signal transmission: the receiving block receives a signal to control the motor to operate;

s3: and (3) starting to work: the motor operates to control the rotation of the rotating rod of the transmission belt, and the top plate and the monitoring body rotate along with the rotation of the rotating rod;

when the monitoring outer side needs to be cleaned:

s1; primary signal transmission: the server transmits the signal to the monitoring detection equipment;

s2: and (3) detection: the monitoring detection equipment detects whether stains exist on the outer side of the monitoring equipment;

s3: secondary signal transmission: if the dirt exists, starting the telescopic cylinder to work, and if the dirt does not exist, returning a signal to the server;

s4: and (3) return signal transmission: and after cleaning, carrying out secondary detection, if no stain exists, returning a signal to the server, and if the stain also exists, carrying out secondary cleaning.

Through the technical scheme, signal transmission is prior art in the above-mentioned operating procedure, the staff makes receipt piece control motor 103 circular telegram through server transmission signal, make dwang 104 drive driving belt 105 motion, drive a helical gear 107 and No. two helical gears 109 motion, make bull stick 108 and roof 201 rotate, stop supplying power to motor 103 when adjusting suitable position, then when needs go on to the clearance in the control body 206 outside, start telescopic cylinder 203 and make frid 204 seesaw, it is semicircle back and forth movement to drive semicircle board 208, semicircle board 208 one side has set up cleaning plate 2084 and has conveniently cleared up it.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides an intelligence fortune dimension electric power monitored control system, includes bearing structure (1), its characterized in that: the top of the supporting structure (1) is provided with a cleaning structure (2);

the supporting structure (1) comprises a supporting pipe (101), a control box (102) is fixedly connected to the left side of the supporting pipe (101), a motor (103) is fixedly connected to the inner bottom wall of the control box (102), an output shaft of the motor (103) is fixedly connected with a rotating rod (104), a transmission belt (105) is arranged at the right end of the rotating rod (104), a linkage rod (106) is movably connected to the inside of the supporting pipe (101), a first helical gear (107) is fixedly connected to the right side of the linkage rod (106), a rotating rod (108) is movably connected to the inner bottom wall of the supporting pipe (101), and a second helical gear (109) is fixedly connected to the outer side of the bottom end of the rotating rod (108);

clearance structure (2) are including roof (201), roof (201) bottom fixedly connected with riser (202), riser (202) are the flexible cylinder of fixedly connected with (203) openly, flexible cylinder (203) openly are fixed with frid (204), roof (201) bottom fixedly connected with control board (205), control board (205) bottom fixed mounting has control body (206), control body (206) left side fixedly connected with limiting plate (207), the inside swing joint of limiting plate (207) has semicircle board (208), roof (201) bottom fixedly connected with intermediate plate (209), semicircle board (208) right side fixedly connected with erects gear (210), intermediate plate (209) right side swing joint has runner (211).

2. The intelligent operation and maintenance power monitoring system of claim 1, wherein: semicircle board (208) include spring hole (2081), spring (2082) are provided with in spring hole (2081), spring (2082) one end fixedly connected with supports pole (2083), support pole (2083) keep away from spring (2082) one side fixedly connected with clearance board (2084).

3. The intelligent operation and maintenance power monitoring system according to claim 2, wherein: one side, far away from the supporting rod (2083), of the spring (2082) is fixedly connected with the bottom of the spring hole (2081), and one side, far away from the supporting rod (2083), of the cleaning plate (2084) is in lap joint with the outer side of the monitoring body (206).

4. The intelligent operation and maintenance power monitoring system of claim 2, wherein: the number of the support rods (2083) is multiple, and the support rods (2083) are symmetrically distributed inside the semicircular plate (208).

5. The intelligent operation and maintenance power monitoring system of claim 1, wherein: the top end of the rotating rod (108) penetrates through the top of the supporting pipe (101) and extends to the outer side of the top of the supporting pipe (101), the top end of the rotating rod (108) is fixedly connected with the bottom of the top plate (201), and the top of the top plate (201) is convex.

6. The intelligent operation and maintenance power monitoring system of claim 1, wherein: semicircle board (208) right-hand member round bar runs through intermediate lamella (209) and extends to intermediate lamella (209) right side, semicircle board (208) right side round bar and intermediate lamella (209) inside swing joint.

7. The intelligent operation and maintenance power monitoring system of claim 1, wherein: the bottom of the groove plate (204) is provided with tooth marks, and the vertical gear (210) is meshed with the tooth marks at the bottom of the groove plate (204).

8. The intelligent operation and maintenance power monitoring system of claim 1, wherein: the top of the groove plate (204) is provided with a groove, and the rotating wheel (211) is movably connected with the groove at the top of the groove plate (204).

9. An operation method of an intelligent operation and maintenance power monitoring system is characterized in that: the method comprises the following operation steps: when rotating the monitoring angle:

s1: primary signal transmission: the server transmits the signal to a receiving block;

s2: secondary signal transmission: the receiving block receives a signal to control the motor to operate;

s3: and (3) starting to work: the motor operates to control the rotation of the rotating rod of the transmission belt, and the top plate and the monitoring body rotate along with the rotation of the rotating rod;

when the monitoring outer side needs to be cleaned:

s1; primary signal transmission: the server transmits the signal to the monitoring detection equipment;

s2: and (3) detection: the monitoring detection equipment detects whether stains exist on the outer side of the monitoring equipment;

s3: secondary signal transmission: if the dirt exists, starting the telescopic cylinder to work, and if the dirt does not exist, returning a signal to the server;

s4: and (3) return signal transmission: and after cleaning, carrying out secondary detection, if no stain exists, returning a signal to the server, and if the stain also exists, carrying out secondary cleaning.

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