CN113265986A - Hydraulic engineering 5G information transmission state monitoring device and transmission display system - Google Patents

Abstract

The invention provides a hydraulic engineering 5G information transmission state monitoring device and a transmission display system thereof, which comprises a dam body, wherein the bottom of the dam body is provided with a plurality of support columns for supporting an operation platform, two support columns are arranged in a group to form a gate opening, the operation platform corresponding to the top of the gate opening is provided with a brake opening motor and a control console, the bottom of the brake opening motor is provided with a connecting screw rod extending into the gate opening, one side of each support column facing away from the interior of the dam is provided with a water baffle plate for reinforcing the strength of the support column, a monitoring cable for monitoring water flow is arranged between the water baffle plates, the inner side of each support column is provided with a gate groove, a telescopic locking block for locking and transmitting signals is arranged in the gate groove, and a gate is movably connected in the gate groove simultaneously, and the problem of insufficient convenience and rapidness in control reaction of hydraulic engineering.

Description

Hydraulic engineering 5G information transmission state monitoring device and transmission display system

Technical Field

The invention relates to the field of hydraulic engineering, in particular to a hydraulic engineering 5G information transmission state monitoring device and a transmission display system thereof.

Background

Water is a valuable resource essential to human production and life, and with the improvement of the infrastructure level of China, the more the civil water conservancy projects are, such as large water conservancy projects of three gorges dam and the like, the larger the civil water conservancy projects are, flood disasters are effectively prevented and controlled, and the water resource distribution required by the life of people is met.

But as hydraulic engineering is bigger, dam staff need consume more time in daily overhaul, maintenance and operation to lead to the reduction of working time, lead to the problem of reducing dam maintenance quality, and can't control dam flood discharge or the problem of operation of damming in time under emergency.

Disclosure of Invention

In order to solve the technical problems, the invention provides a hydraulic engineering 5G information transmission state monitoring device and a transmission display system thereof, which are used for solving the problems of low working efficiency when the maintenance is not timely due to long distance in work such as daily maintenance of large-scale hydraulic engineering and the like, and the problem of insufficient, convenient and rapid control reaction of the hydraulic engineering.

The invention relates to a hydraulic engineering 5G information transmission state monitoring device and a transmission display system thereof, which achieve the purpose and the effect by the following specific technical means: a hydraulic engineering 5G information transmission state monitoring device comprises a dam body bottom provided with a plurality of support columns for supporting an operation platform, wherein two support columns are in a group and form a gate opening, the operation platform corresponding to the top of the gate opening is provided with a brake opening motor and a control console, the bottom of the brake opening motor is provided with a connecting screw rod extending into the gate opening, one side of each support column, facing away from the interior of the dam, is provided with a water baffle plate for reinforcing the strength of the support column, a monitoring cable for monitoring water flow is arranged between the water baffle plates, the inner side of each support column is provided with a gate groove, a telescopic locking block for locking and transmitting signals is arranged in each gate groove, a gate is movably connected in each gate groove, the two sides of each gate are provided with transmission locking grooves matched with the telescopic locking blocks, the center of the inner side of the dam is provided with a monitoring groove and a monitoring limiting groove, and a water detector capable of moving up and down is movably connected in each monitoring groove and the monitoring limiting groove, and the bottom of the gate is provided with a rotating shaft which can rotate by utilizing water flow.

Further, the support column top of floodgate mouth both sides all is equipped with the connecting plate that is used for being connected with operation platform, and the inside embedding of support column of floodgate mouth one side has signal processor, and the inside embedding of support column of opposite side has the battery, signal processor and battery top all are equipped with a cable that extends to in the control cabinet.

Further, the inside embedding of breakwater has the equipment box, and monitors cable fixed connection between the equipment box, and the cavity has been seted up to the inboard inner wall of equipment box simultaneously, both ends fixedly connected with velocity of flow monitor about the cavity, and velocity of flow monitor one side be equipped with monitoring cable fixed connection's elasticity cable, the inside flow signal ware that is equipped with of equipment box simultaneously, pass through cable interconnect between both ends and the velocity of flow monitor about the flow signal ware inboard, and the inboard middle section of flow signal ware is equipped with one and the flexible pivot of monitoring cable meshing.

Further, the monitoring cable includes adapter sleeve, runner, the monitoring cable comprises a plurality of adapter sleeve interconnect, and the adapter sleeve is the setting of I-shaped, the adapter sleeve is flexible rubber material, and the adapter sleeve both ends are equipped with magnetism and inhale the piece, the adapter sleeve center is equipped with the universal joint, and the adapter sleeve both sides are equipped with the runner chamber, rotates in the runner chamber simultaneously and is connected with the runner, runner both sides axle center department fixedly connected with telescopic shaft, and the telescopic shaft is connected with the universal joint meshing, and the guiding gutter has been seted up to the runner shaft simultaneously.

Furthermore, the telescopic shaft is internally provided with a limiting groove, an auxiliary shaft is sleeved in the limiting groove, meanwhile, the tail end of the auxiliary shaft is fixedly connected with a limiting plate, a spring is fixedly connected between the limiting plate and the outer side end of the limiting groove, and the surfaces of the limiting plate and the limiting groove are both provided with threads and are meshed with each other.

Further, the linkage cabin has been seted up to gate bottom one side, and the linkage cabin inside is equipped with the transfer line of a vertical setting, pivot both sides axle center department fixedly connected with fixed axle, and the embedding has the generator in the gate at pivot top, and fixed axle and generator all are connected with the transfer line meshing simultaneously, gate top center is seted up one with the drive screw groove of connecting screw rod meshing, and the transmission locked groove inside of gate both sides all is equipped with the response contact, the terminal series connection of the response contact of gate one side has a transmission cable who is connected with the generator, and the response contact end-to-end connection of gate opposite side has signal transmission cable, and signal transmission cable end-to-end connection has the signal transmission board.

Further, water monitor bottom fixedly connected with kickboard, and water monitor one side center an organic whole is provided with one and is criss-cross connecting block, inside one side of water monitor is equipped with water quality monitor, and the opposite side is equipped with level sensor, and has seted up the delivery port on the inner wall of water monitor left side, has seted up the water inlet on the inner wall of water monitor bottom simultaneously, through pipe through connection between water quality monitor and the delivery port and the water inlet, water quality monitor and level sensor are all connected with the signal contact piece through being equipped with a wire.

Further, the connecting block both sides are equipped with the drive ball of being connected with the meshing of monitor spacing groove, and the connecting block top is equipped with a transmission ball of being connected with the meshing of signal transmission board simultaneously, be equipped with in the connecting block inner wall with the transmission shaft of drive ball meshing, and the vertical transmission shaft that extends to the inside of water detector that is equipped with in the connecting block center inner wall to with the transmission shaft intermeshing of drive ball meshing, the inside signal contact piece that is equipped with of connecting block of transmission ball inboard.

Further, the equipment groove has evenly been seted up on the pivot surface, and the one end fixedly connected with rotation axis in equipment groove, curved water guide plate is fixedly connected with in rotation axis top, and rotation axis one side fixedly connected with retractable seal plate, and retractable seal plate top is sealing connection with the water guide plate simultaneously.

Further, the transmission display system comprises a signal processor for integrating processing signals, a flow rate monitor and a flow annunciator for monitoring the flow rate and the flow of water, a water monitor for detecting the water quality and the water level, a water level sensor and a water quality monitor for monitoring the transmission signals by cooperating with the water monitor, and a generator and a storage battery for providing power for the equipment, and the transmission display system comprises the following steps according to a diagram:

s1: and (3) system power supply: and the generator and the storage battery provide electric energy for the signal transmission device and the signal processor of each monitoring device.

S2: signal transmission: the water level sensor, the water quality monitor, the flow velocity monitor and the flow annunciator transmit the sensed signals to the signal processor in a centralized way through the cables and the transmission locking grooves.

S3: signal processing: and the signal processor transmits the processed signals to the console through a cable.

S4: signal display and transmission: the console displays the signals processed by the signal processing through the display screen, and transmits the signals to the terminal through the 5G signal transmitting antenna.

Has the advantages that:

(1) through being equipped with the gate, the pivot of its bottom will rotate along with rivers when the gate is opened to utilize the transfer line to drive the engine and generate electricity, realize utilizing rivers to provide the effect of electric power for equipment.

(2) Through being equipped with the water monitor, utilize the flotation plate to move the water monitor and change the removal along with the water level when the water level changes, the drive ball of connecting block both sides will drive the transmission shaft rotatory this moment to make water level sensor and the water quality monitoring ware with the transmission shaft meshing provide the power supply, realize that the water quality monitoring ware absorbs water through the water inlet and carry out water quality testing and water level sensor through the effect that the number of turns calculates and obtain the water level change index.

(3) Through being equipped with flexible locking piece, control flexible locking piece when the spacing gate position of needs stretches out and makes flexible locking piece extend to the transmission locked groove inside make the gate spacing, flexible locking piece top will communicate with each other with the response contact in the transmission locked groove simultaneously, realizes the effect of the spacing and transmission power of gate, signal.

Drawings

FIG. 1 is a schematic view of a partial structure of a dam body according to the present invention.

FIG. 2 is a schematic view of a support pillar structure according to the present invention.

FIG. 3 is a schematic view of a front cross-sectional structure of a support pillar according to the present invention.

FIG. 4 is a schematic view of the front cross-sectional structure of the water baffle of the present invention.

FIG. 5 is a schematic side sectional view of the equipment cabinet of the present invention.

FIG. 6 is a schematic view of a partial cross-sectional structure of a monitoring cable according to the present invention.

FIG. 7 is a schematic view of a front cross-sectional view of the wheel of the present invention.

FIG. 8 is an enlarged view of the structure at A in FIG. 7 according to the present invention.

FIG. 9 is a schematic view of the gate structure of the present invention.

FIG. 10 is a schematic view of the front cross-sectional structure of the gate of the present invention.

FIG. 11 is a schematic side sectional view of the gate of the present invention.

FIG. 12 is a schematic view of the water monitor of the present invention.

FIG. 13 is a schematic top sectional view of the water monitor of the present invention.

FIG. 14 is a schematic side sectional view of the rotating shaft according to the present invention.

FIG. 15 is an enlarged view of the structure at B in FIG. 14 according to the present invention.

FIG. 16 is a block diagram of the system of the present invention.

In fig. 1 to 16, the correspondence between the component names and the reference numbers is:

1-dam body, 101-gate, 2-operation platform, 201-brake opening motor, 202-console, 203-connecting screw, 3-supporting column, 301-connecting plate, 302-water baffle, 303-gate groove, 304-telescopic lock block, 305-monitoring cable, 306-connecting sleeve, 307-signal processor, 308-storage battery, 309-equipment box, 310-cavity, 311-flow rate monitor, 312-elastic cable, 313-flow signal device, 314-flexible rotating shaft, 315-universal joint, 316-runner cavity, 317-magnetic block, 318-runner, 319-water guide groove, 320-telescopic shaft, 321-limiting groove, 322-auxiliary shaft, 323-limiting plate, 324-spring, 4-gate, 401-transmission locking groove, 402-monitor groove, 403-monitor limiting groove, 404-water monitor, 405-driving screw groove, 406-induction contact, 407-transmission cable, 408-linkage cabin, 409-transmission rod, 410-generator, 411-rotating shaft, 412-signal transmission plate, 413-signal transmission cable, 414-connecting block, 415-driving ball, 416-floating plate, 417-water outlet, 418-water inlet, 419-transmission ball, 420-transmission shaft, 421-signal contact piece, 422-water level sensor, 423-water quality monitor, 424-fixed shaft, 425-equipment groove, 426-rotating shaft, 427-water guide plate and 428-telescopic sealing plate.

Detailed Description

The first embodiment is as follows:

as shown in figures 1 to 16:

the control console 202 operates the telescopic locking blocks 304 on the two sides of the support column 3 to contract towards the inner side of the support column 3, so that the telescopic locking blocks 304 are withdrawn from the transmission locking groove 401, then the brake opening motor 201 is operated to drive the connecting screw rod 203 to rotate, and at the moment, the gate 4 is driven by the driving screw groove 405 and the connecting screw rod 203 to move up and down along the gate groove 303.

After the gate 4 moves upwards to a predetermined position along the gate slot 303, the telescopic locking block 304 extends into the transmission locking slot 401 to keep the gate 4 stable and realize electrical conduction between the gate 4 and the supporting column 3, water in the dam flows out from the bottom of the gate 101, meanwhile, the rotating shaft 411 at the bottom of the gate 4 rotates under the action of water flow, meanwhile, the transmission shaft 420 is used for driving the generator 410 to work and generate electricity, electric energy is transmitted to the induction contact 406 in the transmission locking slot 401 through the transmission cable 407, and the electric energy is transmitted to the storage battery 308 through the transmission locking block 304 to be stored, so that the storage battery 308 provides electric energy for each component.

When the rotating shaft 411 rotates to the connection with the gate 4, the water guide plate 427 on the surface of the rotating shaft 411 is received inside the rotating shaft 411 by the rotating shaft 426, and the telescopic sealing plate 428 changes to form a seal according to the change of the water guide plate 427, so as to ensure the dryness inside the gate 4 and prevent the generator from malfunctioning.

Example two

As shown in figures 1 to 16:

when water flows at the gate 101, the water flow passes through the monitoring guy cable 305 between the water baffles 302, at this time, when the monitoring guy cable 305 is impacted by the water flow, the connecting sleeve 306 in the surface of the monitoring guy cable 305 is released from the magnetic attraction state, the monitoring guy cable extends along the water flow direction and forms an arc, the rotating wheel cavity 316 is opened to expose the rotating wheel 318 inside and rotate in contact with the water flow, the rotating wheels 318 are connected in series with each other through the universal joint 315, the rotating force is transmitted to the flow annunciator 313 through the flexible rotating shafts 314 at two sides of the monitoring guy cable 305, and at this time, the flow annunciator 313 calculates the flow in the gate 101 at this time through the rotating speed.

When the tension detecting cable 305 is stretched due to a force, the elastic cable 312 connected to the flow rate monitor 311 extends, and the flow rate monitor 311 analyzes and calculates a force signal of the elastic cable 312 to obtain a current water flow rate, and transmits the signal to the flow rate annunciator 313 through a wire, and the flow rate annunciator 313 transmits the signal to the signal processor 307 through the wire and the telescopic lock block 304.

EXAMPLE III

As shown in fig. 9 to 13:

when the water level in the dam changes, the water monitor 404 inside the gate 4 moves up and down in the monitor 402 by using the floating plate 416 at the bottom of the water monitor, meanwhile, the driving balls 415 at the two sides of the connecting block 414 are meshed with the monitor limiting groove 403 to rotate, and the driving shaft 420 at one side inside the connecting block 414 is driven to rotate to provide driving force for the water quality monitor 423, so that the water quality monitor 423 sucks the water source in the dam through the water inlet 418 and analyzes the water quality, and then the water is discharged through the water outlet 417, and meanwhile, the water level sensor 422 calculates the rotation number of the driving shaft 420 at the other side of the connecting block 414 to obtain the water level change value.

The water quality monitor 423 and the water level sensor 422 transmit the analyzed signals to the signal contact piece 421 through cables, and transmit the signals into the transmission locking groove 401 through the transmission ball 419, the signal contact piece 421 and the signal transmission plate 412, and finally transmit the signals to the signal processor 307.

The working principle is as follows: the gate opening motor 201 is controlled by the control console 202 to drive the connecting screw rod 203 to rotate to match with the driving screw groove 405 on the gate 4, so that the gate 4 can move up and down when the telescopic locking block 304 is unlocked.

When the gate 4 is lifted, the water in the dam will be discharged through the gate 101, and at the same time, the water flow will drive the rotating shaft 411 to rotate and drive the generator 410 to generate electricity, and the water flow will impact the monitoring cable 305 when passing through the water baffle 302, so that the monitoring cable 305 monitors the flow velocity and flow of the water flow.

As the water monitor 404 moves up or down along the monitor groove 402 as the water level in the dam changes, the driving balls 415 at both sides of the connection block 414 will engage with the monitor retaining groove 403 to rotate while the driving shaft 420 engages with the driving balls 415 to provide power source for the water level sensor 422 and the water quality monitor 423.

The signals generated by all the monitoring devices are transmitted to the sensing contact 406 in the transmission locking groove 401 through structures such as cables, when the telescopic locking block 304 extends into the transmission locking groove 401, the telescopic locking block is conducted with the sensing contact 406 and transmits the signals to the signal processor 307, and finally the signals are integrated and processed by the signal processor 307 and then transmitted to the console 202 to be displayed through a display screen and transmitted to the terminal through a 5G information technology.

Claims (10)

1. The utility model provides a hydraulic engineering 5G information transmission state monitoring device, includes dam body (1), operation platform (2), support column (3), gate (4), dam body (1) bottom is equipped with many support columns (3) that are used for supporting operation platform (2), and two are a set of and form sluice gate (101) its characterized in that between support column (3): support column (3) one side inside the dam dorsad is equipped with breakwater (302) of reinforcing support column (3) intensity, and is equipped with monitoring cable (305) of monitoring rivers between breakwater (302), gate groove (303) have been seted up to support column (3) inboard, and are equipped with flexible locking piece (304) that are used for locking and transmission signal in gate groove (303), and gate groove (303) interior swing joint has gate (4) simultaneously, gate (4) both sides seted up with flexible locking piece (304) assorted transmission locked groove (401), and gate (4) are equipped with water detector (404) that can move about from top to bottom by the inboard center of dam, and gate (4) bottom is equipped with usable rivers pivoted pivot (411) simultaneously.

2. The hydraulic engineering 5G information transmission state monitoring device of claim 1, characterized in that: and a storage battery (308) and a signal processor (307) are respectively arranged in the supporting columns (3) at the two sides of the gate (101).

3. The hydraulic engineering 5G information transmission state monitoring device of claim 1, characterized in that: the inside embedding of breakwater (302) has equipment box (309), be equipped with between equipment box (309) and be used for monitoring cable (305) of water velocity and flow, and breakwater (302) inside be equipped with monitoring cable (305) electric connection's flow signal ware (313), be equipped with in equipment box (309) inner wall simultaneously with monitoring cable (305) electric connection's velocity of flow monitor (311).

4. The hydraulic engineering 5G information transmission state monitoring device of claim, characterized in that: monitoring cable (305) include adapter sleeve (306), runner (318), monitoring cable (305) comprises a plurality of adapter sleeve (306) that establish ties each other, and adapter sleeve (306) are the I-shaped, adapter sleeve (306) are flexible material, and adapter sleeve (306) both sides have seted up runner chamber (316), runner chamber (316) internally mounted has water guide driven runner (318), and runner (318) both sides axle center department is equipped with telescopic shaft (320) that extend to adapter sleeve (306) inside.

5. The hydraulic engineering 5G information transmission state monitoring device of claim 4, wherein: an auxiliary shaft (322) which is limited and movable inside the telescopic shaft (320) is sleeved inside the telescopic shaft (320), a rebounding spring (324) is arranged between the auxiliary shaft (322) and the top end inside the telescopic shaft (320), and meanwhile, threads which are meshed with each other are arranged between the auxiliary shaft (322) and the inner wall of the telescopic shaft (320).

6. The hydraulic engineering 5G information transmission state monitoring device of claim 1, characterized in that: gate (4) bottom is equipped with along with rivers pivoted pivot (411), and is equipped with generator (410) with pivot (411) linkage in gate (4) of pivot (411) top, transmission locked groove (401) that are used for transmission power and signal source are seted up to gate (4) both sides, and gate (4) top center offer be used for gate (4) drive spiral shell groove (405) that go up and down.

7. The hydraulic engineering 5G information transmission state monitoring device of claim 1, characterized in that: the utility model discloses a water monitor, including water monitor (404), water monitor (404) bottom is equipped with and provides buoyancy's kickboard (416) for water monitor (404), and water monitor (404) one side center be equipped with gate (4) swing joint and be connecting block (414) that the cross set up, water monitor (404) inside both sides are equipped with water quality monitor (423) and level sensor (422) respectively, and set up water inlet (418) and delivery port (417) for water quality monitor (423) formation route on the water monitor (404) lateral wall.

8. The hydraulic engineering 5G information transmission state monitoring device of claim 7, characterized in that: connecting block (414) both sides are rotated and are connected with drive ball (415), and drive ball (415) meshing has transmission shaft (420) that extend to water monitor (404) inside, connecting block (414) top is rotated the indiscriminate transmission ball (419) that has connect, and in connecting block (414) top both sides be equipped with signal contact piece (421) of transmission ball (419) contact, top both sides signal contact piece (421) bottom is equipped with a wire of connecting in water quality monitor (423) and water level sensor (422) respectively in connecting block (414) simultaneously.

9. The hydraulic engineering 5G information transmission state monitoring device of claim 6, characterized in that: the surface of the rotating shaft (411) is uniformly provided with water guide plates (427) capable of being retracted into the rotating shaft (411), and the surfaces of the water guide plates (427) and the rotating shaft (411) are provided with telescopic sealing plates (428) which are sealed with the rotating shaft (411).

10. The transmission display system of the hydraulic engineering 5G information transmission state monitoring device according to any one of claims 1 to 9, characterized in that: the transmission display system comprises a signal processor (307) for integrating processing signals, a monitoring cable (305) for monitoring the water flow rate and flow, a flow rate monitor (311) and a flow annunciator (313) which are matched with the monitoring cable (305) to detect transmission signals, a water monitor (404) for detecting water quality and water level, a water level sensor (422) and a water quality monitor (423) which are matched with the water monitor (404) to monitor the transmission signals, a generator (410) for providing power for equipment, and a storage battery (308), and the transmission display system comprises the following steps:

s1: and (3) system power supply: the signal transmission device of each monitoring device and the signal processor (307) are provided with electric energy through the generator (410) and the storage battery (308).

S2: signal transmission: the water level sensor (422), the water quality monitor (423), the flow rate monitor (311) and the flow signal device (313) transmit the sensed signals to the signal processor (307) in a centralized way through the cable and the transmission locking groove (401).

S3: signal processing: the signal processor (307) transmits the processed signal to the console (202) through a cable.

S4: signal display and transmission: the console (202) displays the signal processed by the signal processing (307) through a display screen, and transmits the signal transmission to the terminal through a 5G signal transmitting antenna.

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