CN116592969A - Hydraulic engineering water level monitoring device - Google Patents

Abstract

The invention belongs to the field of hydraulic engineering, and particularly discloses a hydraulic engineering water level monitoring device. The hydraulic engineering water level monitoring device comprises a measuring rod, wherein the measuring rod is vertically arranged, a floating plate is arranged on one side of the measuring rod, the floating plate is horizontally arranged, an adjusting device is arranged between the floating plate and the measuring rod, the adjusting device drives the floating plate to lift and connect the floating plate and the measuring rod, a radar water level gauge is movably arranged above the floating plate, the radar water level gauge is vertically arranged, a grounding piece is fixedly arranged below the measuring rod, the grounding piece is vertically arranged, and a stabilizing component is arranged outside the grounding piece; according to the hydraulic engineering water level monitoring device, whether the device is started or not can be judged according to the rising of the water level, meanwhile, when the water flow speed is high in stormwater, the radar water level gauge is driven to move upwards through the water flow, so that the radar water level gauge cannot be soaked in water, the service life of the radar water level gauge is prolonged, and meanwhile, the stability of connection between a measuring rod and the ground can be improved.

Description

Hydraulic engineering water level monitoring device

Technical Field

The invention relates to the field of hydraulic engineering, in particular to a hydraulic engineering water level monitoring device.

Background

The water level monitoring device is mainly used for detecting the water level height of hydraulic engineering so as to timely master important information such as water flow, water level, flooding, water level fluctuation and the like. The radar type water level gauge is generally adopted to monitor the water level, when the radar type water level gauge encounters heavy rain weather, the radar type water level gauge can be completely submerged, equipment is damaged, meanwhile, the existing detection mechanism is generally inserted in water through a measuring rod, and under the power of water flow, the water flow easily rushes down the measuring rod, so that the equipment is damaged.

Disclosure of Invention

The invention aims to solve the problems and provide a hydraulic engineering water level monitoring device which comprises a measuring rod, wherein the measuring rod is vertically arranged, a floating plate is arranged on one side of the measuring rod, the floating plate is horizontally arranged, an adjusting device is arranged between the floating plate and the measuring rod, the adjusting device drives the floating plate to lift and connect the floating plate and the measuring rod, a radar water level gauge is movably arranged above the floating plate, the radar water level gauge is vertically arranged, a grounding piece is fixedly arranged below the measuring rod, the grounding piece is vertically arranged, a stabilizing component is arranged outside the grounding piece, and the stabilizing component increases the contact area between the grounding piece and soil.

Further, adjusting device includes threaded rod and diaphragm, and threaded rod rotates the cartridge in the inside of measuring stick, and the threaded rod sets up immediately, and the lower extreme of threaded rod runs through the grounding piece and extends to the inside of grounding piece, and the one end of threaded rod is provided with power component, and power component drives the threaded rod and rotates, and diaphragm thread bush is established in the outside of threaded rod, and the diaphragm level sets up, and the top of diaphragm is provided with coupling assembling, coupling assembling connects diaphragm and kickboard.

Further, power component includes A gear and B gear, and A gear fixed sleeve establishes in the outside of threaded rod, and A gear level sets up, and B gear sets up in one side of threaded rod, and B gear level sets up, and B gear and A gear engagement, the outside of B gear are provided with rotating assembly, and rotating assembly drives B gear rotation.

Further, rotating assembly includes box body, pivot and flabellum, and box body fixed mounting is in one side of measuring stick, and box body level sets up, and the pivot rotates the cartridge in the inside of box body, and the pivot sets up vertically, pivot and B gear fixed connection, flabellum fixed mounting are in the outside of pivot, and the one end of box body is provided with the structure that opens and shuts, and the structure that opens and shuts opens or closes the box body.

Further, the structure of opening and shutting includes water inlet, baffle and trigger piece, and the water inlet is seted up in one side of box body, and baffle slidable mounting is in the outside of box body, and the baffle sets up immediately, and the baffle covers the water inlet completely, triggers a fixed mounting in the top of baffle, and the trigger piece has buoyancy, and the buoyancy of trigger piece is greater than the gravity of baffle.

Further, coupling assembling includes that A connects rope, winding structure and clamping structure, and the floating plate is connected to the rope to A, and winding structure winding A connects the rope, and clamping structure sets up in the top of diaphragm, clamping structure centre gripping floating plate.

Further, the winding structure comprises a winding drum and an A spring, the winding drum is arranged above the transverse plate in a rotating mode, the winding drum is arranged in a vertical mode, and the A spring is connected with the winding drum and the transverse plate.

Further, the clamping structure comprises a sliding groove, clamping plates, B springs and pushing blocks, wherein the sliding groove is formed in the upper portion of the transverse plate, the sliding groove is horizontally formed, the clamping plates are slidably inserted into the sliding groove, the clamping plates are vertically arranged, two groups of clamping plates are close to one side end face and are inclined, the B springs are connected with the clamping plates and the transverse plate, the B springs are horizontally arranged, the pushing blocks are fixedly mounted on the upper portion of the measuring rod, and the pushing blocks are in contact fit with the clamping plates.

Further, stabilize the subassembly and include A sleeve, grounding post, screw thread piece and C spring, A sleeve fixed mounting is in the outside of grounding piece, A sleeve level sets up, grounding post slides and runs through A sleeve, grounding post level sets up, the one end of grounding post runs through the grounding piece and extends to the inside of grounding piece, screw thread piece thread bush is established in the outside of threaded rod, screw thread piece is the shape of falling round platform, screw thread piece and grounding post contact cooperation, C spring movable sleeve is established in the outside of grounding post, C spring coupling grounding post and A sleeve.

Further, stabilizing assembly still includes B sleeve, backup pad and B connecting rope, and B sleeve fixed mounting is in the telescopic outside of A, and B sleeve sets up immediately, and backup pad slip cartridge is in the telescopic inside of B, and the backup pad sets up immediately, and backup pad and grounding post all have magnetism, and backup pad and grounding post are repulsed mutually, and B connecting rope connects backup pad and grounding post.

The invention has the beneficial effects that: according to the device, whether the device is started or not can be judged according to the rising of the water level, meanwhile, when the water flow speed is high in stormwater, the radar water level gauge is driven to move upwards through the water flow, so that the radar water level gauge cannot be soaked in water, the service life of the radar water level gauge is prolonged, meanwhile, the stability of connection of the measuring rod and the ground can be improved, the measuring rod cannot be flushed down by the water flow, the safety of the device is further improved, when the water level is higher than the height of the measuring rod, the radar water level gauge can float on the water surface through the floating plate, the influence of stormwater on the radar water level gauge is further reduced, the radar water level gauge is prevented from being lost, and meanwhile, the damage probability of the radar water level gauge can be reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a hydraulic engineering water level monitoring device according to the present invention;

FIG. 2 is an enlarged view of the hydraulic engineering water level monitoring device at A in FIG. 1;

FIG. 3 is a sectional view showing a partial structure of a hydraulic engineering water level monitoring device according to the present invention;

FIG. 4 is a schematic view of a part of the water level monitoring device for hydraulic engineering according to the present invention;

fig. 5 is a sectional view of a part of the water level monitoring device for hydraulic engineering according to the present invention.

In the figure: 1. a measuring rod; 11. a radar water level gauge; 12. a floating plate; 13. a grounding member; 21. a threaded rod; 22. a cross plate; 23. winding up a winding drum; 24. a, a spring; 25. a is connected with a rope; 31. a chute; 32. a clamping plate; 33. a spring B; 34. a pushing block; 41. a gear; 42. a gear B; 51. a case body; 52. a rotating shaft; 53. a fan blade; 54. a water inlet; 55. a baffle; 56. a trigger; 61. a sleeve; 62. a grounding column; 63. a screw block; 64. c, a spring; 71. a sleeve B; 72. a support plate; 73. and B is connected with the rope.

Detailed Description

The subject matter described herein will now be discussed with reference to example embodiments. It is to be understood that these embodiments are merely discussed so that those skilled in the art may better understand and implement the subject matter described herein and that changes may be made in the function and arrangement of the elements discussed without departing from the scope of the disclosure herein. Various examples may omit, replace, or add various procedures or components as desired. In addition, features described with respect to some examples may be combined in other examples as well.

Example 1

Referring to fig. 1-5, in this embodiment, a hydraulic engineering water level monitoring device is provided, including measuring stick 1, measuring stick 1 sets up vertically, one side of measuring stick 1 is provided with kickboard 12, kickboard 12 level setting is provided with adjusting device between kickboard 12 and the measuring stick 1, adjusting device drives kickboard 12 and goes up and down and connect kickboard 12 and measuring stick 1, the top movable mounting of kickboard 12 has radar fluviograph 11, radar fluviograph 11 sets up vertically, the below fixed mounting of measuring stick 1 has grounding piece 13, grounding piece 13 sets up vertically, the outside of grounding piece 13 is provided with stabilizing component, stabilizing component increases the area of contact of grounding piece 13 and soil.

The adjusting device comprises a threaded rod 21 and a transverse plate 22, wherein the threaded rod 21 is rotatably inserted into the measuring rod 1, the threaded rod 21 is vertically arranged, the lower end of the threaded rod 21 penetrates through the grounding piece 13 and extends to the inside of the grounding piece 13, a power component is arranged at one end of the threaded rod 21 and drives the threaded rod 21 to rotate, the transverse plate 22 is sleeved outside the threaded rod 21 in a threaded manner, the transverse plate 22 is horizontally arranged, a connecting component is arranged above the transverse plate 22, and the connecting component is connected with the transverse plate 22 and the floating plate 12.

The power assembly comprises an A gear 41 and a B gear 42, the A gear 41 is fixedly sleeved outside the threaded rod 21, the A gear 41 is horizontally arranged, the B gear 42 is arranged on one side of the threaded rod 21, the B gear 42 is horizontally arranged, the B gear 42 is meshed with the A gear 41, a rotating assembly is arranged outside the B gear 42, and the rotating assembly drives the B gear 42 to rotate.

The rotating assembly comprises a box body 51, a rotating shaft 52 and fan blades 53, wherein the box body 51 is fixedly arranged on one side of the measuring rod 1, the box body 51 is horizontally arranged, the rotating shaft 52 is rotatably inserted into the box body 51, the rotating shaft 52 is vertically arranged, the rotating shaft 52 is fixedly connected with the B gear 42, the fan blades 53 are fixedly arranged outside the rotating shaft 52, an opening and closing structure is arranged at one end of the box body 51, and the opening and closing structure is used for opening or closing the box body 51.

The opening and closing structure comprises a water inlet 54, a baffle plate 55 and a trigger piece 56, wherein the water inlet 54 is formed in one side of the box body 51, the baffle plate 55 is slidably arranged outside the box body 51, the baffle plate 55 is vertically arranged, the baffle plate 55 completely covers the water inlet 54, the trigger piece 56 is fixedly arranged above the baffle plate 55, the trigger piece 56 has buoyancy, and the buoyancy of the trigger piece 56 is greater than the gravity of the baffle plate 55.

The connecting assembly comprises an A connecting rope 25, a winding structure and a clamping structure, wherein the A connecting rope 25 is connected with the floating plate 12 and the transverse plate 22, the winding structure winds the A connecting rope 25, the clamping structure is arranged above the transverse plate 22, and the clamping structure clamps the floating plate 12.

The winding structure comprises a winding drum 23 and an A spring 24, wherein the winding drum 23 is rotatably arranged above the transverse plate 22, the winding drum 23 is vertically arranged, and the A spring 24 is connected with the winding drum 23 and the transverse plate 22.

The clamping structure comprises a sliding groove 31, clamping plates 32, B springs 33 and a push block 34, wherein the sliding groove 31 is formed in the upper portion of the transverse plate 22, the sliding groove 31 is horizontally arranged, the clamping plates 32 are slidably inserted into the sliding groove 31, the clamping plates 32 are vertically arranged, two groups of clamping plates 32 are close to one side end face of each other and are inclined, the B springs 33 are connected with the clamping plates 32 and the transverse plate 22, the B springs 33 are horizontally arranged, the push block 34 is fixedly arranged above the measuring rod 1, and the push block 34 is in contact fit with the clamping plates 32.

The stabilizing assembly comprises an A sleeve 61, a grounding column 62, a threaded block 63 and a C spring 64, wherein the A sleeve 61 is fixedly arranged on the outer portion of the grounding piece 13, the A sleeve 61 is horizontally arranged, the grounding column 62 penetrates through the A sleeve 61 in a sliding mode, the grounding column 62 is horizontally arranged, one end of the grounding column 62 penetrates through the grounding piece 13 and extends to the inner portion of the grounding piece 13, the threaded block 63 is sleeved on the outer portion of the threaded rod 21 in a threaded mode of inverted round table, the threaded block 63 is in contact fit with the grounding column 62, the C spring 64 is movably sleeved on the outer portion of the grounding column 62, and the C spring 64 is connected with the grounding column 62 and the A sleeve 61.

The stabilizing assembly further comprises a B sleeve 71, a support plate 72 and a B connecting rope 73, wherein the B sleeve 71 is fixedly arranged outside the a sleeve 61, the B sleeve 71 is vertically arranged, the support plate 72 is slidably inserted into the B sleeve 71, the support plate 72 is vertically arranged, the support plate 72 and the grounding post 62 are both magnetic, the support plate 72 and the grounding post 62 are repelled, and the B connecting rope 73 is connected with the support plate 72 and the grounding post 62.

The working flow of the monitoring device proposed in this embodiment is as follows:

the measuring rod 1 is inserted into the soil through the grounding part 13, when the water level rises in heavy rain weather, the trigger part 56 can move upwards along with the rising of the water level, and it is required to be noted that the buoyancy of the trigger part 56 is larger than the gravity of the baffle 55, so that the trigger part 56 can drive the baffle 55 to synchronously move upwards, the baffle 55 does not shade the water inlet 54 when moving upwards, water flow can pass through the water inlet 54 and flow through the inside of the box body 51, the fan blade 53 and the rotating shaft 52 are driven to synchronously rotate when passing through the inside of the box body 51, the rotating shaft 52 drives the A gear 41 to rotate when rotating, the A gear 41 is meshed with the B gear 42, and the A gear 41 can drive the threaded rod 21 to rotate in the inside of the measuring rod 1 through the B gear 42, so that power is provided for the rotation of the threaded rod 21, and the device can be started only when the water level rises to a certain degree.

The threaded rod 21 and diaphragm 22 threaded connection, therefore, the threaded rod 21 can drive diaphragm 22 and upwards move along the length direction of threaded rod 21 when rotating, diaphragm 22 drives the diaphragm 12 and upwards moves in step, when diaphragm 22 moved to measuring stick 1 extreme position, push block 34 and grip block 32 contact and promote two sets of grip blocks 32 and keep away from each other in the inside of spout 31, B spring 33 receives the extrusion and takes place to warp, grip block 32 no longer carries out the centre gripping to the diaphragm 12, along with the continuous rising of water level, can drive the diaphragm 12 synchronous movement, make diaphragm 12 and diaphragm 22 separation, it is to say, the buoyancy of diaphragm 12 is greater than the gravity of radar fluviograph 11, at this moment, diaphragm 12 still is connected with measuring stick 1 through A connecting rope 25, along with the continuous rising of water level, simultaneously under the effect of rivers, the perpendicular and transverse distance of grip block 12 and measuring stick 1 constantly increases, A connecting rope 25 can drive the reel 23 rotation, A spring 24 takes place to warp, make when being higher than the water level of measuring stick 1, the diaphragm 12 can drive the radar 11 at the continuous rising of water level 11, can not influence the radar 11, the radar level gauge 11 is prolonged, the life-span radar 11 can be used to the radar level gauge, the radar level 11 is not be connected to the radar level 11, the radar level gauge is prolonged, the life-span radar level 11 is can be used to the radar level, and the radar level gauge is not used to be connected.

The threaded rod 21 can drive the screw thread piece 63 to move downwards when rotating, and the screw thread piece 63 can drive the grounding post 62 and outwards move in the inside of A sleeve 61 when moving downwards for grounding post 62 can the cartridge to the inside of soil, C spring 64 atress takes place to warp this moment, and grounding post 62 reduces the pulling force effect of connecting rope 73 to B, and under the effect of magnetic force, backup pad 72 and grounding post 62 are repulsed, and backup pad 72 can outwards move in the inside of B sleeve 71, thereby increases the area of contact of the device with the soil, is favorable to reducing the influence of rivers flow force to the device, makes measuring stick 1 be difficult to by the water flush.

Through the action, the device can be started according to the rising of the water level, meanwhile, the radar water level gauge 11 can be driven to move upwards by water flow when the water flow speed is high in stormwater, so that the radar water level gauge 11 cannot be soaked in water, the service life of the radar water level gauge 11 is prolonged, meanwhile, the stability of connection of the measuring rod 1 and the ground can be improved, the measuring rod 1 cannot be flushed down by water flow, the safety of the device is further improved, when the water level is higher than the height of the measuring rod 1, the radar water level gauge 11 can float on the water surface through the floating plate 12, the influence of stormwater on the radar water level gauge 11 is further reduced, the radar water level gauge 11 is prevented from being lost, and meanwhile, the damage probability of the radar water level gauge 11 can be reduced.

The embodiment has been described above with reference to the embodiment, but the embodiment is not limited to the above-described specific implementation, which is only illustrative and not restrictive, and many forms can be made by those of ordinary skill in the art, given the benefit of this disclosure, are within the scope of this embodiment.

Claims (10)

1. The utility model provides a hydraulic engineering water level monitoring device, including measuring stick (1), its characterized in that, measuring stick (1) sets up vertically, one side of measuring stick (1) is provided with kickboard (12), kickboard (12) level setting, be provided with adjusting device between kickboard (12) and measuring stick (1), adjusting device drives kickboard (12) and goes up and down and connect kickboard (12) and measuring stick (1), the top movable mounting of kickboard (12) has radar fluviograph (11), radar fluviograph (11) set up vertically, the below fixed mounting of measuring stick (1) has ground connection piece (13), the ground connection piece (13) sets up vertically, the outside of ground connection piece (13) is provided with stabilizing component, stabilizing component increases the area of contact of ground connection piece (13) and soil.

2. The hydraulic engineering water level monitoring device according to claim 1, wherein the adjusting device comprises a threaded rod (21) and a transverse plate (22), the threaded rod (21) is rotatably inserted into the measuring rod (1), the threaded rod (21) is vertically arranged, the lower end of the threaded rod (21) penetrates through the grounding piece (13) and extends to the inside of the grounding piece (13), one end of the threaded rod (21) is provided with a power assembly, the power assembly drives the threaded rod (21) to rotate, the transverse plate (22) is in threaded sleeve arrangement on the outside of the threaded rod (21), the transverse plate (22) is horizontally arranged, a connecting assembly is arranged above the transverse plate (22), and the connecting assembly is connected with the transverse plate (22) and the floating plate (12).

3. The hydraulic engineering water level monitoring device according to claim 2, wherein the power assembly comprises an A gear (41) and a B gear (42), the A gear (41) is fixedly sleeved outside the threaded rod (21), the A gear (41) is horizontally arranged, the B gear (42) is arranged on one side of the threaded rod (21), the B gear (42) is horizontally arranged, the B gear (42) is meshed with the A gear (41), a rotating assembly is arranged outside the B gear (42), and the rotating assembly drives the B gear (42) to rotate.

4. The hydraulic engineering water level monitoring device according to claim 3, wherein the rotating assembly comprises a box body (51), a rotating shaft (52) and fan blades (53), the box body (51) is fixedly installed on one side of the measuring rod (1), the box body (51) is horizontally arranged, the rotating shaft (52) is rotatably inserted into the box body (51), the rotating shaft (52) is vertically arranged, the rotating shaft (52) is fixedly connected with the B gear (42), the fan blades (53) are fixedly installed on the outer portion of the rotating shaft (52), an opening and closing structure is arranged at one end of the box body (51), and the opening and closing structure is used for opening or closing the box body (51).

5. The hydraulic engineering water level monitoring device according to claim 4, wherein the opening and closing structure comprises a water inlet (54), a baffle (55) and a trigger piece (56), the water inlet (54) is formed in one side of the box body (51), the baffle (55) is slidably mounted on the outer portion of the box body (51), the baffle (55) is vertically arranged, the baffle (55) completely covers the water inlet (54), the trigger piece (56) is fixedly mounted above the baffle (55), the trigger piece (56) has buoyancy, and the buoyancy of the trigger piece (56) is larger than the gravity of the baffle (55).

6. The hydraulic engineering water level monitoring device according to claim 2, wherein the connecting assembly comprises an A connecting rope (25), a winding structure and a clamping structure, the A connecting rope (25) is connected with the floating plate (12) and the transverse plate (22), the winding structure winds the A connecting rope (25), the clamping structure is arranged above the transverse plate (22), and the clamping structure clamps the floating plate (12).

7. The hydraulic engineering water level monitoring device according to claim 6, wherein the winding structure comprises a winding drum (23) and an A spring (24), the winding drum (23) is rotatably arranged above the transverse plate (22), the winding drum (23) is vertically arranged, and the A spring (24) is connected with the winding drum (23) and the transverse plate (22).

8. The hydraulic engineering water level monitoring device according to claim 6, wherein the clamping structure comprises a sliding groove (31), clamping plates (32), B springs (33) and push blocks (34), the sliding groove (31) is formed above the transverse plates (22), the sliding groove (31) is horizontally arranged, the clamping plates (32) are slidably inserted into the sliding groove (31), the clamping plates (32) are vertically arranged, two groups of clamping plates (32) are close to one side end face of each other and form an inclined shape, the B springs (33) are connected with the clamping plates (32) and the transverse plates (22), the B springs (33) are horizontally arranged, the push blocks (34) are fixedly arranged above the measuring rods (1), and the push blocks (34) are in contact fit with the clamping plates (32).

9. The hydraulic engineering water level monitoring device according to claim 2, wherein the stabilizing assembly comprises an A sleeve (61), a grounding column (62), a threaded block (63) and a C spring (64), wherein the A sleeve (61) is fixedly arranged outside the grounding piece (13), the A sleeve (61) is horizontally arranged, the grounding column (62) penetrates through the A sleeve (61) in a sliding mode, the grounding column (62) is horizontally arranged, one end of the grounding column (62) penetrates through the grounding piece (13) and extends to the inside of the grounding piece (13), the threaded block (63) is sleeved outside the threaded rod (21) in a threaded mode, the threaded block (63) is in an inverted circular truncated cone shape, the threaded block (63) is in contact fit with the grounding column (62), the C spring (64) is movably sleeved outside the grounding column (62), and the C spring (64) is connected with the grounding column (62) and the A sleeve (61).

10. The hydraulic engineering water level monitoring device according to claim 9, wherein the stabilizing assembly further comprises a B sleeve (71), a support plate (72) and a B connecting rope (73), the B sleeve (71) is fixedly installed outside the a sleeve (61), the B sleeve (71) is vertically arranged, the support plate (72) is slidably inserted into the B sleeve (71), the support plate (72) is vertically arranged, the support plate (72) and the grounding column (62) are magnetic, the support plate (72) and the grounding column (62) repel each other, and the B connecting rope (73) connects the support plate (72) and the grounding column (62).