CN115200942A

CN115200942A - Water conservancy detects uses intelligent sampling equipment

Info

Publication number: CN115200942A
Application number: CN202210858764.9A
Authority: CN
Inventors: 郑绍能
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-07-20
Filing date: 2022-07-20
Publication date: 2022-10-18

Abstract

The invention discloses intelligent sampling equipment for water conservancy detection, which structurally comprises a movable bottom plate, a support column, a top plate, a motor box and a traction mechanism, wherein the upper end surface of the movable bottom plate is fixed with the bottom of the support column, the top of the support column is provided with the top plate, two inner ring torquers are driven to deviate through the gravity rotation of a rotor, two rotating balls on two sides rotate at two ends of a buffer plate, so that the bottom extraction mechanism is accelerated to reach a stable state, the balls and a rope are in elastic buffer through collision, the underground water sampled in the extraction mechanism is prevented from leaking out in the lifting process, a sliding block slides downwards on the vertical rod, a blocking piece is pushed back to reset, the inner side of a water inlet hole of a sampling barrel is blocked, the underground water is prevented from flowing back from the inner side of the water inlet hole again after being sampled, a clamping block is pushed inwards to move towards the inner side in a water outlet hole through an inwards pushing flexible pipe, the clamping block is separated from the inner side of the water outlet hole, and the underground water is ensured to be completely discharged through the inclined design of the bottom of the sampling barrel.

Description

Water conservancy detects uses intelligent sampling equipment

Technical Field

The invention relates to the field of water conservancy detection, in particular to intelligent sampling equipment for water conservancy detection.

Background

Hydraulic engineering is the surface water and the groundwater that are used for controlling and allotment nature, reach the earth's surface water and the groundwater that remove harm and prosper purpose and construct, also be called water engineering, water is the essential valuable resource of human production and life, groundwater among the hydraulic engineering needs through detecting, use intelligent sampling equipment to take groundwater out and then sampling test before detecting, but because intelligent sampling equipment is carrying out the in-process of taking a sample to groundwater, it stretches into groundwater to drive the rope through the lift inside to pull the sampling bucket, the sampling bucket is uncovered, can be better pack groundwater into inside and take a sample, and after sampling bucket is filled with groundwater, rope on the lift is carrying out the in-process that promotes to the sampling bucket, lead to the sampling bucket to take place to rock easily, sampling bucket top uncovered leads to the groundwater of sampling bucket inside to follow and rock and spill easily, lead to the inside groundwater detection weight of sampling bucket not enough, still need to carry out sampling work once more.

Disclosure of Invention

The technical scheme adopted by the invention for realizing the technical purpose is as follows: this intelligent sampling equipment is used in water conservancy detection, its structure is including removing bottom plate, support column, roof, motor case, drive mechanism, it is fixed with the support column bottom to remove the bottom plate up end to the support column top is equipped with the roof, the motor case is installed at the roof up end, motor case and drive mechanism upper end mechanical connection, the drive mechanism middle-end inlays in the support column outside, drive mechanism includes backup pad, conduction mechanism, rope, stabilizing mean, the end inlays in the support column outside in the backup pad outside to the backup pad middle-end is equipped with conduction mechanism, rope upper end and motor case mechanical connection to the rope adopts clearance fit to run through inside conduction mechanism, the rope lower extreme is fixed with stabilizing mean top middle-end.

As a further improvement of the invention, the conduction mechanism comprises an outer ring, a spring pipe sleeve, a squeezing rod, a hinged plate and balls, wherein the outer ring is arranged in the middle end of the support plate, the inner wall of the outer ring is fixed with the outer end of the spring pipe sleeve, the inner end of the squeezing rod is arranged in the inner end of the spring pipe sleeve in a clearance fit mode, the hinged plate is arranged at the outer end of the squeezing rod and hinged to a ball shaft center, the rope penetrates through the outer ring in a clearance fit mode and is in sliding connection with the balls, the spring pipe sleeve, the squeezing rod, the hinged plate and the balls are all provided with four parts which are respectively arranged in four directions on the inner side of the outer ring, and the four balls are in abutting sliding contact with the four directions on the outer side of the rope.

As a further improvement of the invention, the stabilizing mechanism comprises a connecting plate, a balancing mechanism, a buffer plate, a rotating ball, springs, a balancing plate and an extracting mechanism, wherein the middle end of the top of the connecting plate is fixed with the lower end of the rope, the balancing mechanism is arranged at the bottom of the connecting plate, the balancing mechanism is connected with the buffer plate through the rotating ball, the bottom of the buffer plate is welded with the top of the springs, the bottom of the springs is fixed with the inner part of the upper end of the balancing plate, the buffer plate is positioned in the inner part of the upper end of the balancing plate, the extracting mechanism is arranged at the bottom of the balancing plate, the rotating balls are provided with two rotating balls which are connected between the balancing mechanism and two sides of the buffer plate, and the bottom of the buffer plate is provided with two springs.

As a further improvement of the invention, the balancing mechanism comprises an outer ring, a rotating wheel, a supporting column, an inner ring, two inner ring torquers and a rotor, wherein two ends of the outer side of the outer ring are hinged with the rotating wheel, the rotating wheel is in transmission connection with a rotating ball, the inner side of the rotating wheel is fixed with one end of the supporting column, the other end of the supporting column is fixed with the outer side of the inner ring, the upper end and the lower end of the inner ring are respectively provided with the inner ring torquers, the rotor is positioned on the inner side of the inner ring and is fixed with the inner ring torquers, the top of the outer ring is fixed with the bottom of the connecting plate, the rotating wheel and the supporting column are respectively arranged at the left end and the right end of the outer ring, the two inner ring torquers are respectively arranged at the upper end and the lower end of the inner ring, and the outer ring and the inner ring are connected through the two inner ring torquers.

The extraction mechanism comprises a sampling barrel, an upright rod, a sliding block, a top spring, a linkage push rod, a baffle plate, a water inlet hole and a drainage mechanism, wherein the top of the sampling barrel is fixed with the bottom of a balance plate, the bottom of the upright rod is arranged at the middle end in the sampling barrel, the upright rod penetrates through the sliding block in a clearance fit mode, the top spring is arranged at the upper end of the upright rod, the bottom of the top spring is abutted to the top end of the sliding block, the outer side of the sliding block is hinged to one end of the linkage push rod, the other end of the linkage push rod is hinged to the inner side of the baffle plate, the outer end face of the baffle plate is abutted to the inner wall of the sampling barrel, the baffle plate is positioned on the inner side of the water inlet hole, the water inlet hole penetrates through the sampling barrel, the drainage mechanism is arranged in the sampling barrel, the linkage push rod, the baffle plate and the water inlet hole are respectively distributed in four directions of the sampling barrel in a ring shape, and the water inlet hole is of a cavity structure with a wide outlet.

As a further improvement of the invention, the drainage mechanism comprises a division bar, a flexible hose, a clamping block and a drainage hole, the division bar is arranged in the sampling barrel and fixed with one end of the flexible hose, the other end of the flexible hose is provided with the clamping block, the clamping block is clamped and arranged in the drainage hole, the drainage hole penetrates through the sampling barrel, the flexible hose is of a fold structure and made of rubber, and the flexible hose has certain resilience.

The invention has the beneficial effects that:

1. rope pulling extraction mechanism rises, rotate through rotor gravity and drive two inner ring torquers and produce the skew, the support column drives the runner rotation balance, both sides are changeed the ball and are rotated at the buffer board both ends, the elastic buffer of both sides spring simultaneously for bottom extraction mechanism reaches steady state, conflict between ball and the rope carries out elastic buffer, the rope carries out steady promotion to extraction mechanism, prevent that the groundwater of the inside sample of extraction mechanism from spilling at the in-process that promotes.

2. After groundwater sample was accomplished, the sliding block down slides in the pole setting, the separation blade pushes back and resets, at this moment, the separation blade blocks the inlet opening inboard of sampling bucket once more, prevent again after the groundwater sample from taking place the refluence once more and go out from the inlet opening is inside, through pushing the block piece toward the inboard removal in the wash port inside toward, at this moment the bellows extrusion shrink for the block piece is from the inside separation of wash port, with groundwater discharge, through the slope design of sampling bucket bottom, ensure to discharge groundwater is whole.

Drawings

FIG. 1 is a schematic structural diagram of an intelligent sampling device for water conservancy detection according to the present invention.

Fig. 2 is a schematic structural diagram of a traction mechanism according to the present invention.

Fig. 3 is a schematic top view of an internal structure of a conduction mechanism according to the present invention.

Fig. 4 is a schematic structural diagram of a stabilizing mechanism of the present invention.

Fig. 5 is a schematic diagram of an internal structure of a balancing mechanism according to the present invention.

Fig. 6 is a schematic top view of an internal structure of an extracting mechanism according to the present invention.

Fig. 7 is a schematic structural diagram of a drainage mechanism according to the present invention.

In the figure: the device comprises a movable bottom plate-Y, a support column-L, a top plate-D, a motor box-J, a traction mechanism-X, a support plate-X5, a conduction mechanism-X7, a rope-X3, a stabilizing mechanism-X1, an outer ring-X75, a spring pipe sleeve-X72, an extrusion rod-z 79, a hinged plate-X71, a ball-X76, a connecting plate-X14, a balancing mechanism-X12, a buffer plate-X15, a rotating ball-X18, a spring-X17, a balancing plate-X11, a drawing mechanism-X19, an outer ring-22, a rotating wheel-24, a support column-2 v, an inner ring-2 r, an inner ring torquer-28, a rotor-2Y, a sampling barrel-92, a vertical rod-9D, a sliding block-9 h, a top spring-9 t, a linkage push rod-95, a baffle-96, a water inlet hole-98, a drainage mechanism-9 p, a division bar-p 2, a flexible hose-p 4, a clamping block-p 7 and a drainage hole-p 9.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in figures 1 to 5:

the invention relates to intelligent sampling equipment for water conservancy detection, which structurally comprises a movable bottom plate Y, a support column L, a top plate D, a motor box J and a traction mechanism X, wherein the upper end surface of the movable bottom plate Y is fixed with the bottom of the support column L, the top of the support column L is provided with the top plate D, the motor box J is installed on the upper end surface of the top plate D, the motor box J is mechanically connected with the upper end of the traction mechanism X, the middle end of the traction mechanism X is embedded outside the support column L, the traction mechanism X comprises a support plate X5, a conduction mechanism X7, a rope X3 and a stabilizing mechanism X1, the outer end of the support plate X5 is embedded outside the support column L, the middle end of the support plate X5 is provided with the conduction mechanism X7, the upper end of the rope X3 is mechanically connected with the motor box J, the rope X3 penetrates through the conduction mechanism X7 in a clearance fit mode, and the lower end of the rope X3 is fixed with the middle end of the top of the stabilizing mechanism X1.

The conducting mechanism x7 comprises an outer ring x75, a spring pipe sleeve x72, a pressing rod z79, a hinge plate x71 and balls x76, wherein the outer ring x75 is arranged inside the middle end of a support plate x5, the inner wall of the outer ring x75 is fixed with the outer side end of the spring pipe sleeve x72, the inner side end of the pressing rod z79 is arranged inside the inner side end of the spring pipe sleeve x72 in a clearance fit mode, the outer side end of the pressing rod z79 is provided with the hinge plate x71, the hinge plate x71 is hinged with the shaft center of the balls x76, the rope x3 penetrates through the outer ring x75 in a clearance fit mode, the rope x3 is in sliding connection with the balls x76, the spring pipe sleeve x72, the pressing rod z79, the hinge plate x71 and the balls x76 are respectively arranged in four directions inside the outer ring x75, the four balls x76 slide in four directions outside the rope x3 in a clearance fit mode, and the rope x72 is elastically pressed in a collision mode through the pressing rod z79, so that the ball x76 and the rope x3 is elastically buffered, the rope x76 is improved in an auxiliary sliding effect of sliding and the rope x3 is ensured to descend.

Wherein, stabilizing mean x1 includes connecting plate x14, balance mechanism x12, buffer board x15, changes ball x18, spring x17, balance board x11, extraction mechanism x19, connecting plate x14 top middle-end is fixed mutually with rope x3 lower extreme to connecting plate x14 bottom is equipped with balance mechanism x12, be connected through changeing ball x18 between balance mechanism x12 and the buffer board x15, buffer board x15 bottom and spring x17 top are welded mutually, spring x17 bottom is fixed mutually with balance board x11 upper end inside, buffer board x15 is located inside balance board x11 upper end, balance board x11 bottom is equipped with extraction mechanism x19, change ball x18 and be equipped with two altogether, connect between balance mechanism x12 and buffer board x15 both sides to buffer board x15 bottom is equipped with two spring x17, through the rotation of both sides commentaries on classics ball x18 and the elastic buffer of both sides spring x17 for balance mechanism x12 drives between connecting plate x14 and the buffer board x15 and the balance board x15 and the steady degree between balance board x11 for the steady degree reaches steady extraction, thereby guarantees the internal leakage's of underground water sampling mechanism 19, prevents the internal leakage.

The balance mechanism x12 comprises an outer ring 22, a rotating wheel 24, a supporting column 2v, an inner ring 2r, an inner ring torquer 28 and a rotor 2y, wherein two outer ends of the outer ring 22 are hinged to the rotating wheel 24, the rotating wheel 24 is in transmission connection with a rotating ball x18, the inner side of the rotating wheel 24 is fixed to one end of the supporting column 2v, the other end of the supporting column 2v is fixed to the outer side of the inner ring 2r, the inner ring torquer 28 is arranged at each of the upper end and the lower end of the inner ring 2r, the rotor 2y is located at the inner side of the inner ring 2r and is fixed to the inner ring torquer 28, the top of the outer ring 22 is fixed to the bottom of a connecting plate x14, the two rotating wheels 24 and the two supporting columns 2v are arranged at the left end and the right end of the outer ring 22 respectively, the two inner ring torquer 28 are arranged at the upper end and the lower end of the inner ring 2r respectively, the outer ring 22 and the inner ring 2r are connected through the two inner ring torquer 28, and rotate through the gravity of the rotor 2y in the lifting movement process, so as to drive the two inner ring torquer 28 to generate deviation, at this time, the inner ring 2r and the supporting column 15 can be quickly reset stably, so as to quickly restore the rotating wheel 2v, and drive the supporting column 15 to quickly restore the horizontal angle of the supporting column.

The specific use mode and function of the embodiment are as follows:

in the invention, a motor in a motor box J is started to rotate forwards, an output end of the motor rotates to unreel a rope x3, the rope x3 drives a stabilizing mechanism x1 to descend, an extraction mechanism x19 is put into underground water to sample the underground water, after the underground water sampling is finished, the rope x3 is reeled through the reverse rotation of the motor, the rope x3 pulls the extraction mechanism x19 to ascend, the rotation is realized through the gravity of a rotor 2y in the lifting moving process, so that two inner ring torquers 28 are driven to deviate, at the moment, an inner ring 2r and an outer ring 22 can be quickly reset to keep stable, so that a support column 2v drives a rotating wheel 24 to rotate and balance, at the moment, two rotating balls x18 rotate at two ends of a buffer plate x15 through connecting support, meanwhile, elastic buffering of springs x17 at two sides is realized, the balance mechanism x12 drives a connecting plate x14 and the buffer plate x15 and a balance between the buffer plate x15 and a balance plate x11 to be stable, so that the bottom extraction mechanism x19 achieves a stable state, and the rope x3 stably slides with the ball x76 when the rope x75 is lifted, the rope slides in the outer ring x75, the lifting mechanism, the rope slides, the rope x19, the rope in the process of the rope, and the rope x19 is extruded in the elastic extrusion effect of the lifting mechanism is improved, and the lifting mechanism is improved.

Example 2:

as shown in fig. 6 to 7:

the extraction mechanism x19 includes a sampling barrel 92, an upright rod 9d, a sliding block 9h, a top spring 9t, a linkage push rod 95, a baffle plate 96, a water inlet hole 98 and a drainage mechanism 9p, the top of the sampling barrel 92 is fixed with the bottom of a balance plate x11, the bottom of the upright rod 9d is arranged at the middle end inside the sampling barrel 92, the upright rod 9d penetrates through the inside of the sliding block 9h in a clearance fit manner, the top spring 9t is installed at the upper end of the upright rod 9d, the bottom of the top spring 9t is abutted to the top end of the sliding block 9h, the outer side of the sliding block 9h is hinged to one end of the linkage push rod 95, the other end of the linkage push rod 95 is hinged to the inner side of the baffle plate 96, the outer end face of the baffle plate 96 is abutted to the inner wall of the sampling barrel 92, the baffle plate 96 is located at the inner side of the water inlet hole 98, the water inlet hole 98 penetrates through the sampling barrel 92, the drainage mechanism 9p is arranged inside the linkage sampling barrel 92, the linkage push rods 95, the baffle plates 96, the baffle plate 96, the water inlet hole 98 is arranged at four baffle plates and distributed on the four positions of the sampling barrel 92, the cavity structure with the inlet hole 98 is beneficial to the groundwater flow from the inside to the sampling barrel 92, and the groundwater is prevented from flowing back to the sampling barrel 96, so that groundwater flows to the sampling barrel 96 and flows into the sampling barrel 96, and groundwater is prevented from flowing from the sampling barrel 96.

The drainage mechanism 9p comprises a division bar p2, a telescopic hose p4, a clamping block p7 and a drainage hole p9, the division bar p2 is arranged inside the sampling barrel 92, the division bar p2 is fixed with one end of the telescopic hose p4, the other end of the telescopic hose p4 is provided with the clamping block p7, the clamping block p7 is clamped inside the drainage hole p9, the drainage hole p9 penetrates through the sampling barrel 92, the telescopic hose p4 is of a fold-type structure and made of rubber materials, certain resilience is achieved, elastic pressure can be applied to the clamping block p7 conveniently, accordingly, the clamping block p7 is blocked inside the drainage hole p9 when pushing force towards the inner side is not applied, the underground water is prevented from flowing out from the inside of the drainage hole p9 in the process of extracting the underground water, and the underground water is ensured to be extracted into the sampling barrel 92.

The specific use mode and function of the embodiment are as follows:

according to the invention, after a sampling barrel 92 enters underground water, the underground water enters from a water inlet 98, water pressure is applied to a baffle plate 96 through the underground water, then the baffle plate 96 moves towards the inner side of the sampling barrel 92, the linkage push rod 95 is used for linkage support in the moving process, meanwhile, the linkage push rod 95 pushes a sliding block 9h to slide upwards on an upright rod 9d, after the underground water sampling is completed, the top of the sliding block 9h is applied with elasticity through a top spring 9t on the outer side of the upper end of the upright rod 9d, so that the sliding block 9h slides downwards on the upright rod 9d, the baffle plate 96 is pushed back to reset through linkage pushing of the linkage push rod 95, at the moment, the baffle plate 96 blocks the inner side of the water inlet 98 of the sampling barrel 92 again, the underground water is prevented from flowing back from the inner part of the water inlet 98 after the underground water sampling, when the sampling barrel 92 is lifted after the sampling is finished, the underground water needs to be discharged from the inner part of the sampling barrel 92 to be detected, the telescopic hose p4 is extruded and contracted, so that the clamping block p7 is separated from the inner part of the drain hole, the underground water is prevented from leaking from the drain hole, and the bottom of the sampling barrel 92, and the underground water is prevented from leaking from the telescopic hose p9, and the drain hole is ensured, and the sampling barrel 4.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims

1. The utility model provides a water conservancy detects uses intelligent sampling equipment, its structure is including removing bottom plate (Y), support column (L), roof (D), motor case (J), drive mechanism (X), it is fixed mutually with support column (L) bottom to remove bottom plate (Y) up end to support column (L) top is equipped with roof (D), install at roof (D) up end motor case (J), motor case (J) and drive mechanism (X) upper end mechanical connection, drive mechanism (X) middle-end inlays in support column (L) outside, its characterized in that:

traction mechanism (X) includes backup pad (X5), conduction mechanism (X7), rope (X3), stabilizing mean (X1), backup pad (X5) outside end inlays in support column (L) outside to backup pad (X5) middle-end is equipped with conduction mechanism (X7), rope (X3) upper end and motor case (J) mechanical connection to rope (X3) adopt clearance fit to run through inside conduction mechanism (X7), rope (X3) lower extreme is fixed mutually with stabilizing mean (X1) top middle-end.

2. The intelligent sampling equipment for water conservancy detection according to claim 1, characterized in that: the conduction mechanism (x 7) comprises an outer ring (x 75), a spring pipe sleeve (x 72), an extrusion rod (z 79), a hinge plate (x 71) and balls (x 76), wherein the outer ring (x 75) is arranged inside the middle end of the support plate (x 5), the inner wall of the outer ring (x 75) is fixed with the outer side end of the spring pipe sleeve (x 72), the inner side end of the extrusion rod (z 79) is arranged inside the inner side end of the spring pipe sleeve (x 72) in a clearance fit mode, the outer side end of the extrusion rod (z 79) is provided with the hinge plate (x 71), the hinge plate (x 71) is hinged with the axes of the balls (x 76), the rope (x 3) penetrates through the outer ring (x 75) in a clearance fit mode, and the rope (x 3) is connected with the balls (x 76) in a sliding mode.

3. The intelligent sampling equipment for water conservancy detection according to claim 1, characterized in that: stabilizing mean (x 1) is including connecting plate (x 14), balance mechanism (x 12), buffer board (x 15), changes ball (x 18), spring (x 17), balance board (x 11), extraction mechanism (x 19), connecting plate (x 14) top middle-end is fixed mutually with rope (x 3) lower extreme to connecting plate (x 14) bottom is equipped with balance mechanism (x 12), be connected through changeing ball (x 18) between balance mechanism (x 12) and buffer board (x 15), buffer board (x 15) bottom welds mutually with spring (x 17) top, spring (x 17) bottom is fixed mutually with balance board (x 11) upper end is inside, buffer board (x 15) are located inside balance board (x 11) upper end, balance board (x 11) bottom is equipped with extraction mechanism (x 19).

4. The intelligent sampling equipment for water conservancy detection according to claim 3, characterized in that: balance mechanism (x 12) includes outer lane (22), runner (24), support column (2 v), inner circle (2 r), inner ring torquer (28), rotor (2 y), outer lane (22) outside both ends are articulated mutually with runner (24) to runner (24) are connected with commentaries on classics ball (x 18) transmission, runner (24) inboard is fixed mutually with support column (2 v) one end, and support column (2 v) other end is fixed mutually with inner circle (2 r) outside, both ends all are equipped with inner ring torquer (28) about inner circle (2 r), rotor (2 y) are located inner circle (2 r) inboard to rotor (2 y) are fixed mutually with inner ring torquer (28), outer lane (22) top is fixed bottom connecting plate (x 14).

5. The intelligent sampling equipment for water conservancy detection according to claim 3, characterized in that: the extraction mechanism (x 19) comprises a sampling barrel (92), a vertical rod (9 d), a sliding block (9 h), a top spring (9 t), a linkage push rod (95), a baffle (96), a water inlet hole (98) and a drainage mechanism (9 p), wherein the top of the sampling barrel (92) is fixed with the bottom of a balance plate (x 11), the bottom of the vertical rod (9 d) is arranged at the middle end inside the sampling barrel (92), the vertical rod (9 d) penetrates through the sliding block (9 h) in a clearance fit mode, the top spring (9 t) is arranged at the upper end of the vertical rod (9 d), the bottom of the top spring (9 t) is abutted to the top end of the sliding block (9 h), the outer side of the sliding block (9 h) is hinged to one end of the linkage push rod (95), the other end of the linkage push rod (95) is hinged to the inner side of the baffle (96), the outer side face of the baffle (96) is abutted to the inner wall of the sampling barrel (92), the baffle (96) is located at the inner side of the water inlet hole (98), the water inlet hole (98) penetrates through the inside of the sampling barrel (92), and the drainage mechanism (9 p) is arranged inside the sampling barrel (92).

6. The intelligent sampling equipment for water conservancy detection according to claim 5, characterized in that: drainage mechanism (9 p) include parting bead (p 2), stretch tube (p 4), block piece (p 7), wash port (p 9), establish inside sampling bucket (92) parting bead (p 2), parting bead (p 2) are fixed mutually with stretch tube (p 4) one end to the stretch tube (p 4) other end is equipped with block piece (p 7), block piece (p 7) block is installed inside wash port (p 9) to wash port (p 9) run through inside sampling bucket (92).