CN113981927B

CN113981927B - River course is cursory collection device for hydraulic engineering

Info

Publication number: CN113981927B
Application number: CN202111353682.0A
Authority: CN
Inventors: 涂龙敏
Original assignee: Qingdao Jiade Water Treatment Materials Co ltd
Current assignee: Qingdao Jiade Water Treatment Materials Co ltd
Priority date: 2021-11-16
Filing date: 2021-11-16
Publication date: 2023-09-01
Anticipated expiration: 2041-11-16
Also published as: CN113981927A

Abstract

The invention relates to a river channel buoy collection device, in particular to a river channel buoy collection device for hydraulic engineering. The technical problems of the invention are as follows: the river course cursory collection device for hydraulic engineering that the security is higher, and efficiency is higher is provided. The utility model provides a water conservancy project is with cursory collection device in river course, includes the linking frame, advances water frame, rotating barrier, valve mechanism and valve locking mechanical system, and linking frame one side is equipped with into water frame, and linking frame one side rotation type is connected with rotating barrier, and rotating barrier is located into water frame one side, is equipped with valve mechanism on the water frame, is equipped with valve locking mechanical system between water frame and the valve mechanism part. The invention can separate river water from the buoy by arranging the automatic driving mechanism, thereby improving the collection speed.

Description

River course is cursory collection device for hydraulic engineering

Technical Field

The invention relates to a river channel buoy collection device, in particular to a river channel buoy collection device for hydraulic engineering.

Background

The hydraulic engineering is used for controlling and allocating surface water and underground water in nature, achieves the purpose of removing harm and benefiting, is also called as water engineering, water is an indispensable precious resource for human production and life, urban river pollution is serious at present, a river course water surface often floats to have a float, water environment is affected, the float is rapidly propagated, in the existing small river course, the float is mainly salvaged by a net bag for sanitation workers, the sanitation workers have the possibility of losing feet and falling into water when the gravity center is unstable, the efficiency is low, in addition, the float on the river course is easy to scatter everywhere under the action of water flow, and the downstream river course is polluted.

Therefore, a river course buoy collection device for hydraulic engineering with higher safety and higher efficiency needs to be developed.

Disclosure of Invention

In order to overcome the defects of lower safety and low efficiency of fishing the floats by sanitation workers, the technical problem of the invention is that: the river course cursory collection device for hydraulic engineering that the security is higher, and efficiency is higher is provided.

River course is cursory collection device for hydraulic engineering, including:

the water inlet device comprises a connecting frame, a water inlet frame, a rotary baffle, a valve mechanism and a valve locking mechanism, wherein the water inlet frame is arranged on one side of the connecting frame, the rotary baffle is rotatably connected to one side of the connecting frame, the rotary baffle is positioned on one side of the water inlet frame, the valve mechanism is arranged on the water inlet frame, and the valve locking mechanism is arranged between the water inlet frame and a valve mechanism component.

Optionally, the valve mechanism is including first sliding connection pole, slip breakwater and first spring, and frame one side of intaking is equipped with 2 first sliding connection poles, and sliding connection has the slip breakwater between first sliding connection pole upper portion, and the slip breakwater is connected with frame sliding connection of intaking, is connected with first spring between the first sliding connection pole upper portion of slip breakwater both sides and homonymy.

Optionally, the valve locking mechanical system is including first swivelling joint board, rotatory pin, first torsion spring and dog, and the equal symmetry in frame both sides of intaking is equipped with first swivelling joint board, all rotates on the first swivelling joint board and is connected with rotatory pin, and rotatory pin all cooperates with the slip breakwater, is connected with 2 first torsion springs between rotatory pin all and the first swivelling joint board of homonymy, all is equipped with the dog on the first swivelling joint board.

Optionally, still including automatic drive mechanism, automatic drive mechanism is including first swivelling joint pole, two-way material frame, first gyro wheel and first stay cord of falling, and the symmetry is equipped with first swivelling joint pole on the frame of intaking, and the swivelling joint is connected with two-way material frame of falling between first swivelling joint pole one side, and frame one side of intaking is equipped with the support frame, and the rotation is equipped with first gyro wheel on the support frame, and support frame one side is equipped with the reel, is connected with first stay cord between two-way material frame one side and the slip breakwater one side, and first stay cord twines with first gyro wheel and reel.

Optionally, still including receiving material mechanism, receiving material mechanism is including sliding material frame, second sliding connection pole, the second spring, first sliding sleeve, slip water shutoff board and third spring, connecting frame one side slidingtype is connected with the slip material frame that connects, it has the delivery port to connect material frame one side to slide, it is located two-way material frame one side that falls to connect the material frame to connect, the symmetry is equipped with the second sliding connection pole on the connecting frame, the second sliding connection pole all is connected with the slip material frame slidingtype with sliding material frame, be connected with the second spring between the second sliding connection pole of slip material frame both sides all with the homonymy, slip material frame one side is equipped with first sliding sleeve, first sliding sleeve middle part slidingtype is connected with the slip water shutoff board, the delivery port is plugged up to the slip water shutoff board, be connected with the third spring between slip water shutoff board and the first sliding sleeve.

Optionally, still including automatic release mechanism, automatic release mechanism is including first slip drive pole, the second gyro wheel, the second sliding sleeve, the third slip connecting rod, second stay cord and fourth spring, slip material receiving frame bilateral symmetry is equipped with first slip drive pole, all be equipped with the second slip drive pole on the first slip drive pole, it is equipped with the second gyro wheel to advance equal symmetry rotation in water frame both sides, it is equipped with the second gyro wheel to advance also symmetry rotation on the water frame, all be equipped with the second sliding sleeve on the first swivelling joint pole, all be equipped with the third slip connecting rod on the second slip drive pole symmetry, the second sliding sleeve all is connected with the fourth spring with the third slip connecting rod slip of homonymy, be connected with the second stay cord between the swivelling joint pole of third slip connecting rod one end all with the homonymy, the second stay cord is all twined with the second gyro wheel of homonymy.

Optionally, still including cursory collection mechanism, cursory collection mechanism is including charging frame, second swivelling joint pole, second swivelling joint board, fourth slip drive pole and fifth spring, connecting frame one side is equipped with the charging frame, the inside symmetry of connecting frame is equipped with the second swivelling joint pole between the frame with intaking, bilateral material pouring frame is last the symmetry to be equipped with the second swivelling joint board, the second swivelling joint board all is connected with the second swivelling joint pole slidingtype of homonymy, be connected with the fifth spring between the second swivelling joint board all and the second swivelling joint pole of homonymy, all be equipped with the fourth slip drive pole on the second swivelling joint board.

Optionally, the sliding material receiving frame is rectangular.

The beneficial effects of the invention are as follows: 1. the invention can separate river water from the buoy by arranging the automatic driving mechanism, thereby improving the collection speed.

2. Through the cooperation between receiving mechanism, automatic release mechanism and the valve locking mechanism for the automation of this equipment can be improved, make the valve can realize opening by oneself and close.

3. Through being equipped with cursory collection mechanism for cursory can realize collecting intensively, need not people and collect manually.

Drawings

Fig. 1 is a schematic perspective view of a first part of the present invention.

Fig. 2 is a schematic perspective view of a second part of the present invention.

FIG. 3 is a schematic perspective view of a valve mechanism according to the present invention.

Fig. 4 is a schematic perspective view of a valve locking mechanism according to the present invention.

Fig. 5 is a schematic perspective view of an automatic driving mechanism according to the present invention.

Fig. 6 is a schematic perspective view of a first part of a receiving mechanism according to the present invention.

Fig. 7 is a schematic perspective view of a second part of the receiving mechanism of the present invention.

Fig. 8 is a schematic perspective view of a receiving mechanism according to the present invention.

Fig. 9 is a schematic perspective view of a receiving mechanism according to the present invention.

Fig. 10 is a schematic perspective view of an automatic unlocking mechanism according to the present invention.

Fig. 11 is a schematic perspective view of a float collection mechanism according to the present invention.

The reference symbols in the drawings: 1: connection frame, 2: water inlet frame, 3: rotating baffle, 4: valve mechanism, 41: first slide connection rod, 42: sliding water deflector, 43: first spring, 5: valve locking mechanism, 51: first rotating connection plate, 52: rotating stop lever, 53: first torsion spring, 54: stop block, 6: automatic driving mechanism, 61: first swivelling joint lever, 62: bidirectional pouring frame, 63: first roller, 64: first stay cord, 7: receiving mechanism, 71: sliding material receiving frame, 72: second slide connection rod, 73: second spring, 74: first sliding sleeve, 75: sliding water shutoff plate, 76: third spring, 8: automatic unlocking mechanism, 81: first slide drive lever, 82: second slide drive lever, 83: second roller, 84: second sliding sleeve, 85: third slide connecting rod, 86: second pull cord, 87: fourth spring, 9: float collection mechanism, 91: charging frame, 92: second swivelling joint pole, 93: second rotating web, 94: fourth slide drive bar, 95: and a fifth spring.

Detailed Description

The invention will be further described with reference to specific examples, illustrative examples and illustrations of which are provided herein to illustrate the invention, but are not to be construed as limiting the invention.

Example 1

The utility model provides a river course is cursory collection device for hydraulic engineering, as shown in fig. 1-4, including connecting frame 1, water inlet frame 2, rotating barrier 3, valve mechanism 4 and valve locking mechanism 5, connecting frame 1 upper right side is equipped with water inlet frame 2, and connecting frame 1 upper right side rotation is connected with rotating barrier 3, and rotating barrier 3 is located water inlet frame 2 downside, is equipped with valve mechanism 4 on the water inlet frame 2, is equipped with valve locking mechanism 5 between water inlet frame 2 and the valve mechanism 4 part.

The valve mechanism 4 comprises a first sliding connecting rod 41, a sliding water baffle 42 and a first spring 43, wherein 2 first sliding connecting rods 41 are arranged on the left side of the top of the water inlet frame 2, the sliding water baffle 42 is connected between the upper parts of the first sliding connecting rods 41 in a sliding mode, the sliding water baffle 42 is connected with the water inlet frame 2 in a sliding mode, and the first springs 43 are connected between the left side and the right side of the top of the sliding water baffle 42 and the upper parts of the first sliding connecting rods 41 on the same side.

The valve locking mechanism 5 comprises a first rotary connecting plate 51, rotary stop rods 52, first torsion springs 53 and stop blocks 54, wherein the first rotary connecting plate 51 is symmetrically arranged on the left side and the right side of the left side of the top of the water inlet frame 2, the rotary stop rods 52 are rotationally connected to the upper portions of the first rotary connecting plates 51, the rotary stop rods 52 are matched with the sliding water baffle plates 42, 2 first torsion springs 53 are connected between the rotary stop rods 52 and the first rotary connecting plates 51 on the same side, and the stop blocks 54 are arranged on the inner sides of the first rotary connecting plates 51.

When people need to collect the cursory in the river course, can put this equipment in river course mouth department, rotatory pin 52 blocks the slip breakwater 42, this moment first torsion spring 53 and first spring 43 initial condition are compressed state, river water and cursory get into in the connecting frame 1 through intaking frame 2, when the cursory in the connecting frame 1 reaches the back of a certain amount, people manually stir rotatory pin 52, first torsion spring 53 twists this moment, make rotatory pin 52 and slip breakwater 42 separate, first spring 43 tensile this moment, drive the slip breakwater 42 and move down, make the slip breakwater 42 block up intaking frame 2, prevent river water and cursory continue to get into in the connecting frame 1, people manually open rotatory baffle 3, clear up the cursory in the connecting frame 1, clear up the end, reset rotatory baffle 3, people again manually mention the slip breakwater 42, this moment first spring 43 resets, the rotatory pin 52 is reset again to the first torsion spring 53 resets, make rotatory pin 52 reset, make rotatory pin 52 move down, make water can get into the connecting frame 1 and keep on the river course in the connection, so can continue to collect the cursory.

Example 2

On the basis of embodiment 1, as shown in fig. 5-11, the automatic driving mechanism 6 is further included, the automatic driving mechanism 6 comprises a first rotary connecting rod 61, a bidirectional dumping frame 62, a first roller 63 and a first pull rope 64, the first rotary connecting rod 61 is symmetrically arranged on the front and back of the left upper side of the water inlet frame 2, the bidirectional dumping frame 62 is rotatably connected between the lower sides of the first rotary connecting rod 61, a supporting frame is arranged on the left side of the water inlet frame 2, the first roller 63 is rotatably arranged on the upper portion of the supporting frame, a reel is arranged on the right side of the upper portion of the supporting frame, a first pull rope 64 is connected between the left side of the top of the bidirectional dumping frame 62 and the left side of the top of the sliding water baffle 42, and the first pull rope 64 is wound with the first roller 63 and the reel.

The novel water shutoff device is characterized by further comprising a material receiving mechanism 7, wherein the material receiving mechanism 7 comprises a sliding material receiving frame 71, a second sliding connecting rod 72, a second spring 73, a first sliding sleeve 74, a sliding water shutoff plate 75 and a third spring 76, the sliding material receiving frame 71 is connected to the left lower side of the inside of the connecting frame 1 in a sliding manner, a water outlet is formed in the right lower side of the sliding material receiving frame 71, the sliding material receiving frame 71 is positioned below the left side of the bidirectional material pouring frame 62, the second sliding connecting rods 72 are symmetrically arranged on the left lower side of the inside of the connecting frame 1 in a front-back manner, the second sliding connecting rods 72 are connected with the sliding material receiving frame 71 in a sliding manner, the second springs 73 are connected between the front side and the back side of the sliding material receiving frame 71 and the second sliding connecting rods 72 on the same side, the first sliding sleeve 74 is arranged on the right lower side of the sliding material receiving frame 71, the sliding water shutoff plate 75 is connected to the middle of the sliding material shutoff plate 75 to block the water outlet, and the third spring 76 is connected between the sliding water shutoff plate 75 and the first sliding sleeve 74.

When river water and a buoy flow into the bidirectional pouring frame 62 from the water inlet frame 2, the river water flows into the sliding material receiving frame 71 through the bidirectional pouring frame 62, the sliding material receiving frame 71 slowly moves downwards due to gravity, at the moment, the second spring 73 is compressed, and then the first sliding sleeve 74 and the sliding water blocking plate 75 are driven to move downwards, when the river water in the sliding material receiving frame 71 is accumulated to a certain amount, people manually toggle the rotary stop lever 52 to block the water inlet frame 2, at the moment, the sliding water blocking plate 42 drives the first roller 63 and the bidirectional pouring frame 62 to rotate through the first pull rope 64, the bidirectional pouring frame 62 pours the buoy into a prepared frame, when the sliding water blocking plate 75 moves downwards to be in contact with the sliding material receiving frame 71, the sliding water blocking plate 75 moves to the right, at the moment, the third spring 76 is compressed, the water flows out of the sliding material receiving frame 71 through the water outlet, and is reset due to gravity, the second spring 73 drives the sliding material receiving frame 71, at the moment, the first sliding water blocking plate 74 and the sliding water blocking plate 75 reset, and the sliding water blocking plate 75 reset by the reset spring, and the reset water blocking plate is driven by the reset, and the reset of the sliding water blocking plate 52 can be driven by the reset, and the reset water blocking plate is driven by the reset plate and the reset plate 52, the reset water blocking plate and the reset plate and the water blocking plate can be reset by the reset plate and the water blocking plate 75 can be reset by the water.

The automatic unlocking mechanism 8 comprises a first sliding driving rod 81, a second sliding driving rod 82, a second roller 83, a second sliding sleeve 84, a third sliding connecting rod 85, a second pull rope 86 and a fourth spring 87, wherein the first sliding driving rod 81 is symmetrically arranged on the front side and the rear side of the sliding receiving frame 71, the second sliding driving rod 82 is respectively arranged on the top of the right side of the first sliding driving rod 81, the second roller 83 is respectively symmetrically arranged on the left side and the right side of the top of the water inlet frame 2 in a rotating mode, the second roller 83 is respectively symmetrically arranged on the front side and the rear side of the upper portion of the water inlet frame 2 in a rotating mode, the second sliding sleeve 84 is respectively arranged on the lower side of the first rotating connecting rod 61, the third sliding connecting rod 85 is respectively symmetrically arranged on the second sliding driving rod 82 in a sliding mode, the second sliding sleeve 84 is respectively connected with the third sliding connecting rod 85 on the same side, the fourth spring 87 is respectively symmetrically arranged on the left side and the right side between the second sliding sleeve 84 and the second sliding driving rod 82 on the same side, the top of the third sliding connecting rod 85 is respectively connected with the second roller 83 on the same side, and the second roller 83 is respectively wound on the same side as the second sliding connecting rod 82.

The novel floating type automatic feeding device is characterized by further comprising a floating collection mechanism 9, wherein the floating collection mechanism 9 comprises a charging frame 91, a second rotary connecting rod 92, a second rotary connecting plate 93, a fourth sliding driving rod 94 and a fifth spring 95, the charging frame 91 is arranged on the right side of the bottom in the connecting frame 1, the second rotary connecting rod 92 is symmetrically arranged between the inside of the connecting frame 1 and the water inlet frame 2, the second rotary connecting plate 93 is symmetrically arranged on the right side of the bidirectional dumping frame 62, the second rotary connecting plate 93 is slidably connected with the second rotary connecting rod 92 on the same side, the fifth spring 95 is connected between the second rotary connecting plate 93 and the second rotary connecting rod 92 on the same side, and the fourth sliding driving rod 94 is arranged on the outer side of the second rotary connecting plate 93.

When the sliding material receiving frame 71 moves downwards, the first sliding driving rod 81 is driven to move downwards, the second sliding driving rod 82 is driven to move downwards, at this time, the fourth spring 87 is stretched, the second sliding driving rod 82 drives the third sliding connecting rod 85 to move downwards, the third sliding connecting rod 85 drives the rotary stop lever 52 and the second roller 83 to rotate through the second pull rope 86, the rotary stop lever 52 is separated from the sliding water baffle 42, thereby automatically closing the water inlet frame 2, when the first sliding driving rod 81 moves downwards to be in contact with the fourth sliding driving rod 94, the fourth sliding driving rod 94 is driven to move downwards, the second sliding connecting plate 93 is driven to move downwards, at this time, the fifth spring 95 is compressed, the second sliding connecting plate 93 drives the bidirectional material pouring frame 62 to rotate, so that the bidirectional material pouring frame 62 is poured into the material charging frame 91, when the sliding material receiving frame 71 moves upwards to reset, at this time, the fourth spring 87 resets, the first sliding driving rod 81 is driven to reset, at this time, the fifth spring 95 resets, the second rotating connecting plate 93, the fourth sliding driving rod 94 and the fourth sliding connecting plate 62 are driven to reset, at this time, the second sliding stop lever 52 is driven to reset, and the bidirectional material pouring frame 62 is driven to move upwards through the pull rope 62 to reset, and the bidirectional material pouring frame 52 is enabled to roll up, and the material pouring frame 52 is collected by the inertia, and the material pouring frame 52 is reset by the sliding driving rod, and the sliding rod 52.

It is to be understood that the above description is intended to be illustrative only and is not intended to be limiting. Those skilled in the art will appreciate variations of the present invention that are intended to be included within the scope of the claims herein.

Claims

1. The river course is cursory collection device for hydraulic engineering, characterized by, including connecting frame (1), water inlet frame (2), rotating barrier (3), valve mechanism (4) and valve locking mechanism (5), connecting frame (1) one side is equipped with water inlet frame (2), and connecting frame (1) one side is connected with rotating barrier (3) in a rotating way, and rotating barrier (3) are located water inlet frame (2) one side, are equipped with valve mechanism (4) on water inlet frame (2), are equipped with valve locking mechanism (5) between water inlet frame (2) and valve mechanism (4) part; the valve mechanism (4) comprises a first sliding connecting rod (41), a sliding water baffle (42) and a first spring (43), 2 first sliding connecting rods (41) are arranged on one side of the water inlet frame (2), the sliding water baffle (42) is connected between the upper parts of the first sliding connecting rods (41), the sliding water baffle (42) is connected with the water inlet frame (2) in a sliding mode, and the first springs (43) are connected between the two sides of the sliding water baffle (42) and the upper parts of the first sliding connecting rods (41) on the same side; the valve locking mechanism (5) comprises a first rotary connecting plate (51), rotary stop rods (52), first torsion springs (53) and stop blocks (54), wherein the first rotary connecting plate (51) is symmetrically arranged on two sides of the water inlet frame (2), the rotary stop rods (52) are rotationally connected to the first rotary connecting plate (51), the rotary stop rods (52) are matched with the sliding water baffle plates (42), 2 first torsion springs (53) are connected between the rotary stop rods (52) and the first rotary connecting plate (51) on the same side, and the stop blocks (54) are arranged on the first rotary connecting plate (51); the automatic feeding device is characterized by further comprising an automatic driving mechanism (6), wherein the automatic driving mechanism (6) comprises a first rotary connecting rod (61), a bidirectional pouring frame (62), a first roller (63) and a first pull rope (64), the first rotary connecting rod (61) is symmetrically arranged on the water inlet frame (2), the bidirectional pouring frame (62) is rotatably connected between one sides of the first rotary connecting rod (61), a support frame is arranged on one side of the water inlet frame (2), the first roller (63) is rotatably arranged on the support frame, a winding wheel is arranged on one side of the support frame, a first pull rope (64) is connected between one side of the bidirectional pouring frame (62) and one side of the sliding water baffle (42), and the first pull rope (64) is wound with the first roller (63) and the winding wheel; the automatic water shutoff device is characterized by further comprising a material receiving mechanism (7), wherein the material receiving mechanism (7) comprises a sliding material receiving frame (71), a second sliding connecting rod (72), a second spring (73), a first sliding sleeve (74), a sliding water shutoff plate (75) and a third spring (76), the sliding material receiving frame (71) is connected to one side of the connecting frame (1) in a sliding manner, a water outlet is formed in one side of the sliding material receiving frame (71), the sliding material receiving frame (71) is positioned on one side of the bidirectional material pouring frame (62), the connecting frame (1) is symmetrically provided with the second sliding connecting rod (72), the second sliding connecting rods (72) are connected with the sliding material receiving frame (71) in a sliding manner, the second springs (73) are connected between the two sides of the sliding material receiving frame (71) and the second sliding connecting rods (72) on the same side, the first sliding material receiving frame (71) is provided with the first sliding sleeve (74), the sliding water shutoff plate (75) is connected to the middle of the sliding material receiving frame (71), the water outlet is formed in the sliding manner, and the third spring (76) is connected between the sliding water shutoff plate (75) and the first sliding sleeve (74); the automatic unlocking mechanism (8) comprises a first sliding driving rod (81), a second sliding driving rod (82), a second roller (83), a second sliding sleeve (84), a third sliding connecting rod (85), a second pull rope (86) and a fourth spring (87), wherein the first sliding driving rod (81) is symmetrically arranged on two sides of the sliding receiving frame (71), the second sliding driving rod (82) is symmetrically arranged on the first sliding driving rod (81), the second roller (83) is symmetrically arranged on two sides of the water inlet frame (2), the second roller (83) is symmetrically arranged on the water inlet frame (2), the second sliding sleeve (84) is symmetrically arranged on the first rotating connecting rod (61), the third sliding connecting rod (85) is symmetrically arranged on the second sliding driving rod (82), the second sliding sleeve (84) is symmetrically connected with the third sliding connecting rod (85) on the same side, the fourth spring (87) is symmetrically connected between the second sliding driving rod (82) on the same side, and the second sliding connecting rod (84) on the same side is rotationally connected with the second roller (83) on the same side as the second sliding connecting rod (86); still including cursory collection mechanism (9), cursory collection mechanism (9) is including charging frame (91), second swivelling joint pole (92), second swivelling joint pole (93), fourth slip drive pole (94) and fifth spring (95), connecting frame (1) one side is equipped with charging frame (91), the symmetry is equipped with second swivelling joint pole (92) between inside and the frame (2) that intakes of connecting frame (1), the symmetry is equipped with second swivelling joint pole (93) on two-way pouring frame (62), second swivelling joint pole (93) all are connected with second swivelling joint pole (92) of homonymy in a sliding manner, be connected with fifth spring (95) between second swivelling joint pole (93) all and second swivelling joint pole (92) of homonymy, all be equipped with fourth slip drive pole (94) on second swivelling joint pole (93).

2. The river course buoy collection device for hydraulic engineering according to claim 1, wherein the sliding material receiving frame (71) is rectangular in shape.