CN114164921A - Hydraulic engineering is with energy-efficient drainage pumping station - Google Patents

Abstract

The invention discloses a high-efficiency energy-saving drainage pump station for hydraulic engineering, which relates to the technical field of hydraulic engineering and comprises a vehicle body, wherein a storage tank is arranged at the top of the vehicle body, the high-efficiency energy-saving drainage pump station for hydraulic engineering is provided with a driving shaft, the driving shaft can also drive a rotating shaft to rotate through the matching of a worm section and a worm wheel, so that the rotating shaft drives a cam to rotate, when the round end of the cam rotates towards the direction of a first connecting plate, liquid in a liquid tank enters a first liquid pumping cylinder through a second switch valve, when the convex end of the cam rotates towards the direction of the first connecting plate, the first connecting plate pushes a first piston rod to move towards the interior of the first liquid pumping cylinder, so that the liquid in the first liquid pumping cylinder enters a tee joint through a first switch valve, then enters a second fixed pipe through a communicating pipe, and then enters a counterweight sleeve through the second connecting pipe, the weight of the counterweight sleeve is increased, so that the suction head is convenient to discharge and retract, and energy is saved.

Description

Hydraulic engineering is with energy-efficient drainage pumping station

Technical Field

The invention relates to the technical field of hydraulic engineering, in particular to a high-efficiency and energy-saving drainage pump station for hydraulic engineering.

Background

Nowadays, hydraulic engineering's flood control drainage work is very important, and in order to deal with hydraulic engineering flood disasters, multiple flood control drainage pump station structure to hydraulic engineering has appeared in the market. A common drainage pumping station structure is generally composed of a frame, a control box, a drainage pump, a water pumping pipe and a drainage pipe. However, the existing drainage pump station structure is usually very heavy and inconvenient to move, so that the drainage pump station cannot be rapidly increased as required in a flood disaster.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an efficient and energy-saving drainage pump station for hydraulic engineering, which solves the problems in the background technology.

In order to achieve the purpose, the invention is realized by the following technical scheme: a high-efficiency energy-saving flood drainage pump station for hydraulic engineering comprises a vehicle body, wherein a storage box is arranged at the top of the vehicle body, a storage cavity is formed in the storage box, a pump body is arranged at the bottom of the inner cavity of the storage cavity, a first connecting joint is arranged at one end of the pump body, two first fixing plates are arranged in the inner cavity of the storage cavity, a first pipe roller is rotatably connected between the two first fixing plates, a first rotating joint is arranged on one side of the first fixing plate, one end of the first connecting joint is connected with one end of the first rotating joint, a first fixing pipe is arranged in the first pipe roller, one end of the first fixing pipe is connected with the other end of the first rotating joint, a first connecting pipe is wound on the outer side of the first pipe roller, one end of the first connecting pipe is connected with the other end of the first fixing pipe, and a suction head is arranged at the other end of the first connecting pipe, the outer side of the suction head is sleeved with a counterweight sleeve, one side of the first pipe roller is provided with a connecting column, two second fixing plates are arranged in the storage cavity, a second pipe roller is rotatably connected between the second fixing plates, the other end of the connecting column is connected with one end of the second pipe roller, one end of the connecting column extends to one side of the first fixing plate, a second connecting pipe is wound on the outer side of the second pipe roller, a second fixing pipe is arranged in the second pipe roller, one side of the second fixing plate is provided with a second rotary joint, one end of the second fixing pipe is connected with one end of the second rotary joint, one end of the second connecting pipe is connected with one end of the second fixing pipe, the other end of the second connecting pipe extends to the inside of the counterweight sleeve, the top of the pump body is provided with a hose, and the top end of the hose is provided with a second connector, the bottom of the storage box is provided with a moving groove.

Optionally, a transmission case is arranged at the top of the storage case, a liquid case is arranged at the top of the transmission case, the inner cavity of the transmission case is rotatably connected with a rotating shaft, the outer side of the rotating shaft is sleeved with a cam, a second liquid pumping cylinder is arranged inside the transmission case and on one side of the cam, a second piston rod is arranged in the second liquid pumping cylinder, one end of the second piston rod extends to the outer side of the second liquid pumping cylinder and is provided with a second connecting plate, a second return spring is sleeved on the outer side of the second piston rod, one end of the second return spring is connected with one end of a second connecting plate, the other end of the second return spring is connected with one end of a second liquid pumping cylinder, one end of the second liquid pumping cylinder is provided with a first electromagnetic valve, and a second electromagnetic valve is arranged at the bottom of the second liquid pumping cylinder, and one ends of the second electromagnetic valve and the first electromagnetic valve, which are positioned in the second liquid pumping cylinder, are provided with one-way valves.

Optionally, one side that the transmission case is inside and is located the cam is provided with first liquid cylinder of taking out, the inside first piston rod that is provided with of first liquid cylinder of taking out, the one end of first piston rod extends to the outside of first liquid cylinder of taking out and is provided with first connecting plate, the outside cover of first piston rod is equipped with first reset spring, first reset spring's one end is connected with one side of first connecting plate, first reset spring's the other end is connected with the other end of first liquid cylinder of taking out, one side of first liquid cylinder of taking out is provided with first ooff valve, the top of first liquid cylinder of taking out is provided with the second ooff valve, the second ooff valve all is provided with the check valve with the one end that first ooff valve is located first liquid cylinder of taking out.

Optionally, a communicating pipe is arranged inside the storage cavity, one end of the communicating pipe is connected with one end of the second rotary joint, a three-way joint is arranged at the top of the communicating pipe, the other end of the second electromagnetic valve is connected with one end of the three-way joint, one end of the three-way joint is connected with the other end of the first switch valve, and the top ends of the first electromagnetic valve and the second switch valve extend into the liquid tank.

Optionally, the bottom end of the rotating shaft extends into the storage cavity and is provided with a worm gear.

Optionally, a motor is fixed at one end of the top of the inner side of the storage cavity, the output end of the motor is connected with a driving shaft, the front section of the driving shaft is a screw rod section, the middle part of the driving shaft is a worm section, the driving shaft is suitable for being matched with a second connector through the screw rod section, the driving shaft is suitable for being matched with a worm wheel through the worm section, the driving shaft is also suitable for being matched with a connecting column, a through groove is formed in the position, at the second connector, of the top of the storage box, moving grooves communicated with the through groove are formed in two ends of the through groove, a baffle is slidably mounted in the moving grooves, a moving block is fixed at one end of the baffle and is in screw rod connection with the screw rod section through a connecting component, a first rack plate is fixed at the other end of the baffle, a mounting plate is fixed at the side part of the lower end of the second connector, and a guide rail is vertically fixed at the top of the storage box, a second screw rod is vertically and rotatably arranged in the guide rail, the mounting plate is in sliding fit with the guide rail and is connected with the second screw rod, the top of the second screw rod extends into the moving groove and is provided with a first gear, and the first gear is suitable for the first rack plate to be matched; the first rack plate and the second connector are not overlapped in vertical projection; the driving shaft is connected with the connecting column in a matched mode through a transmission assembly, the transmission assembly comprises a screw shaft, a positioning shaft, a sliding plate, a moving plate and a second rack plate, the screw shaft and the positioning shaft are vertically and parallelly installed in the storage cavity in a rotating mode, the sliding plate is connected with the positioning shaft in a sliding mode, the sliding plate is connected with the screw shaft in a screw mode, the second rack plate is fixed on the sliding plate, a second gear is fixed on the side portion of the connecting column, a second bevel wheel is installed on the top of the screw shaft, and the second bevel wheel is meshed with a first bevel wheel installed on the driving shaft; the coupling assembling includes sliding sleeve and clutch assembly, the sliding sleeve rotates spacing with the movable block to be connected, the lateral wall of sliding sleeve carries out spacing connection with the movable block through clutch assembly, clutch assembly includes the mounting groove, the inside mounting groove of having seted up of sliding sleeve, one side of mounting groove inner chamber is provided with clutch spring, clutch spring's one end is provided with the ball, the spacing groove has been seted up to the inboard of movable block, the ball cooperatees with the spacing groove, the inside wall and the lead screw section of sliding sleeve cooperate.

The invention provides an efficient and energy-saving drainage pump station for hydraulic engineering, which has the following beneficial effects:

1. the efficient and energy-saving drainage pump station for the hydraulic engineering is provided with the driving shaft, the driving shaft can drive the rotating shaft to rotate through the matching of the worm section and the worm wheel, so that the rotating shaft drives the cam to rotate, the first switch valve and the second switch valve are opened at the moment, the first electromagnetic valve and the second electromagnetic valve are closed, when the round end of the cam rotates towards the direction of the first connecting plate, the first piston rod pushes the first connecting plate to move towards the outer side direction of the first liquid pumping cylinder, liquid in the liquid tank enters the first liquid pumping cylinder through the second switch valve, when the convex end of the cam rotates towards the direction of the first connecting plate, the first connecting plate pushes the first piston rod to move towards the inside of the first liquid pumping cylinder, so that the liquid in the first liquid pumping cylinder enters the inside of the three-way joint through the first switch valve, then enters the second fixed pipe through the communicating pipe, and then enters the inside of the counterweight sleeve through the second connecting pipe, the weight of the counterweight sleeve is increased, so that the suction head is convenient to discharge and retract, and energy is saved.

2. This hydraulic engineering is with energy-efficient pumping station that drains stagnant water, through being provided with the drive shaft, lead screw section and baffle, when the motor drives the drive shaft and rotates, the drive shaft drives the movable block through the lead screw section earlier and slides along the shifting chute, and then drive the baffle and will lead to the groove and open, lead to the groove and be in when opening completely, first rack board just in time begins to mesh with first gear, the movable block continues to drive baffle and first rack board afterwards and removes, so that first rack board drives the second lead screw and rotates, thereby the second connector extends the outside of bin along leading to the groove under the drive of second lead screw, in order to make things convenient for operating personnel to operate.

Drawings

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

FIG. 2 is a schematic view of a portion of the present invention;

FIG. 3 is a schematic view of a portion of the baffle of the present invention;

FIG. 4 is an enlarged view taken at A of FIG. 1 in accordance with the present invention;

FIG. 5 is an enlarged view of FIG. 1 at B according to the present invention;

FIG. 6 is an enlarged view of FIG. 1 at C according to the present invention;

FIG. 7 is an enlarged view taken at D of FIG. 1 in accordance with the present invention;

fig. 8 is an enlarged view of fig. 1 at E according to the present invention.

In the figure: 1. a vehicle body; 2. a storage tank; 3. a pump body; 4. a first connector; 5. a first fixing plate; 6. a first tube roll; 7. a first connecting pipe; 8. a first rotary joint; 9. a first stationary tube; 10. a suction head; 11. a counterweight sleeve; 12. a second fixing plate; 13. a second tube roll; 14. a second rotary joint; 15. a second stationary tube; 16. a second connecting pipe; 20. connecting columns; 22. a first liquid pumping cylinder; 23. a first piston rod; 24. a first connecting plate; 25. a first return spring; 26. a rotating shaft; 27. a cam; 28. a first on-off valve; 30. a second on-off valve; 32. a second liquid pumping cylinder; 33. a second piston rod; 34. a second return spring; 35. a second connecting plate; 36. a transmission case; 37. a liquid tank; 38. a three-way joint; 39. a communicating pipe; 40. a moving groove; 43. a moving block; 48. a guide rail; 49. a second lead screw; 54. mounting a plate; 57. moving the plate; 62. a baffle plate; 63. a through groove; 64. a storage chamber; 65. moving the groove; 66. a first solenoid valve; 67. a second solenoid valve; 68. a worm section; 69. a worm gear; 70. a second connector; 71. a hose; 72. a screw section; 73. a first cone pulley; 74. a second cone; 75. a screw shaft; 76. a first rack plate; 77. a first gear; 78. positioning the shaft; 79. a slide plate; 80. a second gear; 81. a sliding sleeve; 82. mounting grooves; 83. a clutch spring; 84. a ball bearing; 85. a limiting groove; 86. a second rack plate; 87. a motor; 88. a drive shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 8, the present invention provides a technical solution: an efficient and energy-saving flood drainage pump station for hydraulic engineering comprises a vehicle body 1, wherein a storage tank 2 is arranged at the top of the vehicle body 1, a storage cavity 64 is formed in the storage tank 2, a pump body 3 is arranged at the bottom of the inner cavity of the storage cavity 64, a first connecting joint 4 is arranged at one end of the pump body 3, two first fixing plates 5 are arranged in the inner cavity of the storage cavity 64, a first pipe roller 6 is rotatably connected between the two first fixing plates 5, a first rotating joint 8 is arranged at one side of one first fixing plate 5, one end of the first connecting joint 4 is connected with one end of the first rotating joint 8, a first fixing pipe 9 is arranged in the first pipe roller 6, one end of the first fixing pipe 9 is connected with the other end of the first rotating joint 8, a first connecting pipe 7 is wound on the outer side of the first pipe roller 6, one end of the first connecting pipe 7 is connected with the other end of the first fixing pipe 9, a suction head 10 is arranged at the other end of the first connecting pipe 7, a counterweight sleeve 11 is sleeved outside the suction head 10, one side of the first tube roller 6 is provided with a connecting column 20, two second fixing plates 12 are arranged inside the storage cavity 64, a second tube roller 13 is rotatably connected between the second fixing plates 12, the other end of the connecting column 20 is connected with one end of the second tube roller 13, one end of the connecting column 20 extends to one side of the first fixing plate 5, a second connecting tube 16 is wound outside the second tube roller 13, a second fixing tube 15 is arranged inside the second tube roller 13, one side of one second fixing plate 12 is provided with a second rotary joint 14, one end of the second fixing tube 15 is connected with one end of the second rotary joint 14, one end of the second connecting tube 16 is connected with one end of the second fixing tube 15, the other end of the second connecting tube 16 extends to the inside of the counterweight sleeve 11, the top of the pump body 3 is provided with a hose 71, the top end of the hose 71 is provided with a second connector 70, the bottom of the storage box 2 is provided with a moving groove 65.

The top of the storage box 2 is provided with a transmission box 36, the top of the transmission box 36 is provided with a liquid box 37, an inner cavity of the transmission box 36 is rotatably connected with a rotating shaft 26, the outer side of the rotating shaft 26 is sleeved with a cam 27, one side, which is located inside the transmission box 36 and located on the cam 27, is provided with a second liquid pumping cylinder 32, the inside of the second liquid pumping cylinder 32 is provided with a second piston rod 33, one end of the second piston rod 33 extends to the outer side of the second liquid pumping cylinder 32 and is provided with a second connecting plate 35, the outer side of the second piston rod 33 is sleeved with a second return spring 34, one end of the second return spring 34 is connected with one end of the second connecting plate 35, the other end of the second return spring 34 is connected with one end of the second liquid pumping cylinder 32, one end of the second liquid pumping cylinder 32 is provided with a first electromagnetic valve 66, the bottom of the second liquid pumping cylinder 32 is provided with a second electromagnetic valve 67, and one ends, which are located inside the second liquid pumping cylinder 32, of the first electromagnetic valve 67 and the first electromagnetic valve 66 are provided with one-way valves.

The first liquid pumping cylinder 22 is arranged inside the transmission case 36 and on one side of the cam 27, the first piston rod 23 is arranged inside the first liquid pumping cylinder 22, one end of the first piston rod 23 extends to the outer side of the first liquid pumping cylinder 22 and is provided with a first connecting plate 24, the outer side of the first piston rod 23 is sleeved with a first return spring 25, one end of the first return spring 25 is connected with one side of the first connecting plate 24, the other end of the first return spring 25 is connected with the other end of the first liquid pumping cylinder 22, one side of the first liquid pumping cylinder 22 is provided with a first switch valve 28, the top of the first liquid pumping cylinder 22 is provided with a second switch valve 30, and one ends of the second switch valve 30 and the first switch valve 28, which are located inside the first liquid pumping cylinder 22, are provided with one-way valves.

The storage chamber 64 is internally provided with a communication pipe 39, one end of the communication pipe 39 is connected with one end of the second rotary joint 14, the top of the communication pipe 39 is provided with a three-way joint 38, the other end of the second electromagnetic valve 67 is connected with one end of the three-way joint 38, one end of the three-way joint 38 is connected with the other end of the first switch valve 28, and the top ends of the first electromagnetic valve 66 and the second switch valve 30 extend into the liquid tank 37.

Wherein the bottom end of the rotating shaft 26 extends to the inside of the storage chamber 64 and is provided with a worm wheel 69.

Wherein, a motor 87 is fixed at one end of the top of the inner side of the storage cavity 64, the output end of the motor 87 is connected with a driving shaft 88, the front section of the driving shaft 88 is a screw rod section 72, the middle part of the driving shaft 88 is a worm section 68, the driving shaft 88 is suitable for matching with a second connector 70 through the screw rod section 72, the driving shaft 88 is suitable for matching with a worm wheel 69 through the worm section 68, the driving shaft 88 is also suitable for matching with a connecting column 20, a through groove 63 is arranged at the top of the storage box 2 at the position of the second connector 70, moving grooves 40 communicated with the through groove 63 are arranged at two ends of the through groove 63, a baffle plate 62 is slidably arranged in the moving grooves 40, a moving block 43 is fixed at one end of the baffle plate 62, the moving block 43 is in screw rod connection with the screw rod section 72 through a connecting component, a first rack plate 76 is fixed at the other end of the baffle plate 62, a mounting plate 54 is fixed at the side part of the lower end of the second connector 70, a vertical fixed guide rail 48 at the top of the storage box 2, a second screw rod 49 is vertically and rotatably arranged in the guide rail 48, the mounting plate 54 is in sliding fit with the guide rail 48, the mounting plate 54 is connected with the second screw rod 49, the top of the second screw rod 49 extends into the moving groove 40 and is provided with a first gear 77, and the first gear 77 is suitable for the first rack plate 76 to be matched; the first rack plate 76 and the second connector 70 are not overlapped in vertical projection; the driving shaft 88 is connected with the connecting column 20 in a matching way through a transmission assembly, the transmission assembly comprises a screw shaft 75, a positioning shaft 78, a sliding plate 79, a moving plate 57 and a second rack plate 86, the screw shaft 75 and the positioning shaft 78 are vertically and parallelly installed in the storage cavity 64 in a rotating way, the sliding plate 79 is connected with the positioning shaft 78 in a sliding way, the sliding plate 79 is connected with the screw shaft 75 in a screw way, the second rack plate 86 is fixed on the sliding plate 79, a second gear 80 is fixed on the side part of the connecting column 20, a second cone 74 is installed at the top part of the screw shaft 75, and the second cone 74 is meshed with a first cone 73 installed on the driving shaft 88; the connecting assembly comprises a sliding sleeve 81 and a clutch assembly, the sliding sleeve 81 is in limited connection with the moving block 43 in a rotating mode, the outer side wall of the sliding sleeve 81 is in limited connection with the moving block 43 through the clutch assembly, the clutch assembly comprises a mounting groove 82, the mounting groove 82 is formed in the sliding sleeve 81, a clutch spring 83 is arranged on one side of the inner cavity of the mounting groove 82, one end of the clutch spring 83 is provided with a ball 84, a limiting groove 85 is formed in the inner side of the moving block 43, the ball 84 is matched with the limiting groove 85, and the inner side wall of the sliding sleeve 81 is matched with the screw rod section 72.

In conclusion, in the efficient and energy-saving flood drainage pump station for hydraulic engineering, initially, the through groove 63 is closed by the baffle plate 62, the second connector 70 is located in the storage cavity 64, when the motor 87 drives the driving shaft 88 to rotate, the driving shaft 88 firstly drives the moving block 43 to slide along the moving groove 40 through the screw rod section 72, and then drives the baffle plate 62 to open the through groove 63, when the through groove 63 is completely opened, the first rack plate 76 just starts to be meshed with the first gear 77, and then the moving block 43 continues to drive the baffle plate 62 and the first rack plate 76 to move, so that the first rack plate 76 drives the second screw rod 49 to rotate, and the second connector 70 extends to the outside of the storage box 2 along the through groove 63 under the driving of the second screw rod 49, so as to facilitate the operation of an operator,

in the above process, the driving shaft 88 can also drive the rotating shaft 26 to rotate through the cooperation of the worm section 68 and the worm wheel 69, so that the rotating shaft 26 drives the cam 27 to rotate, at this time, the first on-off valve 28 and the second on-off valve 30 are opened, the first electromagnetic valve 66 and the second electromagnetic valve 67 are closed, so that when the circular end of the cam 27 rotates towards the first connecting plate 24, the first piston rod 23 pushes the first connecting plate 24 to move towards the outside of the first liquid pumping cylinder 22, the liquid inside the liquid tank 37 enters the inside of the first liquid pumping cylinder 22 through the second on-off valve 30, when the convex end of the cam 27 rotates towards the first connecting plate 24, the first connecting plate 24 pushes the first piston rod 23 to move towards the inside of the first liquid pumping cylinder 22, so that the liquid inside the first liquid pumping cylinder 22 enters the inside of the three-way joint 38 through the first on-off valve 28, and then enters the inside of the second fixed pipe 15 through the communicating pipe 39, then enters the interior of the weight sleeve 11 through the second connecting pipe 16, so that the weight of the weight sleeve 11 is increased;

in the above process, the driving shaft 88 can also drive the screw shaft 75 to rotate, so that the screw shaft 75 drives the second rack plate 86 to move downwards from the highest position to be just meshed with the second gear 80; at this time, the moving block 43 moves to the bottom end of the moving groove 40, so that the clutch assembly is in a disengaged state, thereby ensuring that the driving shaft 88 can continue to rotate. Through the continuous rotation of the driving shaft 88, the second rack plate 86 continuously moves downwards to be completely disengaged from the second gear 80, in the process, the second gear 80 drives the connecting column 20 to rotate for multiple circles so as to lower the suction head 10 to a waterlogging area for draining the waterlogging, and then the driving shaft 88 continuously rotates so as to ensure that the second rack plate 86 is positioned below the second gear 80;

when the suction head 10 finishes draining the stagnant water, the motor 87 drives the driving shaft 88 to rotate reversely, at the moment, the clutch component is in a clamping state, and the moving plate 57 is driven to drive the first rack plate 76 to engage with the first gear 77, so that the second connector 70 is retracted into the storage box 2 and the through slot 63 is closed by the shutter 62, meanwhile, in the process, the second rack plate 86 moves upwards just to be meshed with the second gear 80 on the connecting column 20, and the worm 68 drives the worm wheel 69 to rotate reversely to completely pump out the water in the weight sleeve 11 through the liquid pumping cylinder structure, at this time, since the first rack plate 76 is pressed against the head end of the moving slot 40, the clutch assembly is in a separated state, the drive shaft 88 can then be rotated in the further direction to bring the second rack 86 further upwards into engagement with the second gear 80 to wind the cleaner head 10 back into position, and the second rack 86 is then moved upwards to the initial position for return under the further drive of the drive shaft 88.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (6)

1. The utility model provides a hydraulic engineering is with energy-efficient drainage pumping station, includes automobile body (1), its characterized in that: the top of the vehicle body (1) is provided with a storage box (2), a storage cavity (64) is formed in the storage box (2), the bottom of the inner cavity of the storage cavity (64) is provided with a pump body (3), one end of the pump body (3) is provided with a first connecting joint (4), the inner cavity of the storage cavity (64) is provided with two first fixing plates (5), a first pipe roller (6) is rotatably connected between the two first fixing plates (5), one side of the first fixing plate (5) is provided with a first rotating joint (8), one end of the first connecting joint (4) is connected with one end of the first rotating joint (8), a first fixing pipe (9) is arranged in the first pipe roller (6), one end of the first fixing pipe (9) is connected with the other end of the first rotating joint (8), a first connecting pipe (7) is wound on the outer side of the first pipe roller (6), the one end of first connecting pipe (7) is connected with the other end of first fixed pipe (9), the other end of first connecting pipe (7) is provided with suction head (10), the outside cover of suction head (10) is equipped with counter weight cover (11), one side of first pipe roller (6) is provided with spliced pole (20), it is provided with two second fixed plates (12) to store chamber (64) inside, it is connected with second pipe roller (13) to rotate between second fixed plate (12), the other end of spliced pole (20) is connected with the one end of second pipe roller (13), the one end of spliced pole (20) extends to one side of first fixed plate (5), the outside winding of second pipe roller (13) has second connecting pipe (16), second pipe roller (13) inside is provided with second fixed pipe (15), one side of second fixed plate (12) is provided with second rotary joint (14), the one end of the fixed pipe of second (15) is connected with the one end of second rotary joint (14), the one end of the fixed pipe of second (15) is connected with the one end of the fixed pipe of second (15), the other end of second connecting pipe (16) extends to inside counter weight cover (11), the top of the pump body (3) is provided with hose (71), the top of hose (71) is provided with second connector (70), groove (65) have been seted up in the bottom of bin (2).

2. The high-efficiency energy-saving flood drainage pump station for the hydraulic engineering according to claim 1, characterized in that: the top of bin (2) is provided with transmission case (36), the top of transmission case (36) is provided with liquid tank (37), transmission case (36) inner chamber rotates and is connected with axis of rotation (26), the outside cover of axis of rotation (26) is equipped with cam (27), one side that transmission case (36) inside and lie in cam (27) is provided with the second and takes out liquid cylinder (32), the inside second piston rod (33) that is provided with of second liquid cylinder (32), the one end of second piston rod (33) extends to the outside of second liquid cylinder (32) and is provided with second connecting plate (35), the outside cover of second piston rod (33) is equipped with second reset spring (34), the one end of second reset spring (34) is connected with the one end of second connecting plate (35), the other end of second reset spring (34) is connected with the one end of second liquid cylinder (32), one end of the second liquid pumping cylinder (32) is provided with a first electromagnetic valve (66), the bottom of the second liquid pumping cylinder (32) is provided with a second electromagnetic valve (67), and one ends, located inside the second liquid pumping cylinder (32), of the second electromagnetic valve (67) and the first electromagnetic valve (66) are provided with one-way valves.

3. The high-efficiency energy-saving flood drainage pump station for the hydraulic engineering according to claim 2, characterized in that: a first liquid pumping cylinder (22) is arranged inside the transmission case (36) and positioned at one side of the cam (27), a first piston rod (23) is arranged in the first liquid pumping cylinder (22), one end of the first piston rod (23) extends to the outer side of the first liquid pumping cylinder (22) and is provided with a first connecting plate (24), a first return spring (25) is sleeved on the outer side of the first piston rod (23), one end of the first return spring (25) is connected with one side of the first connecting plate (24), the other end of the first return spring (25) is connected with the other end of the first liquid pumping cylinder (22), a first switch valve (28) is arranged on one side of the first liquid pumping cylinder (22), the top of the first liquid pumping cylinder (22) is provided with a second switch valve (30), one ends of the second switch valve (30) and the first switch valve (28) which are positioned in the first liquid pumping cylinder (22) are respectively provided with a one-way valve.

4. The high-efficiency energy-saving flood drainage pump station for the hydraulic engineering according to claim 3, characterized in that: store chamber (64) inside and be provided with communicating pipe (39), the one end of communicating pipe (39) is connected with the one end of second rotary joint (14), the top of communicating pipe (39) is provided with three way connection (38), the other end of second solenoid valve (67) is connected with the one end of three way connection (38), the one end of three way connection (38) is connected with the other end of first ooff valve (28), the top of first solenoid valve (66) and second ooff valve (30) extends to inside liquid tank (37).

5. The high-efficiency energy-saving flood drainage pump station for the hydraulic engineering according to claim 3, characterized in that: the bottom end of the rotating shaft (26) extends to the inside of the storage cavity (64) and is provided with a worm wheel (69).

6. The high-efficiency energy-saving flood drainage pump station for the hydraulic engineering according to claim 1, characterized in that: the storage box is characterized in that a motor (87) is fixed at one end of the top of the inner side of the storage cavity (64), the output end of the motor (87) is connected with a driving shaft (88), the front section of the driving shaft (88) is a screw section (72), the middle part of the driving shaft (88) is a worm section (68), the driving shaft (88) is suitable for being matched with a second connector (70) through the screw section (72), the driving shaft (88) is suitable for being matched with a worm wheel (69) through the worm section (68), the driving shaft (88) is also suitable for being matched with a connecting column (20), a through groove (63) is formed in the position of the second connector (70) at the top of the storage box (2), moving grooves (40) communicated with the through groove (63) are formed in two ends of the through groove (63), a baffle plate (62) is slidably installed in the moving groove (40), and a moving block (43) is fixed at one end of the baffle plate (62), the moving block (43) is in screw rod connection with a screw rod section (72) through a connecting assembly, a first rack plate (76) is fixed to the other end of the baffle plate (62), a mounting plate (54) is fixed to the side portion of the lower end of the second connector (70), a guide rail (48) is vertically fixed to the top of the storage box (2), a second screw rod (49) is vertically and rotatably mounted in the guide rail (48), the mounting plate (54) is in sliding fit with the guide rail (48), the mounting plate (54) is connected with the second screw rod (49), the top of the second screw rod (49) extends into the moving groove (40) and is provided with a first gear (77), and the first gear (77) is suitable for the first rack plate (76) to be matched; the first rack plate (76) and the second connector (70) do not coincide in vertical projection; the driving shaft (88) is in fit connection with the connecting column (20) through a transmission assembly, the transmission assembly comprises a screw shaft (75), a positioning shaft (78), a sliding plate (79), a moving plate (57) and a second rack plate (86), the screw shaft (75) and the positioning shaft (78) are vertically and parallelly installed in the storage cavity (64) in a rotating mode, the sliding plate (79) is in sliding connection with the positioning shaft (78), the sliding plate (79) is in screw connection with the screw shaft (75), the second rack plate (86) is fixed to the sliding plate (79), a second gear (80) is fixed to the side portion of the connecting column (20), a second bevel wheel (74) is installed at the top portion of the screw shaft (75), and the second bevel wheel (74) is meshed with a first bevel wheel (73) installed on the driving shaft (88); the connecting assembly comprises a sliding sleeve (81) and a clutch assembly, the sliding sleeve (81) is in limited connection with the moving block (43) in a rotating mode, the outer side wall of the sliding sleeve (81) is in limited connection with the moving block (43) through the clutch assembly, the clutch assembly comprises a mounting groove (82), the mounting groove (82) is formed in the sliding sleeve (81), a clutch spring (83) is arranged on one side of the inner cavity of the mounting groove (82), one end of the clutch spring (83) is provided with a ball (84), a limiting groove (85) is formed in the inner side of the moving block (43), the ball (84) is matched with the limiting groove (85), and the inner side wall of the sliding sleeve (81) is matched with the screw rod section (72).

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