CN210002346U - hydraulic engineering automation control equipment - Google Patents

Abstract

The utility model discloses a hydraulic engineering automatic control equipment, including dykes and dams, floodgate and tooth piece, level sensor is installed in the outside of dykes and dams, and the top of dykes and dams installs control box and motor, the control box respectively with level sensor and motor electric connection, and the control box is located the left side of motor, the last surface mounting of dykes and dams has the thread bush, and the centre of thread bush is run through by the lead screw, the lead screw runs through from the surface of dykes and dams, and the below fixed mounting of lead screw has floodgate , inside the guide rail was inserted at the both ends of floodgate , and the guide rail was seted up on the surface of dykes and dams, the outside of fixed axle is fixed with the cutter.

Description

hydraulic engineering automation control equipment

Technical Field

The utility model relates to a hydraulic engineering technical field specifically is hydraulic engineering automation control equipment.

Background

The existing sluice needs to observe the water quantity manually at regular time in rainy season, when the water level is too high, the water is manually prevented from being opened, the operation amount is large, and silt deposited at the bottom of the water makes the sluice difficult to open, and in addition, the deposited silt reduces the drainage speed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide hydraulic engineering automation control equipment to it needs artifical regularly to observe the water yield to propose in solving above-mentioned background art, and submarine sedimentary silt makes floodgate be difficult to by opened, and silt has reduced the problem of the speed of drainage.

hydraulic engineering automation control equipment, including dykes and dams, floodgate and tooth piece, level sensor is installed in the outside of dykes and dams, and the top of dykes and dams installs control box and motor, the control box respectively with level sensor and motor electric connection, and the control box is located the left side of motor, the last surface mounting of dykes and dams has the thread bush, and the centre of thread bush is run through by the lead screw, the output of motor passes through the conveying chain of installation and thread bush interconnect, the lead screw runs through from the surface of dykes and dams, and the below fixed mounting of lead screw has floodgate , inside guide rail was inserted at the both ends of floodgate , and guide rail set up on the surface of dykes and dams, the surface mounting of dykes and dams has the mount pad, and the interior surface mounting of mount pad has the fixed axle, the fixed axle passes through the bracing piece of outside installation and the interior surface interconnect of the lantern ring, and the tooth piece is installed in the outside of the lantern ring, the bearing plate is installed in the outside of the lantern ring, and the surface of bearing plate is seted up flu.

Preferably, the surface of the dam is provided with tooth blocks at equal height, and the tooth blocks are in meshed connection with the tooth blocks on the outer side of the lantern ring.

Preferably, the lower end of the threaded sleeve is rotatably connected with the dam, and the inner wall of the threaded sleeve is in threaded connection with the outer wall of the screw rod.

Preferably, the brake is embedded at two sides in the guide rail, and both of them constitute a sliding structure.

Preferably, the support rods are distributed at equal angles on the outer side of the fixed shaft, and the support rods are respectively connected with the fixed shaft and the lantern ring in a welding mode.

Preferably, the cutters are arranged on the outer surface of the fixed shaft at equal angles, the cutters form an -body structure, and the cutters are arranged in a right-angled trapezoid structure.

Compared with the prior art, the beneficial effects of the utility model are that: the hydraulic engineering automation control equipment is characterized in that,

1. the water level sensor is arranged, when the water level is too high, the motor is started through the control box, the motor drives the thread sleeve to rotate, the bolt sleeve drives the screw rod to rotate, the screw rod moves upwards, the gate is opened, the water discharging effect is achieved, when the water level sensor detects that the water level is too low, the control box is triggered, the motor rotates reversely, the gate falls down again, the dam is conveniently plugged, manual control is not needed, and intelligent management is facilitated;

2. when floodgate rebound, the tooth piece through the surface drives the lantern ring and removes to the lantern ring removes at the bottom, and the bearing plate in the lantern ring outside drives silt and overturns, is convenient for become flexible submarine silt, and pivoted cutter drives silt and rotates, thereby has played the effect of desilting, has avoided silt to plug up the lower extreme of floodgate , the discharge of the upper water level of consequently being convenient for.

Drawings

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

FIG. 2 is a schematic view of the side structure of the dam of the present invention;

FIG. 3 is a schematic view of the side view of the mounting structure of the collar and the fixed shaft according to the present invention;

fig. 4 is a schematic view of the top view structure of the dam of the present invention;

fig. 5 is a schematic view of the front view structure of the installation of the fixing shaft and the cutter of the utility model.

In the figure, the water level sensor 1, the dam 2, the water level sensor 3, the control box 4, the motor 5, the thread bush 6, the screw rod 7, the gate , the guide rail 8, the guide rail 9, the mounting seat 10, the fixed shaft 11, the support rod 12, the lantern ring 13, the tooth block 14, the bearing plate 15, the groove 16, the cutter 17 and the transmission chain are shown.

Detailed Description

The technical solution in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of , but not all embodiments.

hydraulic engineering automation control equipment, including dyke 1, level sensor 2, control box 3, motor 4, thread bush 5, lead screw 6, gate , guide rail 8, mount pad 9, fixed axle 10, support rod 11, lantern ring 12, toothed block 13, bearing plate 14, recess 15, cutter 16 and conveying chain 17, level sensor 2 is installed on the outside of dyke 1, and control box 3 and motor 4 are installed on the top of dyke 1, control box 3 is respectively electrically connected with level sensor 2 and motor 4, and control box 3 is located the left side of motor 4, thread bush 5 is installed on the upper surface of dyke 1, and the middle of thread bush 5 is run through by lead screw 6, the output end of motor 4 is connected with thread bush 5 through the conveying chain 17 of installation, lead screw 6 runs through from the surface of lead screw 1, and is fixedly installed below of gate 6, the both ends of dyke 5397 are inserted into guide rail 8, and guide rail 8 is set up in the surface of dyke 1, lead screw 1 is installed on the surface of guide rail 1, lead screw 6 is installed on the surface of lantern ring 9, and the inner surface of mounting ring 12, and outer surface of bearing block 12 is installed on the outer side of bearing plate, and bearing block 12, the outer side of bearing block 12 is installed on the outer side of bearing block 12, the bearing block 12 and bearing block 12 of bearing block 12.

The surface of the dam 1 is provided with the tooth blocks 13 at the same height, and the tooth blocks 13 are engaged with the tooth blocks 13 outside the lantern ring 12, so that when the dam 1 ascends or descends, the lantern ring 12 is driven to rotate by the tooth blocks 13 on the surface, and the fixing shaft 10 is driven to rotate.

The lower end of the threaded sleeve 5 is rotatably connected with the dam 1, the inner wall of the threaded sleeve 5 is in threaded connection with the outer wall of the screw rod 6, and when the threaded sleeve 5 rotates, grains on the outer surface of the screw rod 6 move upwards along the grains on the inner wall of the threaded sleeve 5, so that the screw rod 6 drives the brake 7 to rotate.

The two sides of the gate 7 are embedded in the guide rail 8, and the two form a sliding structure, the gate 7 keeps moving vertically, the stability of the gate 7 is improved, and the connection performance of the gate 7 and the dam 1 is improved.

The bracing piece 11 is for the angular distribution such as the outside at fixed axle 10, and bracing piece 11 is welded connection with fixed axle 10 and lantern ring 12 respectively, and the setting up of bracing piece 11 makes to be hollow structure between fixed axle 10 and the lantern ring 12, reduces holistic weight, and the lantern ring 12 of being convenient for rotates.

The cutters 16 are arranged on the outer surface of the fixed shaft 10 at equal angles, the cutters 16 and the outer surface of the fixed shaft form an -body structure, the cutters 16 are arranged in a right-angle trapezoid structure, and the cutters 16 are arranged in a manner that sludge is driven to rotate by steps, so that the sludge is stirred and scattered, the adhesive force of sludge sediment is reduced, and the sludge is convenient to wash away by water flow.

When the control device is used, firstly, the control device is communicated with an external cable, so that the water level sensor 2 and the control box 3 are powered on, the water level sensor 2 monitors the water level below the water level sensor, when the water level is higher than the highest water level, the water level sensor 2 transmits a signal to the control box 3, the control box 3 starts the motor 4 through an internal potential signal, the motor 4 is powered on, the motor 4 rotates, namely the motor 4 drives the threaded sleeve 5 to rotate through the transmission chain 17, the threaded sleeve 5 rotates above the dam 1, the rotating threaded sleeve 5 drives the screw rod 6 to move upwards, namely the screw rod 6 drives the gate 7 to move upwards, so that the screw rod 6 drives the gate 2 7 to move upwards along the guide rail 8, namely the lower part of the is opened, when the gate moves upwards, the toothed block 13 on the surface of the gate drives the toothed block 13 on the outer side of the lantern ring 12 to rotate, the lantern ring 12 drives the fixed shaft 10 to rotate, so that the lantern ring 12 drives the bearing plate 14 to rotate, the bearing plate 14 lifts sediment, the silt groove 15 is provided with increased adhesive force, the silt is convenient for cutting by the silt plate 539, the silt is convenient for cutting, and the silt is convenient for cutting the silt under the silt moving of the water discharging knife so as to reduce the silt and the silt moving speed of the water under the water flowing away;

when the water level sensor 2 detects that the water level falls to the safe water level, the control box 3 is triggered again to control the motor 4 to be switched off.

Those not described in detail in this specification are within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The hydraulic engineering automatic control equipment comprises a dam (1), a gate (7) and a toothed block (13), and is characterized in that a water level sensor (2) is installed on the outer side of the dam (1), a control box (3) and a motor (4) are installed above the dam (1), the control box (3) is electrically connected with the water level sensor (2) and the motor (4) respectively, the control box (3) is located on the left side of the motor (4), a threaded sleeve (5) is installed on the upper surface of the dam (1), the middle of the threaded sleeve (5) is penetrated through by a screw rod (6), the output end of the motor (4) is connected with the threaded sleeve (5) through an installed transmission chain (17), the screw rod (6) penetrates through the surface of the dam (1), a gate (7) is fixedly installed below the screw rod (6), two ends of the gate (7) are inserted into guide rails (8), the guide rails (8) are arranged on the surface of the dam (1), a gate mounting seat (9) is installed on the surface of the dam (1), a bearing plate (12) is installed on the outer side of the fixed shaft (10), a bearing plate (12) is installed on the outer side of the bearing plate (10), and a bearing plate (12) is installed on the outer side of the bearing plate (10) and a bearing plate (10) is installed on the bearing plate (10) and a bearing plate (10) which is installed on which is.
2. 2. kinds of hydraulic engineering automation control equipment as claimed in claim 1, characterized in that the surface of the dam (1) is provided with tooth blocks (13) at equal height, and the tooth blocks (13) are engaged with the tooth blocks (13) outside the collar (12).
3. 3. The kinds of hydraulic engineering automation control equipment of claim 1, characterized in that the lower end of the thread bushing (5) is connected with the dyke (1) in a rotating way, and the inner wall of the thread bushing (5) is connected with the outer wall of the screw rod (6) in a threaded way.
4. 4. The hydraulic engineering automation control equipment of claim 1, wherein the brake (7) is embedded at both sides inside the guide rail (8) and both constitute a sliding structure.
5. 5. The hydraulic engineering automation control equipment of claim 1, wherein the support bars (11) are distributed at equal angles outside the fixed shaft (10), and the support bars (11) are respectively connected with the fixed shaft (10) and the lantern ring (12) by welding.
6. 6. The hydraulic engineering automation control equipment of claim 1, wherein the cutters (16) are arranged at equal angles on the outer surface of the fixed shaft (10) and form a integrated structure, and the cutters (16) are arranged in a right-angled trapezoid structure.

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