CN219218902U - A open and close gate for hydraulic and hydroelectric engineering - Google Patents

Abstract

The utility model relates to the technical field of opening and closing gates, in particular to an opening and closing gate for hydraulic and hydroelectric engineering. Including dam body and servo motor, the support is installed to the inboard of dam body, and the gate body is installed to the inboard of support, and the threaded rod is installed to the top of gate body, and reduction gear box is installed to the last half of threaded rod, and the hand rocker is installed on reduction gear box's right side, and driving motor is installed in reduction gear box's left side, and servo motor installs in the top of dam body, and servo motor's below is installed the lead screw, and the slider is installed to the bottom of lead screw, and the brush board is installed to the below of slider, and the brush roll is installed to one side that the brush board is close to the gate body. The beneficial effects of the utility model are as follows: at the gate beginning at every turn, servo motor drives slider, brush board and brush roll through the lead screw and follows the lead screw slip and go up and down, cleans the outside of gate body, and the residual water mark and the silt on the clearance gate body can be convenient effectual clear up the gate body outside.

Description

A open and close gate for hydraulic and hydroelectric engineering

Technical Field

The utility model relates to the technical field of opening and closing gates, in particular to an opening and closing gate for hydraulic and hydroelectric engineering.

Background

The gate is used for closing and opening the control means of the water discharge channel. Is an important component of a water conservancy building, and can be used for intercepting water flow, controlling water level, regulating flow and the like. In hydraulic engineering, a water conservancy gate is often required to control the water storage capacity of a canal and a reservoir. The existing water conservancy gate is mainly a lifting control gate in structural design, and can be widely applied to larger river channels and water channels.

In the use of the existing gate, the gate is often soaked in water, the bottom of the gate needs to be dredged, sludge is easy to adhere to the outer side of the gate and is used for a long time, the gate is easy to rust, so that the gate needs to be cleaned, the existing cleaning mode is often manual cleaning, the cleaning efficiency is poor, and a device is provided to solve the problem.

Disclosure of Invention

In view of the above problems, an object of the present utility model is to: the utility model provides a gate of opening and close for hydraulic and hydroelectric engineering solves current gate in the use, and the gate often soaks in water, and the gate needs to be desilting to the gate bottom, and silt adhesion is outside the gate easily, uses for a long time, and the gate rust easily, so need clear up the gate, and current clearance mode is often manual clearance, and clearance efficiency is poor.

In order to achieve the above purpose, the utility model adopts the technical scheme that: the utility model provides a gate of opening and close for hydraulic and hydroelectric engineering, includes dam body and servo motor, the support is installed to the inboard of dam body, and the inboard of support installs the gate body, the connecting rod is installed to the top of gate body, the threaded rod is installed through the pivot to the top of connecting rod, reduction gear box is installed to the last half of threaded rod, and reduction gear box's right side installs hand rocker, driving motor is installed in reduction gear box's left side, the protection casing is installed to the top of dam body, servo motor installs in the top of dam body, and installs the lead screw in servo motor's below, the slider is installed to the bottom of lead screw, and the brush board is installed to the below of slider, the brush roller is installed to one side that the brush board is close to the gate body.

The beneficial effects of the utility model are as follows: at the gate beginning at every turn, servo motor drives slider, brush board and brush roll through the lead screw and follows the lead screw slip and go up and down, cleans the outside of gate body, and the residual water mark and the silt on the clearance gate body can be convenient effectual clear up the gate body outside.

In order to ensure the opening and closing of the device:

as a further improvement of the above technical scheme: and the gate body and the connecting rod are integrally arranged by welding.

The beneficial effects of this improvement are: adopt the welding between gate body and the connecting rod, can make the connection between connecting rod and the gate body more firm reliable, and then can make things convenient for the threaded rod to drive the gate body and rise.

As a further improvement of the above technical scheme: the threaded rod and the dam body are mutually perpendicular, and a rotary installation structure is formed between the threaded rod and the dam body through a reduction gearbox.

The beneficial effects of this improvement are: the mutually perpendicular setting can make the threaded rod drive the at the same speed rise of gate body, drives the threaded rod through reduction gear box and rotates, can make the threaded rod rise along reduction gear box.

In order to facilitate the lifting of the brush plate:

as a further improvement of the above technical scheme: the two screw rods are symmetrically arranged about the center line of the dam body, and the screw rods and the dam body are mutually perpendicular.

The beneficial effects of this improvement are: the two screw rods which are symmetrically arranged can drive the sliding block and the brush plate to slide and lift along the screw rods under the driving of the servo motor, and the sliding and lifting of the sliding block and the brush plate can be facilitated by mutually perpendicular.

As a further improvement of the above technical scheme: the sliding installation structure is formed between the sliding block and the dam body through the screw rod, and the sliding block and the brush plate are integrally welded.

The beneficial effects of this improvement are: the brush plate welded with the slide block can be driven to ascend through the sliding of the slide block to wipe the outer side of the gate body, and residual water marks and sludge on the gate body are cleaned.

In order to ensure the cleaning effect:

as a further improvement of the above technical scheme: the brush rolls are symmetrically arranged on the center line of the brush plate.

The beneficial effects of this improvement are: the two brush rolls can increase the structural strength of the brush plate, avoid the brush plate from deforming in the wiping process, and ensure the cleaning effect.

Drawings

Fig. 1 is a schematic diagram of an overall front view structure.

Fig. 2 is a schematic diagram of the overall left-view structure.

Fig. 3 is a schematic view of a brush plate axis measurement structure.

Fig. 4 is an enlarged schematic view of the structure at a in fig. 2.

In the figure: 1. a dam body; 2. a bracket; 3. a gate body; 31. a connecting rod; 4. a threaded rod; 5. a reduction gear box; 6. a hand rocker; 7. a driving motor; 8. a protective cover; 9. a servo motor; 10. a screw rod; 11. a slide block; 12. brushing a plate; 13. and (5) brushing the roller.

Detailed Description

In order that those skilled in the art may better understand the technical solutions of the present utility model, the following detailed description of the present utility model with reference to the accompanying drawings is provided for exemplary and explanatory purposes only and should not be construed as limiting the scope of the present utility model.

Example 1:

as shown in fig. 1-4, an opening and closing gate for hydraulic and hydroelectric engineering comprises a dam body 1 and a servo motor 9, wherein a support 2 is installed on the inner side of the dam body 1, a gate body 3 is installed on the inner side of the support 2, a connecting rod 31 is installed above the gate body 3, a threaded rod 4 is installed above the connecting rod 31 through a rotating shaft, a reduction gearbox 5 is installed on the upper half part of the threaded rod 4, a hand rocker 6 is installed on the right side of the reduction gearbox 5, a driving motor 7 is installed on the left side of the reduction gearbox 5, a protective cover 8 is installed above the dam body 1, the servo motor 9 is installed on the top of the dam body 1, a screw rod 10 is installed below the servo motor 9, a sliding block 11 is installed at the bottom end of the screw rod 10, a brush plate 12 is installed below the sliding block 11, and a brush roller 13 is installed on one side of the brush plate 12, which is close to the gate body 3.

Example 2:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an opening and closing gate for hydraulic and hydroelectric engineering includes a dam body 1 and a servo motor 9, a bracket 2 is installed at the inner side of the dam body 1, a gate body 3 is installed at the inner side of the bracket 2, a connecting rod 31 is installed at the upper side of the gate body 3, a threaded rod 4 is installed at the upper side of the connecting rod 31 through a rotating shaft, a reduction gearbox 5 is installed at the upper half part of the threaded rod 4, a hand rocker 6 is installed at the right side of the reduction gearbox 5, a driving motor 7 is installed at the left side of the reduction gearbox 5, a protective cover 8 is installed at the upper side of the dam body 1, the servo motor 9 is installed at the top of the dam body 1, a screw rod 10 is installed at the lower side of the servo motor 9, a slider 11 is installed at the bottom end of the screw rod 10, a brush plate 12 is installed at the lower side of the slider 11, and a brush roller 13 is installed at one side of the brush plate 12 close to the gate body 3. And the gate body 3 and the connecting rod 31 are integrally welded.

Example 3:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an opening and closing gate for hydraulic and hydroelectric engineering includes a dam body 1 and a servo motor 9, a bracket 2 is installed at the inner side of the dam body 1, a gate body 3 is installed at the inner side of the bracket 2, a connecting rod 31 is installed at the upper side of the gate body 3, a threaded rod 4 is installed at the upper side of the connecting rod 31 through a rotating shaft, a reduction gearbox 5 is installed at the upper half part of the threaded rod 4, a hand rocker 6 is installed at the right side of the reduction gearbox 5, a driving motor 7 is installed at the left side of the reduction gearbox 5, a protective cover 8 is installed at the upper side of the dam body 1, the servo motor 9 is installed at the top of the dam body 1, a screw rod 10 is installed at the lower side of the servo motor 9, a slider 11 is installed at the bottom end of the screw rod 10, a brush plate 12 is installed at the lower side of the slider 11, and a brush roller 13 is installed at one side of the brush plate 12 close to the gate body 3. The threaded rod 4 and the dam body 1 are arranged in a mutually perpendicular mode, and a rotary installation structure is formed between the threaded rod 4 and the dam body 1 through a reduction gear box 5.

Example 4:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an opening and closing gate for hydraulic and hydroelectric engineering includes a dam body 1 and a servo motor 9, a bracket 2 is installed at the inner side of the dam body 1, a gate body 3 is installed at the inner side of the bracket 2, a connecting rod 31 is installed at the upper side of the gate body 3, a threaded rod 4 is installed at the upper side of the connecting rod 31 through a rotating shaft, a reduction gearbox 5 is installed at the upper half part of the threaded rod 4, a hand rocker 6 is installed at the right side of the reduction gearbox 5, a driving motor 7 is installed at the left side of the reduction gearbox 5, a protective cover 8 is installed at the upper side of the dam body 1, the servo motor 9 is installed at the top of the dam body 1, a screw rod 10 is installed at the lower side of the servo motor 9, a slider 11 is installed at the bottom end of the screw rod 10, a brush plate 12 is installed at the lower side of the slider 11, and a brush roller 13 is installed at one side of the brush plate 12 close to the gate body 3. Two lead screws 10 are symmetrically arranged about the center line of the dam body 1, and the lead screws 10 and the dam body 1 are mutually perpendicular.

Example 5:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an opening and closing gate for hydraulic and hydroelectric engineering includes a dam body 1 and a servo motor 9, a bracket 2 is installed at the inner side of the dam body 1, a gate body 3 is installed at the inner side of the bracket 2, a connecting rod 31 is installed at the upper side of the gate body 3, a threaded rod 4 is installed at the upper side of the connecting rod 31 through a rotating shaft, a reduction gearbox 5 is installed at the upper half part of the threaded rod 4, a hand rocker 6 is installed at the right side of the reduction gearbox 5, a driving motor 7 is installed at the left side of the reduction gearbox 5, a protective cover 8 is installed at the upper side of the dam body 1, the servo motor 9 is installed at the top of the dam body 1, a screw rod 10 is installed at the lower side of the servo motor 9, a slider 11 is installed at the bottom end of the screw rod 10, a brush plate 12 is installed at the lower side of the slider 11, and a brush roller 13 is installed at one side of the brush plate 12 close to the gate body 3. The sliding installation structure is formed between the sliding block 11 and the dam body 1 through the screw rod 10, and the sliding block 11 and the brush plate 12 are integrally welded.

Example 6:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an opening and closing gate for hydraulic and hydroelectric engineering includes a dam body 1 and a servo motor 9, a bracket 2 is installed at the inner side of the dam body 1, a gate body 3 is installed at the inner side of the bracket 2, a connecting rod 31 is installed at the upper side of the gate body 3, a threaded rod 4 is installed at the upper side of the connecting rod 31 through a rotating shaft, a reduction gearbox 5 is installed at the upper half part of the threaded rod 4, a hand rocker 6 is installed at the right side of the reduction gearbox 5, a driving motor 7 is installed at the left side of the reduction gearbox 5, a protective cover 8 is installed at the upper side of the dam body 1, the servo motor 9 is installed at the top of the dam body 1, a screw rod 10 is installed at the lower side of the servo motor 9, a slider 11 is installed at the bottom end of the screw rod 10, a brush plate 12 is installed at the lower side of the slider 11, and a brush roller 13 is installed at one side of the brush plate 12 close to the gate body 3. The brush roller 13 is symmetrically arranged with respect to the center line of the brush plate 12.

The working principle of the utility model is as follows: the manual rocker 6 or the driving motor 7 drives the reduction gear box 5 to rotate, the threaded rod 4 and the gate body 3 are driven to ascend or descend through the rotation of the reduction gear box 5, the gate body 3 can be conveniently and rapidly driven to ascend or descend along the support 2, when each gate starts, the servo motor 9 drives the sliding block 11, the brush plate 12 and the brush roller 13 to slide and ascend along the lead screw 10 through the lead screw 10, the outer side of the gate body 3 is cleaned, residual water marks and sludge on the gate body 3 are cleaned, the structural strength of the brush plate 12 can be increased through the brush roller 13, deformation of the brush plate 12 after encountering the sludge is avoided, the cleaning effect is reduced, and the other side of the gate can be cleaned by using the high-pressure water gun standing on the dam body 1 due to shallower water level.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. The foregoing is merely illustrative of the preferred embodiments of the utility model, and it is noted that there is virtually no limit to the specific structure which may be imposed by those skilled in the art without departing from the spirit of the utility model, and that modifications, adaptations, or variations of the foregoing features may be combined in a suitable manner; such modifications, variations and combinations, or the direct application of the inventive concepts and aspects to other applications without modification, are contemplated as falling within the scope of the present utility model.

Claims (6)

1. A open and close gate for hydraulic and hydroelectric engineering, its characterized in that: including dam body (1) and servo motor (9), support (2) are installed to the inboard of dam body (1), and gate body (3) are installed to the inboard of support (2), connecting rod (31) are installed to the top of gate body (3), threaded rod (4) are installed through the pivot to the top of connecting rod (31), reduction gearbox (5) are installed to the last half of threaded rod (4), and hand rocker (6) are installed on the right side of reduction gearbox (5), driving motor (7) are installed in the left side of reduction gearbox (5), protection casing (8) are installed to the top of dam body (1), servo motor (9) are installed in the top of dam body (1), and lead screw (10) are installed to the below of servo motor (9), slider (11) are installed to the bottom of lead screw (10), and brush board (12) are installed to the below of slider (11), brush roller (13) are installed to one side that brush board (12) is close to gate body (3).

2. The open-close gate for hydraulic and hydroelectric engineering according to claim 1, wherein: and the gate body (3) and the connecting rod (31) are integrally welded.

3. The open-close gate for hydraulic and hydroelectric engineering according to claim 1, wherein: the threaded rod (4) and the dam body (1) are arranged vertically, and a rotary installation structure is formed between the threaded rod (4) and the dam body (1) through a reduction gearbox (5).

4. The open-close gate for hydraulic and hydroelectric engineering according to claim 1, wherein: two lead screws (10) are symmetrically arranged about the central line of the dam body (1), and the lead screws (10) and the dam body (1) are mutually perpendicular.

5. The open-close gate for hydraulic and hydroelectric engineering according to claim 1, wherein: a sliding installation structure is formed between the sliding block (11) and the dam body (1) through the screw rod (10), and the sliding block (11) and the brush plate (12) are integrally welded.

6. The open-close gate for hydraulic and hydroelectric engineering according to claim 1, wherein: the brush rollers (13) are symmetrically arranged in two with respect to the center line of the brush plate (12).

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