CN219863077U - Hydraulic engineering pump station structure - Google Patents

Abstract

The utility model discloses a hydraulic engineering pump station structure, which comprises a bearing table, a guide piece, a lifting piece and a driving switch, wherein the guide piece is connected below the bearing table; the floating trigger assembly is connected to the guide piece in a sliding manner and can be electrically connected with the lifting piece under the action of buoyancy; the floating trigger component comprises a floating part and a trigger part, and the trigger part is connected to the floating part, so that the floating trigger component is driven to work by utilizing the action of the floating force of flood, and the lifting mechanism for driving the pump station room to lift is driven to move, so that the lifting mechanism can automatically lift along with the fluctuation of the flood, the problem that the flood submerges the pump station room and damages equipment in the pump station room is avoided, meanwhile, the continuous compression component can also ensure that the floating trigger component receives stable pressure of the floating force of the flood, the interference of external factors on the movement of the floating trigger component is avoided, and the real-time stable lifting of the pump station room is ensured.

Description

Hydraulic engineering pump station structure

Technical Field

The utility model relates to the technical field of hydraulic engineering, in particular to a hydraulic engineering pump station structure.

Background

The pump station is a device, engineering name pump and pump station engineering which can provide hydraulic power and pneumatic power with certain pressure and flow. And the general name of the buildings such as water inlet, water outlet, pump house and the like of the drainage and irrigation pump station.

The pump station room is generally built on the water side, when flood occurs, the pump station room is generally required to be driven to move upwards through the lifting mechanism, the internal facilities of the pump station room are prevented from being soaked and damaged by the flood, the existing pump station room lifting mechanism is generally required to be controlled manually, and the lifting mechanism is manually adjusted through manual monitoring.

The time of flood amplitude cannot be judged and predicted, operators are required to monitor and pay attention to in real time when flood damages to pump station rooms are prevented, the dependency on operators is high, time and labor are wasted, and when workers are not on site or fail to find flood in time, the flood is easy to submerge the pump station rooms, and damage is caused to equipment inside the pump station rooms.

In summary, the prior art still has the problem that the pump station room lifting mechanism generally needs manual control, has strong dependence on operators, is time-consuming and labor-consuming, and can not control the pump station room lifting in real time according to the flood fluctuation at the first time.

Disclosure of Invention

The utility model aims to provide a hydraulic engineering pump station structure, which solves the technical problems that in the prior art, a pump station room lifting mechanism generally needs manual control, has strong dependence on operators, is time-consuming and labor-consuming, and cannot control the lifting of a pump station room in real time according to the fluctuation of flood at the first time.

In order to solve the technical problems, the utility model specifically provides the following technical scheme: a hydraulic engineering pump station structure comprising:

the bearing table is used for bearing the pump station room;

the guide piece is connected below the bearing table and used for directional sliding of the bearing table;

the lifting piece is connected below the bearing table and is arranged in parallel with the guide piece, and the driving switch of the lifting piece is arranged at the bottom of the bearing table;

the floating trigger assembly is connected to the guide piece in a sliding manner and can be electrically connected with the lifting piece under the action of buoyancy;

the floating trigger assembly comprises a floating piece and a trigger piece, the trigger piece is connected to the floating piece, and the floating piece drives the trigger piece to be in contact electrical connection with a driving switch of the lifting piece under the action of buoyancy lifting, so that the lifting piece automatically drives the bearing platform to lift along the guide piece.

As a preferable mode of the utility model, at least four guide members are arranged, the four guide members are respectively connected at the corners of the bearing table, and the lifting member is positioned among the four guide members.

As a preferable scheme of the utility model, each guide piece is connected with one floating piece in a sliding way, a floating connecting piece is connected between two adjacent floating pieces, so that each floating piece is connected into a whole, and a trigger piece is arranged on any floating piece.

As a preferred embodiment of the present utility model, a continuous compression assembly is connected between each floating connector and the bottom of the bearing table.

As a preferred aspect of the present utility model, the continuous compression assembly includes an upper guide post, a lower guide post, and an elastic member;

the upper guide column is connected to the bottom of the bearing table;

the lower guide post is connected to the floating connecting piece, and the lower guide post and the upper guide post are in sliding connection;

the elastic piece is connected between the bearing table and the floating connecting piece, and is sleeved between the lower guide post and the upper guide post.

Compared with the prior art, the utility model has the following beneficial effects:

the utility model utilizes the action of the floating force of the flood to drive the floating trigger assembly to work, thereby driving the lifting mechanism of the pump station room to move, realizing that the lifting mechanism can automatically lift along with the fluctuation range of the flood, achieving the purpose of adjusting the height of the pump station room at the first time, and avoiding the problem that the flood floods the pump station room and damages the equipment in the pump station room.

Meanwhile, the continuous compression assembly can also ensure that the floating trigger assembly receives stable pressure of the buoyancy of flood, and avoids the interference of external factors on the motion of the floating trigger assembly, thereby ensuring the real-time stable lifting of the pump station room.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It will be apparent to those of ordinary skill in the art that the drawings in the following description are exemplary only and that other implementations can be obtained from the extensions of the drawings provided without inventive effort.

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a cross-sectional side view of the overall structure of the present utility model;

reference numerals in the drawings are respectively as follows:

1. a carrying platform; 2. a guide member; 3. a lifting member; 4. a float member; 5. a trigger; 6. a floating connection; 7. a continuous compression assembly;

71. an upper guide post; 72. a lower guide post; 73. an elastic member.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1, the utility model provides a hydraulic engineering pump station structure, which comprises a bearing table 1, a guide piece 2, a lifting piece 3 and a floating trigger assembly.

The bearing table 1, the bearing table 1 takes a round shape or a square shape as an example, and is used for bearing the pump station house, namely, the pump station house is built on the bearing table 1.

And a guide member 2 connected below the carrying platform 1 for directional sliding of the carrying platform 1, wherein the guide member 2 corresponds to a cylindrical structural member such as a sliding rod.

The lifting piece 3 is connected below the bearing table 1 and is arranged in parallel with the guide piece 2, and a driving switch of the lifting piece 3 is arranged at the bottom of the bearing table 1, wherein the lifting piece 3 can be an electric control lifting device such as a hydraulic electric telescopic rod.

The floating trigger assembly is slidably connected to the guide piece 2 and can be electrically connected with the lifting piece 3 under the action of buoyancy, wherein the floating trigger assembly comprises a floating piece 4 and a trigger piece 5, the trigger piece 5 is connected to the floating piece 4, and the floating piece 4 drives the trigger piece 5 to be in contact with a driving switch of the lifting piece 3 under the action of buoyancy lifting so that the lifting piece 3 automatically drives the bearing table 1 to ascend along the guide piece 2.

The touch connection between the trigger piece 5 and the driving switch is equivalent to the contact between the contact and the contact piece, when the contact is in contact with the contact piece, the contact is electrically connected with an external power supply, otherwise, when the contact is separated from the contact piece, the contact is disconnected with the external power supply, and the driving switch is automatically closed.

The pump station structure drives the floating trigger assembly to work by utilizing the action of the floating force of the flood, so that the lifting mechanism driving the pump station room to lift moves, the lifting mechanism can automatically lift along with the fluctuation range of the flood, and the problem that the flood floods the pump station room and damages equipment in the pump station room is avoided.

When detecting flood, when initial state, the float 4 floats above the surface of water, once the flood rises, under the effect of flood buoyancy, the rise of float 4 along with the rising of flood also synchronous, wherein, guide 2 has played spacing effect to the motion of float 4, along with the rising height of float 4, the rise that the trigger piece 5 that sets up on float 4 also can follow, once rising height reaches trigger piece 5 and drive switch contact, with external power supply electric connection, drive switch automatically opens, can drive lifting piece 3 normal motion, under the drive effect of lifting piece 3, the holistic rising along guide 2 of plummer 1 that lifting piece 3 drove, with the lifting of pump station room, after the lifting, the drive switch of plummer 1 bottom progressively separates with trigger piece 5, once the contact is separated with the external power source, drive switch automatic closure, drive pump station room 3 stops moving, as long as the rising of water does not rise, drive pump station room 3 can not continuously drive the room.

The pump station house can be lowered through manual control, so that the pump station house can be adjusted to a proper position according to the change of the flood water level.

In the rising process of the pump station house, stability is particularly important, and the stability and the safety of the main body structure of the pump station house can be ensured by stable rising.

Specifically, as shown in fig. 1-2, at least four guide members 2 are provided, and taking four guide members as an example, the four guide members 2 are respectively connected at each corner of the bearing table 1, that is, the four guide members 2 are distributed along the circular arc of the circular bearing table 1, and the lifting member 3 is located between the four guide members 2.

Through the spacing of four guide pieces 2 to plummer 1, guaranteed that plummer 1 whole each part can slide along the straight line, reduced the possibility of skew, and drive through middle lifting piece 3, wherein, four guide pieces 2 square formation distributes, and the intersection point position of the line of two sets of guide pieces 2 on the diagonal is the mounted position of lifting piece 3.

Due to the influence of stormy waves in the flood amplitude process, the heights of the flood at the ends of the four guide members 2 may have certain difference, so as to ensure the accuracy of detecting the flood amplitude.

Specifically, each guide member 2 is slidably connected with one floating member 4, and a floating connecting member 6 is connected between two adjacent floating members 4, so that each floating member 4 is connected into a whole, and a trigger member 5 is installed on any one floating member 4.

The floating member 4 and the floating connection member 6 are understood to be a kind of buoyant member having buoyancy.

Through the whole motion of the floating pieces 4 on four guide pieces 2, the single trigger piece 5 is moved, one of the floating pieces 4 is subjected to buoyancy in time, the single trigger piece 5 cannot move, and the whole motion can be realized only after the four floating pieces 4 are synchronously subjected to the buoyancy of the flood under the condition that the flood is fully lifted, so that the single trigger piece 5 is lifted, and the lifting of a pump station room is accurately realized.

Further, as shown in fig. 1-2, a continuous compression assembly 7 is connected between each floating connection 6 and the bottom of the load table 1.

Wherein the buoyancy of the flood to the float 4 is received by the continuous compression assembly 7, the interference of the wave formed by the wind wave to the float 4 is avoided,

specifically, as shown in fig. 2, the continuous compression assembly 7 includes an upper guide post 71, a lower guide post 72, and an elastic member 73; the upper guide post 71 is connected to the bottom of the bearing table 1; the lower guide post 72 is connected to the floating connecting piece 6, and the lower guide post 72 and the upper guide post 71 are in sliding connection; the elastic piece 73 is connected between the bearing table 1 and the floating connecting piece 6, and the elastic piece 73 is sleeved between the lower guide post 72 and the upper guide post 71.

The elastic member 73 may be understood as an elastic element such as a telescopic spring, when the wave formed by the wind waves impacts the floating member 4, the elastic member 73 may buffer a part of impact force, and the impact force drives the floating member 4 to move upwards, so that the trend that the wind waves rapidly lift the floating member 4 is avoided, and once the duration of the wind waves is small, the floating member 4 does not keep continuously rising, only the flood continuously rises, when the floating member 4 continuously receives the floating force of the rising, the elastic member 73 is continuously compressed, the space between the upper guide post 71 and the lower guide post 72 gradually decreases, and at this time, the floating member 4 continuously and stably slides until the triggering member 5 is electrically connected with the driving switch.

Wherein, when the upper guide post 71 is completely recovered in the lower guide post 72, the trigger member 5 can just contact with the driving switch controlling the movement of the lifting member 3.

The above embodiments are only exemplary embodiments of the present utility model and are not intended to limit the present utility model, the scope of which is defined by the claims. Various modifications and equivalent arrangements of this utility model will occur to those skilled in the art, and are intended to be within the spirit and scope of the utility model.

Claims (5)

1. A hydraulic engineering pump station structure, its characterized in that includes:

the bearing table (1) is used for bearing the pump station room;

the guide piece (2) is connected below the bearing table (1) and is used for directional sliding of the bearing table (1);

the lifting piece (3) is connected below the bearing table (1) and is arranged in parallel with the guide piece (2), and a driving switch of the lifting piece (3) is arranged at the bottom of the bearing table (1);

the floating trigger assembly is connected to the guide piece (2) in a sliding manner, and can be electrically connected with the lifting piece (3) under the action of buoyancy;

the floating trigger assembly comprises a floating piece (4) and a trigger piece (5), the trigger piece (5) is connected to the floating piece (4), the floating piece (4) is driven under the buoyancy lifting action, the trigger piece (5) is electrically connected with a driving switch of the lifting piece (3) in a contact mode, so that the lifting piece (3) is automatically driven, and the bearing table (1) is lifted along the guide piece (2).

2. A hydraulic engineering pump station structure according to claim 1, wherein,

the guide pieces (2) are at least four, the four guide pieces (2) are respectively connected to the corners of the bearing table (1), and the lifting piece (3) is located between the four guide pieces (2).

3. A hydraulic engineering pump station structure according to claim 2, wherein,

each guide piece (2) is connected with one floating piece (4) in a sliding manner, a floating connecting piece (6) is connected between every two adjacent floating pieces (4), so that each floating piece (4) is connected into a whole, and a trigger piece (5) is arranged on any one floating piece (4).

4. A hydraulic engineering pump station structure according to claim 3, wherein,

a continuous compression assembly (7) is connected between each floating connecting piece (6) and the bottom of the bearing table (1).

5. A hydraulic engineering pump station structure according to claim 4, wherein,

the continuous compression assembly (7) comprises an upper guide post (71), a lower guide post (72) and an elastic piece (73);

an upper guide post (71) connected to the bottom of the bearing table (1);

the lower guide post (72) is connected to the floating connecting piece (6), and the lower guide post (72) is in sliding connection with the upper guide post (71);

the elastic piece (73) is connected between the bearing table (1) and the floating connecting piece (6), and the elastic piece (73) is sleeved between the lower guide post (72) and the upper guide post (71).