阅读说明：本技术 一种工程用分流器 (Shunt for engineering ) 是由 江启龙 于 2020-11-29 设计创作，主要内容包括：本发明公开了一种工程用分流器,其结构包括主流管道、分流球,主流管道与分流球相连接,分流球由球腔、壁层、分流装置、过渡腔、弧形过渡端构成,壁层所围成的腔体为球腔,球腔内设有分流装置,分流装置贯穿壁层,弧形过渡端与主流管道相通,弧形过渡端与过渡腔相连接,过渡腔与分流装置相通,本发明的有益效果：通过转轴旋转牵引联动轴随之旋转,使得两个阻流板相向运动并连接,从而将从过渡腔流进分流管道的水流量进行阻挡,使得进入分流槽的水流变小,从而分流槽内流水的水位线会下降而恢复正常,有效保障分流槽进行水流分流引导的过程中,水流不会溢出避免造成资源浪费。(The invention discloses a flow divider for engineering, which structurally comprises a main flow pipeline and a flow dividing ball, wherein the main flow pipeline is connected with the flow dividing ball, the flow dividing ball consists of a ball cavity, a wall layer, a flow dividing device, a transition cavity and an arc transition end, the cavity surrounded by the wall layer is the ball cavity, the flow dividing device is arranged in the ball cavity, the flow dividing device penetrates through the wall layer, the arc transition end is communicated with the main flow pipeline, the arc transition end is connected with the transition cavity, and the transition cavity is communicated with the flow dividing device, so that the flow divider has the beneficial effects that: the universal driving shaft is rotationally pulled through the rotation of the rotating shaft to rotate along with the universal driving shaft, so that the two spoilers move in opposite directions and are connected, the water flow flowing into the diversion pipeline from the transition cavity is blocked, the water flow entering the diversion channel is reduced, the water level line of the flowing water in the diversion channel can be reduced and recovered to be normal, the diversion channel is effectively guaranteed to conduct the in-process of diversion guiding, and the water flow cannot overflow to avoid causing resource waste.)

1. An engineering shunt, its characterized in that: its structure includes mainstream pipeline (1), reposition of redundant personnel ball (2), mainstream pipeline (1) is connected with reposition of redundant personnel ball (2), reposition of redundant personnel ball (2) comprises ball chamber (a), wall layer (b), diverging device (c), transition chamber (d), arc transition end (e), the cavity that wall layer (b) enclose is ball chamber (a), be equipped with diverging device (c) in ball chamber (a), diverging device (c) runs through wall layer (b), arc transition end (e) communicates with each other with mainstream pipeline (1), arc transition end (e) is connected with transition chamber (d), transition chamber (d) communicates with each other with diverging device (c).

2. The engineering diverter according to claim 1, wherein: the flow dividing device (c) is composed of a flow dividing pipeline (c1), a connecting end (c2), an annular cavity (c3), spoilers (c4) and a linkage shaft (c5), the flow dividing pipeline (c1) is located in the center of the annular cavity (c3), the spoilers (c4) are arranged in the annular cavity (c3), the connecting end (c2) is connected with a transition cavity (d), one end of each spoiler (c4) is penetrated through the linkage shaft (c5), the linkage shaft (c5) is arranged in the annular cavity (c3), and the flow dividing pipeline (c1) penetrates through a wall layer (b).

3. The engineering diverter according to claim 1, wherein: the flow dividing pipeline (c1) is composed of a lifting plate (c11), a rotating shaft (c12), a floating ball (c13), a connecting rod (c14), a flow dividing groove (c15), an arc rod (c16), an arc cavity (c17) and a solid layer (c18), the lifting plate (c11) is mechanically connected with the rotating shaft (c12), the lifting plate (c11) is fixedly connected with the arc rod (c16), the connecting rod (c14) is mechanically connected with the arc rod (c16), the floating ball (c13) is arranged in the flow dividing groove (c15), the arc rod (c16) is installed in the arc cavity (c17), and the solid layer (c18) is tightly attached to the inner wall of the flow dividing groove (c 15).

4. An engineering diverter according to claim 3, wherein: the two solid layers (c18) are arranged and are arranged in a symmetrical structure, the two solid layers (c18) are fixed on the inner wall of the diversion channel (c15), so that the diversion channel (c15) can be arranged in a V shape through the liquid part, and the diversion channel (c15) is communicated with the transition cavity (d).

5. An engineering diverter according to claim 3, wherein: the floating ball (c13) is a hollow structure, so that the floating ball can always float on the surface of the liquid under the buoyancy action of the liquid.

6. An engineering diverter according to claim 3, wherein: the rotating shaft (c12) is installed on the side, facing outwards, of the top end of the solid layer (c18), and a waterproof connecting layer is arranged in the connection between the rotating shaft (c12) and the lifting plate (c11) and the solid layer (c 18).

7. The engineering diverter according to claim 2, wherein: the spoiler (c4) is a solid structure, and the two spoilers (c4) are connected after rotating towards each other, so that the flow distribution pipeline (c1) is shielded.

Technical Field

The invention relates to the field of engineering, in particular to a shunt for engineering.

Background

The plumbing is in municipal works's application, the different applications at same water source and the ascending water demand of a plurality of directions, need use the splitter box and shunt the water source, thereby realize the multidirectional guide use of water, the water that the reposition of redundant personnel goes is direct use of coming into operation, there is not the problem of holding, consequently, in order to reduce the material of reposition of redundant personnel pipeline, the form through the splitter box is shunted and is guided, and carry out the in-process that rivers guide carried with the splitter box, the water yield control of reposition of redundant personnel is not good can lead to water to spill over from the splitter box, cause the waste.

Disclosure of Invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme: the utility model provides a shunt for engineering, its structure includes mainstream pipeline, reposition of redundant personnel ball, the mainstream pipeline is connected with the reposition of redundant personnel ball, the reposition of redundant personnel ball comprises ball chamber, wall layer, diverging device, transition chamber, arc transition end, the cavity that the wall layer encloses is the ball chamber, the ball intracavity is equipped with diverging device, diverging device runs through the wall layer, the arc transition end communicates with each other with the mainstream pipeline, the arc transition end is connected with the transition chamber, the transition chamber communicates with each other with diverging device.

As a further optimization of the invention, the flow dividing device comprises flow dividing pipelines, connecting ends, an annular cavity, two flow baffles and a linkage shaft, wherein the flow dividing pipelines are positioned in the center of the annular cavity, the flow baffles are arranged in the annular cavity, the two flow baffles are arranged and are symmetrically arranged about the flow dividing pipelines, the connecting ends are connected with the transition cavity, the linkage shaft penetrates through one ends of the flow baffles, the linkage shaft is arranged in the annular cavity, the flow dividing pipelines penetrate through the wall layer, and the linkage shaft is matched with the flow dividing pipelines.

As a further optimization of the invention, the flow distribution pipeline is composed of a lifting plate, a rotating shaft, floating balls, connecting rods, a flow distribution groove, arc-shaped rods, an arc-shaped cavity and a solid layer, wherein the lifting plate is mechanically connected with the rotating shaft, the lifting plate is fixedly connected with the arc-shaped rods, the connecting rods are arranged at one ends of the arc-shaped rods far away from the lifting plate, the connecting rods are mechanically connected with the arc-shaped rods, the floating balls are arranged in the flow distribution groove, the two floating balls are arranged and are arranged in a symmetrical structure, the arc-shaped rods are arranged in the arc-shaped cavity, the solid layer is tightly attached to the inner wall of the flow distribution groove.

As a further optimization of the invention, two solid layers are arranged and are arranged in a symmetrical structure, the two solid layers are fixed on the inner wall of the diversion channel, so that the diversion channel can be arranged in a V shape through the liquid part, and the diversion channel is communicated with the transition cavity.

As a further optimization of the invention, the floating ball is of a hollow structure, so that the floating ball can always float on the surface of the liquid under the buoyancy action of the liquid.

As a further optimization of the invention, the rotating shaft is arranged on the outward side of the top end of the solid layer, and the joint between the rotating shaft and the lifting plate and the solid layer is provided with a waterproof joint layer, so that liquid is prevented from entering the arc-shaped cavity.

As a further optimization of the invention, the flow blocking plates are of a solid structure, and the two flow blocking plates are connected after rotating in opposite directions, so that the flow dividing pipeline is shielded, and the flow of liquid entering the flow dividing pipeline is reduced.

Advantageous effects

The invention relates to a flow divider for engineering, which is characterized in that two flow baffles are in a separated state in an initial state, a flow dividing groove is in a normal unblocked state at the moment, water in a main flow pipeline enters a transition cavity through an arc transition end and respectively enters different flow dividing pipelines from the transition cavity to realize flow division, the divided water is guided by the flow dividing groove to be conveyed out for use, in the process, a floating ball floats on the water surface all the time due to the buoyancy of the water in the flow dividing groove, when the water level of the water in the flow dividing groove rises, the floating ball is driven to move upwards, an arc rod is driven by a connecting rod to move along with the floating ball in the upward process, the arc rod pushes a lifting plate to rotate upwards around one end, connected with a rotating shaft, of the lifting plate, so that the inner wall of the flow dividing groove can be indirectly lifted, the water level is prevented from rising to overflow the flow dividing groove, and a linkage shaft, so that the two spoilers move towards each other and are connected, and the water flow entering the splitter box is reduced.

Compared with the prior art, the invention has the following advantages:

the water level can drive the floating ball to move upwards when rising, so that the floating ball pushes the lifting plates to move, and the two lifting plates move oppositely, thereby rising the water level line which can be flowed by water flow in the shunting groove and effectively preventing the water flow from overflowing;

the linkage shaft is driven to rotate along with the rotation of the rotating shaft, so that the two spoilers move in opposite directions and are connected, the water flow flowing into the diversion pipeline from the transition cavity is blocked, the water flow entering the diversion channel is reduced, the water level line of the flowing water in the diversion channel is reduced to be normal, the diversion channel is effectively ensured to not overflow in the process of conducting water diversion guidance on the diversion channel, and resource waste is avoided.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic structural diagram of an engineering diverter according to the present invention.

Fig. 2 is a structure diagram of a shunt ball of the engineering shunt according to the present invention.

Fig. 3 is a top view of fig. 2.

Fig. 4 is a structural view of a flow divider of the engineering flow divider according to the present invention.

Fig. 5 is a diagram of the operation state of fig. 4.

Fig. 6 is a structure diagram of a diversion pipeline of an engineering diverter according to the present invention.

In the figure, a main flow pipeline-1, a flow dividing ball-2, a ball cavity-a, a wall layer-b, a flow dividing device-c, a transition cavity-d, an arc transition end-e, a flow dividing pipeline-c 1, a connecting end-c 2, an annular cavity-c 3, a spoiler-c 4, a linkage shaft-c 5, a lifting plate-c 11, a rotating shaft-c 12, a floating ball-c 13, a connecting rod-c 14, a flow dividing groove-c 15, an arc rod-c 16, an arc cavity-c 17 and a solid layer-c 18.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easy to understand, the following description and the accompanying drawings further illustrate the preferred embodiments of the invention.

Example 1

Referring to fig. 1-6, the invention provides a flow divider for engineering, which structurally comprises a main flow pipeline 1 and a flow dividing ball 2, wherein the main flow pipeline 1 is connected with the flow dividing ball 2, the flow dividing ball 2 is composed of a ball cavity a, a wall layer b, a flow dividing device c, a transition cavity d and an arc transition end e, the cavity surrounded by the wall layer b is the ball cavity a, the flow dividing device c is arranged in the ball cavity a, the flow dividing device c penetrates through the wall layer b, the arc transition end e is communicated with the main flow pipeline 1, the arc transition end e is connected with the transition cavity d, and the transition cavity d is communicated with the flow dividing device c.

The flow dividing device c is composed of a flow dividing pipeline c1, a connecting end c2, an annular cavity c3, spoilers c4 and a linkage shaft c5, the flow dividing pipeline c1 is located in the center of the annular cavity c3, the spoilers c4 are arranged in the annular cavity c3, two spoilers c4 are arranged and are arranged in a symmetrical structure with respect to the flow dividing pipeline c1, the connecting end c2 is connected with a transition cavity d, one end of each spoiler c4 is penetrated by the linkage shaft c5, the linkage shaft c5 is arranged in the annular cavity c3, the flow dividing pipeline c1 penetrates through a wall layer b, and the linkage shaft c5 is matched with the flow dividing pipeline c1 to realize the aperture size control of the flow dividing pipeline c 1.

The flow dividing pipeline c1 is composed of a lifting plate c11, a rotating shaft c12, a floating ball c13, a connecting rod c14, a flow dividing groove c15, an arc rod c16, an arc cavity c17 and a solid layer c18, wherein the lifting plate c11 is mechanically connected with the rotating shaft c12, the lifting plate c11 is fixedly connected with an arc rod c16, one end, away from the lifting plate c11, of the arc rod c16 is provided with a connecting rod c14, the connecting rod c14 is mechanically connected with the arc rod c16, the floating ball c13 is arranged in the flow dividing groove c15, the floating ball c13 is provided with two symmetrical structures, the arc rod c16 is installed in the arc cavity c17, the solid layer c18 is arranged on the inner wall of the flow dividing groove c15, the rotating shaft c12 is mechanically connected with the linkage shaft c5, and the rotating shaft 12 drives the linkage shaft 5 to rotate along with the rotation so as to draw the flow dividing plate 4 c 737.

The two solid layers c18 are arranged and are arranged in a symmetrical structure, the two solid layers c18 are fixed on the inner wall of the diversion channel c15, so that the diversion channel c15 can be arranged in a V shape through the liquid part, and the diversion channel c15 is communicated with the transition cavity d.

The floating ball c13 is a hollow structure, so that the floating ball can always float on the surface of the liquid under the buoyancy action of the liquid.

The rotating shaft c12 is installed on the side, facing outwards, of the top end of the solid layer c18, and the joint between the rotating shaft c12 and the lifting plate c11 and the solid layer c18 is provided with a waterproof joint layer, so that liquid is prevented from entering the arc-shaped cavity c 17.

The spoiler c4 is a solid structure, and two spoilers c4 are connected after rotating towards each other, so as to shield the branch pipe c1, and reduce the flow rate of the liquid entering the branch pipe c 1.

In the initial state, the two spoilers c4 are in a separated state, at this time, the diversion trench c15 is in a normally unblocked state, water in the main flow pipeline 1 enters the transition cavity d through the arc transition end e, and enters different diversion pipelines c1 from the transition cavity d to realize diversion, the diverted water is guided through the diversion trench c15 to be conveyed out for use, in the process, due to buoyancy of water in the diversion trench c15, the floating ball c13 floats on the water surface, when the water level of water in the diversion trench c15 rises, the floating ball c13 is driven upwards, in the process that the floating ball c13 rises, the connecting rod c14 drives the arc lever c16 to move along with the floating ball c16, so that the arc lever c 6854 pushes the lifting plate c11 to rotate upwards around the end of the lifting plate c11 connected with the rotating shaft c12, thereby the inner wall of the diversion trench c15 can be indirectly lifted, the water level of the diversion trench c15 can be prevented from rising, and the rotating shaft c12 can pull the linkage shaft c5 to rotate upwards, so that the two spoilers c4 move towards each other and are connected, and the water flow entering the splitter box c15 becomes smaller.

While there have been shown and described what are at present considered the fundamental principles of the invention, the essential features and advantages thereof, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but rather, is capable of numerous changes and modifications in various forms without departing from the spirit or essential characteristics thereof, and it is intended that the invention be limited not by the foregoing descriptions, but rather by the appended claims and their equivalents.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.