KR200401283Y1 - Water Hammer Protection unit of Siphon Spillway - Google Patents

Abstract

The present invention relates to a device for absorbing water hammer pulsation in the siphon channel, more specifically, to form a pulsation absorption tank integrally with the water hammer pulsation absorption tube to improve the robustness, and also to absorb and mitigate noise and water hammer pulsation. A water hammer pulsation absorber. The configuration of the present invention, the upper inclined tube formed upward from the reservoir to the upper end of the bank, the connecting pipe extending from the upper inclined tube over the upper end of the bank, and the lower inclined downward formed along the slope of the bank in the connector In a siphon channel including a pipe, a pulsation absorption tank formed on the outer upper side of the connecting pipe or the lower inclined pipe, and a through hole for connecting between the connecting pipe or the lower inclined pipe and the pulsation absorption tank. Characterized in that it comprises a.

The water hammer pulsation absorber of the present invention can mitigate the water hammer pulsation and water hammer action with a simple configuration, and the water hammer pulsation absorber can be firmly fixed to the waterway so as to be robust against external shocks. The water hammer pulsation absorbing device has an effect of preventing unnecessary occupying a lot of space on the outside of the channel and enabling the same function in a small space.

Description

Water Hammer Protection unit of Siphon Spillway

The present invention relates to a device for absorbing water hammer pulsation in the siphon channel, more specifically, to form a pulsation absorption tank integrally with the water hammer pulsation absorption tube to improve the robustness, and also to absorb and mitigate noise and water hammer pulsation. A water hammer pulsation absorber.

In general, the siphon channel is inserted at both ends of the inverted U-shaped pipe into the liquid at high and low places on the banks of dams and reservoirs. It is a device that allows you to continue to flow to a higher place while sucking up to a higher place.

That is, the water level of the reservoir rises and the thin water flow in the initial stage beyond the inlet of the upper inclined pipe of the siphon flows down the downstream of the lower inclined pipe of the siphon channel and causes a rapid to rush to the outlet surface of the lower inclined pipe. At this time, the bubble accompanying the water flows to the surface of the inside of the outlet and burst to join the air inside the siphon Yeosu channel to increase the internal air pressure of the channel.

At this time, since the reservoir level is rising, the amount of water flow increases so that the air inside the siphon channel is compressed as much as the volume of the water stream, and at the outlet, a repair jump occurs to block the outlet. It is compressed and tries to expand through air pressure to both the inlet and outlet.

From this point, the reservoir level rises sharply, the exclusion volume becomes relatively small, and if the reservoir level rises continuously, the induction of the siphon action is radically driven by pushing the air pressure inside the siphon.

As such, when the siphon acts, water descends to the downstream inclined tube past the outlet of the siphon, causing a lot of noise and water hammer. In addition, as the water sucked up into the current flow siphon flows through the negative pressure part, the tiny gas particles contained in the water collapse under the equilibrium condition, causing the bubbles to expand rapidly, and at the same time, the vaporization phenomenon occurs as a collapsed fog. The noise and vibration from the water hammer (Water Hammer) phenomenon occurs.

In this water hammer phenomenon, even when water containing bubbles flows into the siphon channel, rapid expansion and water supply shaft progress according to the inflection point of the tube, causing pressure waves in the liquid. The pressure wave rebounds back toward the siphon inlet, and then returns again and again, until it dissipates as friction between the pipe wall and the liquid.

In addition, the water hammer is a phenomenon in which a round is generated in various parts, and the mutual rise and offset each other, the impact pressure has a problem that causes various instrument damage. In addition, when the air-flowing water stream reaches the static pressure part near the surface of the outlet of the siphon channel, the bubble is rapidly compressed and broken, and the force acting downstream of the place where the bubble is crushed is very large, where the flow direction changes rapidly. There was a problem that the erosion change phenomenon occurs.

When the action of the siphon is completed, a whirlwind and a vortex returning counterclockwise are generated at the liquid surface above the inlet of the siphon, and the outside air is sucked into the siphon by a hole formed in the center of the vortex. In this case, the noise is large and the siphon is suddenly changed into a bubble water stream, the amplitude of the water hammer pulsation is large, and the expectation of the water flow rate is greatly lowered.

Therefore, there is a need for an apparatus for preventing such a water hammer phenomenon. Conventional techniques devised to solve the water hammer phenomenon are shown in FIGS. 1 and 2. 1 is a side cross-sectional view showing a siphon channel and a conventional water hammer pulsation absorber, Figure 2 is a perspective view showing a conventional water hammer pulsation absorber and its interior.

1 and 2, the upper inclined tube 10, the connecting tube 20, and the lower inclined tube 30 are positioned over the left and right sides of the embankment 6. The upstream water 2 flows down the dike 6 to the downstream 4 by the siphon action. In order to reduce the water hammer pulsation, water hammer phenomenon generated at this time is provided with a water hammer pulsation absorber (60). This water hammer pulsation absorber 60 is composed of a horizontal cylindrical tank 62 and two outflow vertical pipe (64).

The tank 62 has a buffer function in the change of air pressure in the inside, and when a severe air pressure difference occurs in the channel, the water enters into the inner space of the sealed tank 62 through the inflow and outflow pipe 64. It also releases and alleviates sudden changes in air pressure.

In addition, the water hammer pulsation absorber 60 formed at the lower portion of the lower inclined tube 30 has a pair of inflow and outflow vertical pipes 64 so that the water in the channel is absorbed and flows back at a very slow speed. It passes through the water in Yeosu and recombines with water, and the siphon action is completed and flows in the downstream direction.

However, since the conventional water hammer pulsation absorber has to form a separate outflow and inflow vertical tube 64, it is cumbersome to design, manufacture, and somewhat uncomfortable to overcome the impact during extreme water hammer phenomenon.

The present invention has been made in order to solve the above problems, the object of the present invention is to improve the shape of the water hammer pulsation absorber, to improve the strength against external impact, and to provide a water hammer pulsation absorber more easy to install and construction do.

The configuration of the present invention for achieving the above object, the upper inclined tube formed upward from the reservoir to the upper end of the bank, the connection pipe extending from the upper inclined tube over the upper end of the bank, and the bank of the bank A siphon channel including a downward inclined tube formed downward along the slope, the pulsation absorption tank formed on the outer upper side of the connecting tube or the lower inclined tube, and the connecting tube or the downward inclined tube and the pulsation absorption tank It characterized in that it comprises a through-hole for connecting between the.

One end is located above a predetermined level above the full water level of the upper inclined tube side, the other end penetrates through the connecting pipe or the lower inclined tube, and the central portion of both ends is formed to be bent to have a predetermined height upward water hammer pulsation absorption It further comprises a tube.

The pulsation absorption tank is characterized in that it is provided in a form surrounding the other end side of the water hammer pulsation absorption tube, outside the connection point of the water hammer pulsation absorption tube and the connecting pipe or the lower inclined pipe.

The through hole formed between the pulsation absorption tank and the connecting pipe or the lower inclined pipe is formed in the lowest position of the surface of the connecting pipe or the lower inclined pipe contacting the interior of the pulsation absorption tank. do.

Or between an upward inclined tube formed upward from the reservoir to the top of the dike, a connecting tube extending from the upper inclined tube over the top of the dike, and a downward inclined tube formed downward along the slope of the dike in the connecting tube. In the pawn channel, one end is positioned above a water level above the upper inclined tube side, the other end penetrates through the connecting pipe or the lower inclined tube, and the central portions of both ends are bent to have a predetermined height upward. Characterized in that it comprises a water hammer pulsation absorption tube is formed.

Hereinafter, the configuration of the present invention will be described in detail with reference to an embodiment of the present invention shown in the accompanying drawings.

Figure 3 is a side cross-sectional view showing a siphon channel and the water hammer pulsation absorber of the present invention, Figure 4 is a perspective view showing the water hammer pulsation absorber of the present invention and its interior. 3 and 4, the water hammer pulsation absorber 70 of the present invention is formed integrally surrounding the end of the water hammer pulsation absorption tube 40 at the site where the water hammer pulsation absorption tube 40 and the connection pipe 20 meet. It is.

The water hammer pulsation absorber 70 is formed by attaching the lower side of the cylindrical tank 72 to the outside of the connecting pipe 20 or the lower inclined pipe 30. The tank 72 is wrapped in a larger diameter than the water hammer pulsation absorption tube 40, the inside is formed of an empty space and is attached to the connecting pipe (20). The connection pipe 20 is formed with a through hole 74 connected to the inside of the tank 72.

The through hole 74 is formed on the lowest side of the outer surface of the connection pipe 20 in contact with the inside of the tank 72, and rides through the through hole 74 without any water remaining in the tank 72. (20) Let it flow down again. The space inside the tank 72 is only connected to the inside of the connection pipe 20 through the through hole 74, but is not directly connected to the water hammer pulsation absorption pipe 40 or the outside.

The water hammer pulsation absorber 70 does not need a separate outflow and outflow vertical pipe, and the construction is easy because the same function only by forming the through-hole 74. In addition, since the tank 72 is coupled with the water hammer pulsation absorption tube 40, it is also robust to external shocks.

The water hammer pulsation absorption tube 40 is an upright U-shaped bent tube, the lower opening of one end being positioned about 30 to 70 mm above the full water level of the reservoir, and the other end penetrating through the connecting pipe 20. The middle portion of the stage is configured to soar upwards.

When the water level pulsation absorption tube 40 is slightly higher than the water level, the lower opening of the water hammer pulsation absorption tube 40 is blocked, and the inside of the water hammer pulsation absorption tube 40 is opened only toward the connection pipe 20. When the water hammer pulsation occurs in the connecting pipe 20, the air trapped in the water hammer pulsation absorption tube 40 expands and contracts by the water hammer pulsation, and serves to mitigate the water hammer pulsation.

Figure 5 is a side cross-sectional view showing the operation of the water hammer pulsation absorber of the present invention. Referring to FIG. 5, (a) shows the inside of the water hammer pulsation absorber 70 from the side, and (b) shows the action and operation in the water hammer pulsation absorber 70 when water hammer pulsation occurs. The through hole 74 is formed at the lowest side and the side side of the connecting pipe 20 so that no water remains in the tank 72.

In the case where the water flow is rapidly generated in the connecting pipe 20 and the water hammer pulsation occurs, water is filled into the tank 72 through the through hole 74 of the connecting pipe 20. As the water filled inside moves up and down as in A, the air pressure in the sealed tank 72 expands and compresses, thereby weakening the water hammer in the sealed space.

6 is a cross-sectional view showing the structure of the water hammer pulsation absorption device of the present invention. Referring to FIG. 6, after a portion of the water flow in the connection pipe 20 flows into the tank 72, the water flows through the through hole 74 as shown in B, and exits into the connection pipe 20. Since the tank 72 is formed integrally with the water hammer pulsation absorption tube 40, it can be firmly fixed to each other, there is no need for a separate column or vertical pipe for the inflow and outflow, construction is quick and easy.

7 is a side cross-sectional view showing another embodiment of the water hammer pulsation absorber of the present invention, Figure 8 is a cross-sectional view showing another embodiment of the water hammer pulsation absorber of the present invention. 7 and 8, the water hammer pulsation absorber of the present invention composed of a double structure of the water hammer pulsation absorber 70 and the water hammer pulsation absorber tube 40 is superior in installation robustness and performance compared to the conventional water hammer pulsation absorber. . In particular, the other side of the water hammer pulsation absorber (70) consisting of a tank-type space is completely enclosed and the other side is in contact with the surface of the water pulsation pulsation absorption tube 40, which allows a somewhat fluid air pressure change at the same time, more effectively water hammer pulsation Can be adjusted.

Water hammer pulsation absorption tube 40 is 30 ~ 70mm away from the water surface like the B portion, when the water level is increased, the water pulsation pulsation absorption tube 40 opening of the B portion is blocked by the water surface. Therefore, the air therein is located in a sealed space, the air expands, contracts and serves to mitigate the water hammer.

The water hammer pulsation absorber of the present invention has an effect of mitigating water hammer and water hammer action with a simple configuration.

In addition, the present invention provides a structure that allows the water hammer pulsation absorber to be firmly fixed to the waterway, has the effect of being robust to external shocks.

In addition, the present invention has the effect of preventing the water hammer pulsation absorber from occupying a lot of space unnecessarily on the outside of the channel, and can achieve the same function even in a small space.

1 is a side cross-sectional view showing a siphon channel and a conventional water hammer pulsation absorber.

2 is a perspective view showing a conventional water hammer pulsation absorber and its interior.

Figure 3 is a side cross-sectional view showing a siphon channel and the water hammer pulsation absorption device of the present invention.

Figure 4 is a perspective view showing the water hammer pulsation absorption device and its interior of the present invention.

Figure 5 is a side cross-sectional view showing the operation of the water hammer pulsation absorber of the present invention.

6 is a cross-sectional view showing the structure of the water hammer pulsation absorption device of the present invention.

Figure 7 is a side cross-sectional view showing another embodiment of the water hammer pulsation absorption device of the present invention.

8 is a cross-sectional view showing another embodiment of the water hammer pulsation absorption device of the present invention.

<Description of Signs of Major Parts of Drawings>

10: upward inclined tube 12: inlet

20: connector 30: downward inclination pipe

32: outlet 40: water hammer pulsation absorption tube

42: valve 50: water level control pipe

60: water hammer pulsation absorber 62: tank

64: outflow and outflow vertical pipe 70: water hammer pulsation absorber

72: pulsation absorption tank 74: through hole

Claims (5)

An upward inclined tube formed upward from the reservoir to the top of the embankment, A connecting pipe extending from the upward inclined pipe and over the top of the embankment; and In the siphon channel including a downward inclined tube formed downward along the slope of the bank in the connecting pipe, A pulsation absorption tank formed on the outer upper side of the connecting pipe or the lower inclined pipe, and And a through hole for connecting the connection pipe or the lower inclined pipe to the pulsation absorption tank. The method of claim 1, One end is located above a predetermined height above the full water level of the upper inclined tube side, The other end is penetrated through the connecting pipe or the lower inclined pipe, Water central pulsation absorbing device further comprises a water hammer pulsation absorbing tube is formed to be bent to have a predetermined height upward. The pulsation absorption tank of claim 2, wherein the pulsation absorption tank is: Outside the connection point of the water hammer pulsation absorption pipe and the connecting pipe or the lower inclined pipe, The water hammer pulsation absorber of the siphon yeosu channel characterized in that it is provided in a form surrounding the other end side of the water hammer pulsation absorption tube. The method according to any one of claims 1 to 3, The through hole formed between the pulsation absorption tank and the connecting pipe or the lower inclined pipe is: The water hammer pulsation absorber of the siphon channel, characterized in that formed in the lowest position of the surface of the connecting pipe or the lower inclined pipe in contact with the inside of the pulsation absorption tank. An upward inclined tube formed upward from the reservoir to the top of the embankment, A connecting pipe extending from the upward inclined pipe and over the top of the embankment; and In the siphon channel including a downward inclined tube formed downward along the slope of the bank in the connecting pipe, One end is located above a predetermined height above the full water level of the upper inclined tube side, The other end is penetrated through the connecting pipe or the lower inclined pipe, Water central pulsation absorber, characterized in that the central portion of the both ends comprises a water hammer pulsation absorption tube formed bent to have a predetermined height upward.