RU2446319C2 - Siphon - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: proposed siphon comprises intake and discharge tubes 2, 3, fluid level gage tube 4, feed tube 5 with cock 6 and branch pipe 7, intake cover 8 and manifold 10. The latter consists of casing 11, barrel 14 and cover 17 furnished with outlet branch pipe 18. Casing 11 is made up of cylinder divided by baffle 21 with radial and axial holes 22, 23, into top chamber 19 with inlet branch pipe 12 and bottom chamber 20. Intake cover 8 is divided by baffle 25 into top and bottom chambers 26, 27 communicated via filling tube 28. Lower ends of suction tube 2, discharge tube 3 and pressure gage tube 4 are arranged in manifold 10, while their upper ends are arranged in bottom chamber of intake cover 8.

EFFECT: simplified and compact design, higher efficiency.

4 cl, 6 dwg

Description

The invention relates to hydraulic devices and can be used in many sectors of the national economy for the automatic conversion of a continuous flow of fluid into a discrete flow with a high flow rate. More specifically, this invention can find application for a dosed supply of liquid in the food and chemical industries, in irrigation systems and in various water washing devices.

A siphon is known, which is part of an irrigation device and consists of a suction and drain elbows, the last of which is connected to a collector, a supply pipe with a tap and a siphon charging mechanism consisting of an ejector of the mentioned collector and a liquid level sensor tube in a storage tank with a suction and drain parts. The siphon also contains a breather tube. The ends of the sensor tube passing through the hole in the wall of the storage tank and the breather tube are inserted into the nests in the collector cover, while the ejector of the siphon charging mechanism is made in the form of a tube with holes in its wall (RU 2175831 C2, 11/20/2001).

The disadvantage of this siphon is the design complexity and non-compactness, which leads to the need to make a number of holes and windows in the walls, flange and cover of the storage tank and, therefore, to complicate installation. In this siphon design, part of the ejector function is performed by one of the irrigation pipelines with outlets, which leads to unstable operation of the siphon as a whole due to possible clogging of outlets. The siphon does not have a vacuum breakdown mechanism, as a result of which its operability is ensured in a narrow range of input flow rate changes, which sharply reduces its applicability in various sectors of the national economy.

The closest analogue of the invention is a siphon containing a suction and drain pipe, a liquid level sensor tube, a supply pipe with a tap and elbow, a receiver cover and a collector consisting of a housing, a glass and a cover with an outlet pipe (RU 2306460 C1, 09/20/2007 ) A drain pipe of a known siphon is connected to a collector. The siphon charging mechanism consists of an ejector, the aforementioned collector and a liquid level sensor tube with suction and drain parts. The supply tube is made with the main and additional outputs, and the liquid level sensor tube is equipped with a chamber located under the main outlet of the supply tube, divided by a partition into the upper and lower cavities, communicating with each other by a channel with the possibility of forming a lower cavity of the air-water shutter, in addition, the suction a portion of the liquid level sensor tube is located in the upper part of the chamber, and a hole above the level of the suction part is made on its drain part.

The disadvantages of this siphon are the design complexity, non-compactness and performance in a narrow range of changes in the input flow due to the lack of a vacuum breakdown mechanism in its design. A narrow range of changes in the input flow rate does not allow accumulation and discharge of liquid from the tank when the value of the input flow rate is higher than 15% of the flow rate (Q _drain is the discharge rate of the siphon liquid before the vacuum breaks) the drain of the siphon. The low value of the input flow rate (≤0.15 Q _drain ) is explained by the fact that when the liquid level in the tank decreases, when the liquid level approaches the level of the lower cut of the suction tube, air enters the working cavity of the siphon, which drastically reduces the siphon flow rate to Q _min but does not disrupt its vacuum. With the input flow rate of ≥Q _{min, the} mode of supplying liquid to the storage tank and the drain from it are balanced, and the accumulation-drain mode is terminated, which is a failure of the siphon. When installing this siphon, the suction elbow and the chamber are installed in the storage tank, which leads to the need for refinement (window cutting) of the tank lid and, therefore, to complicate the manufacture.

The objective of the invention is to simplify the design of the siphon, reducing the number of technological operations in the manufacture and installation by achieving compactness and ensuring operability while increasing the range of variation of the input flow rate.

The technical result is achieved by the fact that in a siphon containing a suction and drain pipes, a liquid level sensor tube, a supply pipe with a tap and elbow, a receiver cover and a collector consisting of a body, a glass and a cover with an outlet pipe, according to the invention, the collector body in the form of a cylinder divided by a partition with axial and radial openings into the upper ones with an inlet pipe and lower cavities, and the receiver cover is divided by a partition into upper and lower cavities communicated with each other by the filling tube, when the lower ends of the suction tube, drain tube and liquid level sensor tube are installed in the manifold, and their upper ends are in the lower cavity of the receiver, in addition, the lower ends of the drain tube, suction tube and liquid level sensor tube are installed, respectively, in the glass through the axial hole of the partition wall of the collector body, in the collector above the level of the inlet pipe and in the radial hole of the collector partition, and the upper ends are installed in the lower cavity of the receiver cover, the upper ends of the suction tube and the liquid level sensor tubes are installed at the same level, the drain tube section is installed below the upper cut of the suction tube, and the holes on the walls of the liquid level sensor tube are made below the upper cut of the drain tube, the siphon is equipped with a vacuum separation mechanism made in the form of a microtube, the upper end which is installed above the upper level of the receiver cover, and the lower end is made in the form of a loop, installed in the siphon cavity and directed upward, while the lower level of the loop is installed above the level of the inlet pipe of the housing the collector, and the lower section of the filling tube is installed below the level of the microtube loop to break the siphon vacuum.

The invention is illustrated by drawings, where figure 1 shows a General view of the siphon, figure 2 is a structural diagram of a siphon, figure 3 is a structural diagram of a siphon with storage capacity, figure 4 is a section aa in figure 2, figure 5 is a General view of the siphon with the storage capacity in the context of figure 6 - view B in figure 5.

The siphon 1 (Fig. 1) contains a suction and drain pipe 2, 3, a liquid level sensor 4, a supply pipe 5 with a tap 6 and an elbow 7, a receiver cover 8, a fixing nut 9, and a manifold 10 consisting of a housing 11 s the inlet pipe 12 and the eye 13, the glass 14 with the ribs 15 and the axial hole 16 and the cover 17 with the outlet pipe 18 (figure 2 and figure 3). The housing 11 is divided into upper and lower cavities 19, 20 by a partition 21 with axial and radial holes 22, 23.

The receiver cover 8 has an eyelet-connector 24 (Fig. 4) and is divided by a partition 25 into upper and lower cavities 26, 27 communicated with each other by a filling tube 28. The lower ends of the drain tube 3, the suction tube 2 and the liquid level sensor 4 are installed, respectively, in the glass 14 through the axial hole 22 of the baffle 21 of the housing 11, in the upper cavity 19 above the level of the inlet pipe 12 and in the radial hole 23 of the collector baffle 10. Their upper ends are installed in the lower cavity 27 of the cover of the receiver 8. The upper ends of the suction tube 2 and the sensor tube 4 are installed at the same level, the drain pipe 3 is installed below the upper cut of the suction pipe 2, and the holes 29 on the walls of the sensor tube 4 performed below the upper cut of the drain pipe 3.

The siphon 1 is equipped with a vacuum separation mechanism made in the form of a microtube 30 located at the bottom in the cavity of the siphon 31. The upper end 32 of the microtube 30 is connected to the atmosphere and is installed above the upper level of the receiver cover 8, and the lower end 33 is made in the form of a loop 34 and is directed up. In this case, the lower level of the loop 34 is set above the level of the inlet pipe 12, and the lower cut of the filling tube 28 is set below the level of the loop 34. For a stable supply of fluid to the upper cavity 26 of the receiver cover 8, the end of the supply tube 5 is passed through the eyelet 13 and inserted from the bottom side in the eye of the connector 24, and the output of the knee 7 is directed into the cavity 26 and through the crane 6 is rigidly installed in the eye of the connector 24.

By means of the inlet pipe 12 and the fixing nut 9, the siphon 1 is connected to the storage tank 35 with a cover 36 (Fig. 5 and Fig. 6).

Siphon 1 operates as follows. The working fluid with a small flow rate set by the valve 6 through the supply tube 5, installed in the ears 13 and 24, and the elbow 7 enters the cavity 26, separated by a partition 25 from the cavity 27, and then through the filling tube 28, the upper cavity 19 of the housing 11 and the passage the cross section of the inlet pipe 12 with the fixing nut 9 enters the storage tank 35 with the cover 36 and slowly accumulates in it and in the cavity 31 of the siphon 1, since the cavity 19 is hermetically separated from the cavity 20 (from the atmosphere) by means of a partition 21 with axial 22 and radial 23 drain holes tube 3 and tube-sensor 4 of the liquid level (the beginning of the cycle of "accumulation"). The liquid level in the storage tank 35 and in the cavity 31 rises slowly and when reaching the lower end 33 of the microtube 30 fills it, forcing air out of it into the atmosphere through the upper end 32. Further, the liquid level rises simultaneously in the storage tank 35, in the cavity 31 and in the microtube 30. Upon reaching the liquid level in the tank 35 to the upper level (WU) of the hole 29 (Fig. 3), the sensor tube 4 begins to drain the liquid from the cavity 31 into the cavity 20 with a full cross section, since the diameter of the liquid droplets is comparable with the diameter of the passage section t ubki liquid level sensor. The flow rate of the liquid level sensor tube 4 enters the cavity of the glass 14 and, flooding the lower section of the drain tube 3 and creating an ejection effect, draws air from the cavity 27 through the upper end of the liquid level sensor tube 4 and is discharged into the atmosphere through the passage section of the outlet pipe 18, passing through both the axial hole 16 and through the passage channels formed between the ribs 15 and the inner surface of the housing 11. After flooding the lower cut of the drain tube 3, due to the continuous increase in vacuum in the cavity 27, the liquid level it rises above the level of the upper cut of the drain pipe 3, while the drain pipe is put into operation and with a full cross section with a flow rate Q exceeding the input flow q, drains the liquid from the tank 35 into the atmosphere to the consumer through the inlet pipe 12, cavities 19, 31, 27, the cup 14, the axial hole 16, the lateral flow sections of the cup 14 and the outlet pipe 18 of the cover 17 (the beginning of the "drain" cycle).

The liquid level in the tank 35 and in the microtube 30 begins to decrease, and when it reaches the lower level (NU), which corresponds to the level below the level of the loop 34, a vacuum is created in the siphon cavity 31 below the level of the end 33. In this case, the liquid from the microtube 30 is sucked into the cavity 31 and a reliable communication of the working cavity of the siphon 1 with the atmosphere through the upper end 32 occurs. Vacuum breaks down, the siphon 1 stops draining the liquid from the tank 35, the glass 14 is emptied through the axial hole 16, the lower cut of the drain pipe 3 is released, and the cavities 31 and 27 communicate with the atmosphere (end of the accumulation-discharge cycle). Siphon 1 returns to its original position and is ready for a new cycle of “accumulation - discharge”.

Further, the duty cycles of slow filling of the liquid in the storage tank 35 with the input flow q and its quick discharge with the flow Q are automatically repeated.

The execution of the end 32 above the upper level of the receiver cover 8, the loop 34 above the level of the inlet pipe 12 and the lower cut of the filling tube 28 below the loop 34 allowed, accordingly, to exclude the possibility of liquid entering through the slice 32 into the microtube 30, which would lead to disruption of the siphon 1 , to prevent a decrease in the liquid level in the tank 35 to the level of the inlet pipe 12, which would lead to unreliable breakdown of the vacuum of the siphon 1, and to eliminate the unwanted breakdown of the vacuum of the siphon 1 through the filling tube 28. The principle of siphon vacuum breakdown 1 makes it possible to ensure the siphon’s operability at a supplied flow q close to the siphon discharge flow Q, that is, the siphon vacuum breakdown does not depend on the rate of lowering the liquid level in the tank 35, since at the time of the vacuum breakdown the OH is distant from the end of 33 microtubes 30 that provides reliable communication of the working cavity of the siphon with the atmosphere and, as a result, a reliable breakdown of the vacuum.

Thus, by making the suction and drain pipes 2, 3 coaxial, located one in the other, and installing their lower ends in the manifold 10 with the inlet and outlet pipes 12, 18, and the upper ends in the receiver cover 8, the placement of the sensor tube 4 the level of the liquid, the filling tube 28 in the cavity of the siphon 1, supplying the siphon 1 with a vacuum separation mechanism in the form of a microtube 30 and ensuring the supply of liquid from the supply tube 5 to the storage tank 35 through the siphon 1 cavity, simplification of the siphon’s design and compactness and reliable failure of the Uuma regardless of the rate of lowering the liquid level in the storage tank 35, which allowed to reduce the number of technological operations in the manufacture and installation and to ensure the operability of the siphon while increasing the range of variation of the input flow rate.

In the conditions of the workshops of the All-Russian Research Institute of Raduga in 2009, an experimental batch of the proposed siphon was manufactured. Tests of two samples from the batch in laboratory conditions showed its high reliability, ease of use and performance in a wide range of input flow rates. The maximum input flow rate of these siphons amounted to 0.90 Q _drain , while in the prototype this value does not exceed 0.15 Q _drain . Having worked for more than 1200 hours with an accumulation – discharge cycle of 30 minutes, no failures were observed. The volume of discharge per cycle was 9.6 l, the time for the siphon to start up completely was 5 ... 6 sec, the time for emptying the tank was 35-110 ... 120 sec, and the time for the siphon was diluted after emptying the tank for 35 was 2 ... 4 sec.

The application of the invention in the national economy will increase the reliability and efficiency of hydraulic systems, where it is necessary to automatically convert a continuous fluid flow into a discrete flow with a high flow rate.

Claims (4)

1. A siphon containing a suction and drain pipe, a liquid level sensor tube, a supply pipe with a tap and elbow, a receiver cover and a manifold consisting of a housing, a glass and a cover with an outlet pipe, characterized in that the collector housing is made in the form of a cylinder divided by a baffle with axial and radial holes into the upper one with an inlet pipe and a lower cavity, and the receiver cover is divided by a baffle into the upper and lower cavities communicated with each other by the filling tube, while the lower ends of the suction tube, drain the tubes and tubes of the liquid level sensor are installed in the collector, and their upper ends are in the lower cavity of the receiver cover. 2. Siphon according to claim 1, characterized in that the lower ends of the drain pipe, suction pipe and liquid level sensor tube are installed, respectively, in the glass through the axial hole of the partition of the manifold body, in the collector above the level of the inlet pipe and in the radial hole of the collector partition and the upper ends are installed in the lower cavity of the receiver cover, the upper ends of the suction tube and the liquid level sensor tube are installed at the same level, the drain pipe section is installed below the upper section of the suction pipe, and the holes on the walls of the tube of the liquid level sensor are made below the upper cut of the drain pipe. 3. The siphon according to claim 1, characterized in that it is equipped with a vacuum separation mechanism made in the form of a microtube, the upper end of which is installed above the upper level of the receiver cover, and the lower end is located in the siphon cavity, made in the form of a loop and directed upward, this lower level of the loop is installed above the level of the inlet pipe of the manifold body. 4. The siphon according to claim 1, characterized in that the lower cut of the filling tube is installed below the level of the microtube loop to break the siphon vacuum.

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