RU2694493C1 - Siphon - Google Patents

Abstract

FIELD: hydroautomatic devices.

SUBSTANCE: invention relates to hydroautomatic devices and can be used for automatic conversion of continuous flow of liquid with low consumption into discrete flow with high flow rate. Siphon comprises suction bend with air cap (4), plug (5) and suction tube (6) with side outlet nozzle (8), drain elbow with coupling (11), drain tube (13) and breather (14) and siphon start-up mechanism is made up of said suction and discharge elbows. Tube (6) along axis is divided by partition (7) into two parts, plugged at the bottom completely, and on top – in part on side of nozzle (8). Lower part of partition (7) is made above lower edge of tube (6). Cap (4) is installed in upper part of tube (6) and has collar (16) with cutout (17). Cutout (17) is directed towards nozzle (8).

EFFECT: invention is aimed at simplifying the siphon design, improving operating reliability and improving operating convenience.

1 cl, 14 dwg

Description

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

A siphon is known, comprising a suction and drainage elbow and a siphon triggering mechanism, wherein the suction elbow tube is equipped with an air cap and a cup, and the siphon triggering mechanism is made of the said parts of the suction elbow and the drain elbow tube. In this siphon, the lower edge of the air cap is installed below the upper edge of the cup, but higher than the lower edge of the suction tube, and the lower edge of the drain tube of the drain elbow is installed below the lower edge of the air cap, but higher than the lower edge of the suction tube. The volume of the air cap is larger than the volume of the glass, and the flow area of the suction pipe of the suction knee is less than the slotted flow area of the glass, but larger than the flow area of the drain tube of the drain knee [RF Patent №2506465, cl. F04F 10/00 from 10.02.2014. Bull. No. 4].

The disadvantages of this siphon are the complexity of the design, low reliability, inconvenience in operation and a large variation in discharge flow. The implementation of the air cap at the same time with the suction tube does not allow to reduce the difference between the initial and final head of the drain, which leads to a significant variation in the discharge flow and the violation of the requirements for consumption parameters by the consumer. Changing the position of the drain tube 90 ° counterclockwise and back each time you recharge the siphon (before the season or after each flushing of the storage tank) weakens the suction elbow connection with the drain elbow, resulting in a partial depressurization of the siphon and reducing its reliability .

The closest technical solution is a siphon containing a suction knee with a suction tube, an air cap and a cup, a drain elbow with a drain tube, and a siphon trigger mechanism made of the mentioned parts of the suction and drain elbow. In this siphon, the glass is installed upside-down, hermetically sealed with a lid on the bottom side and provided with an outlet side fitting at the bottom, a suction tube with a lower end is tightly installed in the glass through its bottom, and the upper end is elevated above the bottom and equipped with an air cap, the tube is installed above the lower edge of the suction tube, in addition the drain tube of the drain elbow is equipped with a coupling coupling with a breather tube [RF Patent №2557879, cl. F04F 10/10 from 07/27/2015 by Bul. No. 21 (prototype)].

The disadvantages of this siphon are the complexity of the design, low reliability and inconvenience in operation. The execution of the suction knee in the form of a suction tube installed in the glass and centered at the bottom with a lid on the inner side leads to a reduction in flow areas, an increase in the likelihood of clogging and poor siphon triggering, which ultimately complicates the design and reduces the siphon as a whole. The flow of supplied water flow from the tap directly into the storage tank at the time of the end of the "drain" creates waves on the surface of the water in the tank, which worsens the breakdown of the siphon vacuum and leads to partial parametric or complete failure of the siphon. The threaded connection of the suction and drainage of the knee during operation becomes unusable due to frequent disassembly for flushing the storage tank and siphon flow sections. At each flushing of the storage tank, it is necessary to disconnect the drain elbow from the receiving tube of the consumer, which creates inconvenience in operation.

The purpose of the proposed invention is to simplify the design of the siphon, increase reliability and improve ease of operation.

This goal is achieved by the fact that in the siphon containing a suction knee with an air cap, a cap and a suction tube with a side outlet fitting, a drain elbow with a coupling, a drain tube and a breather tube, and a trigger mechanism for the siphon made from the mentioned parts of the suction and drain knee sucking the tube is axially divided by a partition into two parts, completely muffled at the bottom, and at the top in part from the outlet nozzle, the lower part of the partition is made above the lower edge of the suction tube, The second cap is installed in the upper part of the suction tube and is made with a collar with a cutout, the cutout is directed towards the outlet fitting, in addition the output fitting is equipped with a fastening nut, and its end and the inlet duct of the drainage bend are smooth for their connection to each other with a sliding fit.

The essence of the proposed invention is shown in the figures, where FIG. 1 - General view of the siphon, FIG. 2 is a structural diagram of the siphon; FIG. 3 is a view A of FIG. 2, FIG. 4 is a structural diagram of the suction tube of the suction knee, FIG. 5 - Type B in FIG. 4, FIG. 6 - View B in FIG. 4, FIG. 7 - Installation diagram of the siphon and the supply tube to the storage tank, FIG. 8 - Type G in FIG. 7, FIG. 9 — Siphon charging circuit, FIG. 10 — The condition of the siphon after charging; FIG. 11 - Working scheme for mounting a siphon with a cumulative capacity and a consumer (the consumer’s variant is a suction inlet and irrigation pipes with water outlets), FIG. 12 - The condition of the siphon before starting the operation, FIG. 13 - The state of the siphon after start-up (the fluid is drained from the storage tank freely into the atmosphere), FIG. 14 - The condition of the siphon after the end of its work (free discharge of liquid from the storage tank stops).

Siphon 1 (Fig. 1), contains suction 2 and drain 3 knees. Suction elbow 2 (Fig. 2) consists of an air cap 4, a plug 5 and a suction tube 6 (Fig. 4) with an dividing partition 7 along the axis and a side outlet fitting 8, made with a smooth end 9 and fitted with a fastening nut 10. Suction tube 6 completely plugged at the bottom, and at the top in parts from the outlet of the nozzle, while the lower part of the partition 7 is made above the lower edge of the suction tube 6 (Fig. 4, Fig. 5 and Fig. 6). Drain leg 3 consists of a coupling 11 with a smooth inlet duct 12, a drain pipe 13 and a breather tube 14. Suction elbow 2 is connected to the drain elbow 3 by sliding the smooth end 9 of the outlet fitting 8 and the smooth inlet channel 12 of the coupling 11 and fixed with a lock 15 while the lower edge of the drain tube 13 is installed above the lower edge of the partition wall 7 of the suction tube 6. The siphon 1 has a siphon trigger mechanism made of the mentioned parts of the suction and drain elbow. Air cap 4 is installed in the upper part of the suction tube 6 and is made of a flange 16 with a notch 17 (Fig. 3).

To prepare the siphon 1 for operation, it is necessary to install it in the tank 18 with the lid 19 and the hole 20, fix the supply tube 21 to the side wall of the tank by means of the valve 22 installed above the siphon with the regulating flag 23 (Fig. 7 and Fig. 8) and produce it charging

Install the siphon 1 in the tank 18 as follows (Fig. 7)

Disconnect the drain elbow 3 from the suction elbow 2, unscrew the fastening nut 10, place the suction elbow 2 in the container 18 and, having directed the suction pipe 6 vertically down, insert the outlet side fitting 8 into the hole 20 and fix it to the wall with the fastening nut 10. Connect the drain elbow 3 with the suction bend 2, by sliding the fit of the smooth end 9 and the smooth inlet duct 12, guide the end of the drain tube 13 vertically downwards and fix with the lock 15 (Fig. 7 and Fig. 8).

Charge the siphon 1 as follows (Fig. 9). Remove the air cap 4 from the suction tube 6 by pulling it upwards with a small effort to prevent the suction knee 2 from deviating from the vertical position. Fill the air cap 4 with the working fluid and pour it into the suction pipe 6. Continue supplying the working fluid to the suction pipe 6 until the liquid flows out of the drain tube 13. After the working fluid has flowed out from the drain tube 13, install the air cap 4 at the upper end of the suction tube 6, pushing on it with a little effort and not allowing the deviation of the suction knee 2 from the vertical position (siphon charging is completed). Charging the siphon 1 is the filling of the suction tube 6 with the working fluid to the inner lower level of the side outlet fitting 8. (Fig. 10).

Next, close the container 18 with the lid 19 and the siphon 1 by means of a coupling 11 to connect with the receiving pipe 24 of the consumer (Fig. 11), consisting, for example, of irrigation pipes 25 with outlets 26 (Fig. 12).

Siphon 1 is ready for operation.

Siphon 1 works as follows. Working fluid with a small flow rate q, set by the valve 22 and the regulating flag 23, through the supply tube 21 enters the accumulation tank 18 and slowly accumulates in it to the level of the lower edge of the air cap 4 (lower level - NU) without making any impact on the siphon condition 1 (Fig. 14). Then begins the accumulation of fluid in the tank above NU (the beginning of the "accumulation" mode). The liquid level in the storage tank 18 rises slowly. The liquid level also rises in the cavity of the air cap 4, but with a lag from the level in the tank 18, since air in the cap 4 and in the upper part of the suction tube 6 and the column of working fluid in the suction tube 6 prevent it from rising. the fluid in the tank 18 under the action of the column of working fluid in the tank compresses the air in the cap 4 and slowly squeezes the fluid out of the suction pipe 6 into the atmosphere through the cover 5, the outlet side fitting 8 with the fastening nut 10 and the smooth cylindrical end 9, the coupling is connected I 11 with the inlet channel 12, the latch 15 and the drain tube 13. The liquid level in the cap 4 approaches the upper edge of the suction pipe 6, and the liquid level in the suction pipe 6 on the left side falls and approaches the lower edge of the dividing wall 7. Equilibrium compressed air in the cap 4 and in the suction tube 6 is supported, on the one hand, by a column of accumulated liquid in the tank 18, located above the lower edge of the air cap 4, and on the other hand, by a column of fluid in the suction tube 6 on the right side of the p partition 7 (FIG. eleven). When the level in the tank 18 upper level (WU), due to the special dimensions of the air cap 4 and the suction tube 6, the liquid level in the cap 4 still remains below the level of the upper edge of the suction tube 6, and compressed air, overcoming the lower edge of the partition wall 7, falls into the right side of the partition wall 7 and reduces the density of the liquid in the right side of the suction pipe 6. Then the air enters the right side of the suction pipe 6 and the process of reducing the density of the working fluid awn it takes a growing character. The equilibrium of compressed air in the cap 4 and in the suction tube 6 is sharply disturbed, and the liquid column in the tank 18, squeezing the air from the air cap 4 and the left side of the suction tube 6 into the atmosphere through the drain tube 13, the coupling sleeve 11 and the breather tube 14, high flow rate Q, exceeding the input flow q repeatedly, is drained from tank 18 with lid 19 into consumer tube 24 through air cap 4, suction tube 6, outlet side fitting 8, drain pipe 13, coupling 11 with a breather tube 14. (start “drain” mode) (FIG. 13).

The liquid level in the tank 18 begins to decrease (Fig. 13), and when the lower level (LL) is reached a little below the level of the lower edge of the air cap 4 (Fig. 14), air continuously flows into the cavity of the air cap 4 and the siphon vacuum 1 abruptly collapses. , because after lowering the liquid level below the upper edge of the air cap 4, the input flow q enters the accumulation tank 18 through the restriction collar 16 and the notch 17 directed towards the outlet fitting 8, which eliminates the possibility of wave formation on the level surface liquid in the tank 18 and unwanted intermittent entry of air into the air cap 4 at the time when the siphon vacuum breaks down at the end of the “drain” mode. The operation of the siphon 1 in the "drain" mode with the flow rate Q stops. The lower level falls below the level of the lower edge of the air cap 4. At the same time, part of the working fluid from the cavity of the air cap 4 flows back into the tank 18, and some continues to flow into the atmosphere through the drain tube 13. After the vacuum has been broken and the air cap 4 communicates with the atmosphere, the siphon 1 continues to work until the level of the working fluid in the left side of the suction tube 6 drops to the level of the lower edge of the drain tube 13. When the fluid level in the left side of the suction tube 6 reaches the level the lower edge of the discharge tube 13, the drain of the siphon stops (end of cycle "accumulation - draining").

The liquid columns in the suction tube 6 and the drain tube 13 are balanced. The left side of the suction tube remains filled with liquid to the level of the lower edge of the drain tube 13, and the right side remains filled to the level of the outlet fitting 8. Next, the liquid slowly begins to flow from the drain tube 13 to the atmosphere, and from the right side of the suction tube 6 to the left side, raising the level of the liquid in it. There is an automatic charging of the siphon and its preparation for the next cycle “accumulation-discharge” (Fig. 14).

Further, the working cycles of slow accumulation of fluid in the accumulation tank 18 with the supplied flow rate q and its quick discharge into the consumer inlet 24 of the consumer with irrigation pipes 25 and water outlets 26 are automatically repeated with the flow rate Q (Fig. 12).

Thus, due to the fact that the suction tube 6 is divided into two parts along the axis of the partition 7, completely covered at the bottom by the cover 5, and at the top in the part from the outlet fitting 8, an increase in flow sections is achieved, the siphon start condition is improved and the probability of it is reduced clogging. The implementation of the air cap 4 with the restrictive shoulder 16 and the notch 17 directed towards the outlet fitting 8 allowed eliminating wave formation on the surface of the liquid in the tank 18 at the end of the “drain” mode and improving the conditions for breaking the siphon vacuum 1. Running the outlet fitting 8 with the fastening nut 10 and a smooth end 9, and a drain elbow 3rd smooth inlet channel 12 and a retainer 15 allowed the suction elbow to be attached to the wall of the container 18 directly and connected to the drain red teeter fit, which simplified the maintenance of the equipment IAOD and increased battery life.

In the workshops of the Research Institute "Rainbow" in 2018 were made experimental samples of the proposed siphon in the amount of 10 pieces. Tests of selectively part of the samples in the laboratory and in the greenhouses of home plots showed high reliability and ease of use. The maximum input flow of these siphons exceeded the maximum required flow for watering the greenhouse by an order of magnitude. Samples, having worked in total more than 10,000 hours with an accumulation-discharge cycle of about 2 hours and 30 minutes. did not commit a single failure. At the same time, the full launch of the siphon occurred instantly, and its disruption of the vacuum and the termination of the “discharge” mode occurred reliably.

The use of the proposed invention in the national economy will increase the reliability and efficiency of hydraulics automation systems, where it is required to automatically convert a continuous stream of fluid with a low flow rate into a discrete flow with a high flow rate.

Claims (2)

1. A siphon containing a suction elbow with an air cap, a cap and a suction tube with a side outlet fitting, a drain elbow with a coupling, a drain tube and a breather tube, and a trigger mechanism for the siphon made of the mentioned parts of the suction and drain elbow, characterized in that the suction the tube is axially divided by a partition into two parts, completely muffled at the bottom, and at the top - from the outlet fitting side, while the lower part of the partition is made above the lower edge of the suction tube, the air cap is installed flax in the upper part of the suction tube and is made with a collar with a notch, with the notch directed toward the outlet fitting. 2. Siphon according to Claim. 1, characterized in that the outlet fitting is provided with a fixing nut, and its end and the inlet channel of the drainage elbow are made smooth for their connection with each other by a sliding fit.

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