RU2182203C2 - TOILET WITH PRESSURE WATER FLUSHING (Versions) AND ITS FLUSHING SYSTEM - Google Patents

Abstract

FIELD: toilets with pressure water flushing. SUBSTANCE: toilet has tank for water provided with circular seat of valve located in lower part of tank and formed by discharge hole of tank, drain valve having cylinder with piston and collector installed in tank. Piston forms upper chamber of cylinder and collector has means for air supply to cylinder upper chamber and connection of water source under pressure with water tank and upper chamber of cylinder of drain valve. System for flushing with water under pressure includes tank for disinfection means, pipeline for supply of water to tank, pipeline for supply of disinfection means from disinfection tank to water tank and means for regulation of amount of disinfection means. EFFECT: use of minimal amount of water for flushing and higher efficiency of removal of wastes. 14 cl, 8 dwg

Description

 The invention relates to an improved toilet with flushing with water under pressure, which minimizes the amount of water required for flushing, but which has maximum waste removal efficiency and reliability.

 The pressurized flush toilet described herein is an improvement on the systems presented in US Pat. Nos. 4,233,698 of November 18, 1980 and 5,361,426 of November 8, 1994, as well as the system of U.S. Patent Application 09 / 457.162. filed July 1, 1995

 The main components of a pressure flushing toilet are a water tank, a drain valve and a drain valve actuator. These components are typically installed inside a conventional toilet flush system. The source of energy for the flush system of such a toilet is the water pressure in the water supply network.

 To operate the system, air compression is used inside the water tank as its level rises in this tank after flushing. When the water pressure in the tank is compared with the pressure in the water supply network, or when the regulator valve closes under the influence of this pressure, if the pressure in the water supply network exceeds the level set by the regulator, the flow of water into the water tank is stopped and the system is ready for use. When the drain valve actuator is actuated, the compressed air in the water tank pushes the water in it into the toilet bowl with relatively high pressure and speed, flushing the waste in the toilet with a minimum flow rate.

 Known systems for flushing a toilet with pressurized water are successful with consumers, however, some of their operational characteristics can be improved. In particular, the energy of the discharge of water, which ensures the efficient removal of waste from the toilet, is insufficient; too high or too low pressure in the water supply network leads to instability; the volume of water supplied is variable; no means are provided for pressure relief inside the system if the pressure in the water supply network exceeds the permissible one; the operation of the system depends on the duration of exposure to the drain valve actuator; insufficiently reliable actuation of the drain valve under reduced pressure in the water supply network; the drive valve does not have a self-cleaning function; there is no way to adjust the volume of water to fill the toilet, and there are no funds for the introduction of disinfectants without impairing the operation of the flush system as a whole.

 These problems are solved in the flush system for a toilet with water under pressure, presented by the present invention. In particular, the system significantly increased the efficiency of waste disposal, as well as the constancy of flushing parameters and its reliability. The system uses a minimum amount of water to flush; the system has an internal pressure relief if the pressure in the water supply network exceeds the permissible; system operation does not depend on the duration of exposure to the drain valve actuator; provides reliable locking of the drain valve with insufficient pressure in the water supply network; the drive valve has a self-cleaning function; the volume of water to fill the toilet can be selected in accordance with the conditions of use. In addition, the water consumption of the system is almost the same at high and low water pressures; The system has two internal non-return check valves, an integrated drain, an internal drain hole and ensures that disinfectants are introduced into the toilet without deterioration of the flushing system.

 Another distinctive feature of the invention is that water enters the reservoir with a disinfectant, with further injection of the disinfectant into the toilet bowl when the drain valve actuator is actuated, through the actuator directly above the drain valve cylinder.

The above features of a pressure flushing system in accordance with the present invention provide more powerful and efficient removal and removal into the sewer, better cleaning of the toilet bowl, less chance of clogging of the sewer drain, the absence of hidden leakage of water between the flushes and a reduction in the size of the piping system. The system in accordance with the present invention provides the cleaning and washing of the toilet bowl using less than 6.06 dm ³ (1.6 gallons) of water, meeting the most stringent requirements of municipal regulations. The toilet is cleaned with one flush in the absence of a gradually decreasing flow of water, characteristic of many toilets using small amounts of water, or toilets in which flushing occurs under the influence of gravity.

 When the system starts, the impact on the manual actuator causes the appearance of a pressure difference acting on the piston of the bleed valve located in the cylinder of the bleed valve. In this case, the piston of the drain valve and the drain valve move upward at a certain speed.

 An upward bias (opening bias) of the drain valve allows water to be pushed out of the water tank into the toilet bowl at a relatively high pressure to ensure effective cleaning of the toilet bowl. Drainage begins simultaneously with the action of the drain valve on the drive and lasts for a certain time, which ensures a continuous flow of high-energy water, which carries waste into the sewer.

 The closing moment of the drain valve is determined by the ratio of the amounts of water entering the upper chamber of the cylinder of the drain valve and into the water tank. When the effect on the drain valve actuator is stopped, the path for the liquid to exit outward from the upper chamber of the drain valve cylinder is blocked. At this point, a certain amount of water flowing under pressure from the water supply network falls directly into the upper chamber of the drain valve cylinder. The rest of the water coming from the water supply goes to the main chamber of the water tank. Before closing the drain valve, water and a certain amount of disinfectant entering the water tank pass through it into the toilet bowl, ensuring its disinfection and restoring the water lock in the toilet siphon to prevent sewer gases through it. When the upper chamber of the drain valve cylinder is filled, all incoming water is sent to the water tank.

 The water that fills the water tank under the influence of the controlled pressure of the water supply network compresses the air there until its pressure reaches either the pressure in the network or a set level, for example, at 207 kPa (30 psi), as in the preferred embodiment under consideration inventions, depending on what level will be reached first. At this point, the flow stops and the system is ready for a new flush.

One of the features of the present invention is that both the water tank and the upper chamber of the drain valve cylinder are constantly connected through a water pressure regulator to a pressurized water network. Another feature of the present invention is that at least 75% of the water stored in the water tank is discharged at a flow rate in excess of 75.7 dm ³ per minute (20 gallons per minute) if the pressure in the water supply network is equal to or greater than the pressure in the water supply network. This feature provides excellent cleaning of the toilet and the removal of waste into the sewer.

 Another feature of the present invention is that the drain valve actuator is hydraulically connected to the upper chamber of the drain valve cylinder. In this case, when the drain valve actuator opens the outlet to the atmosphere, the water pressure in the upper chamber of the cylinder instantly, but silently, drops, forming the pressure difference acting on the piston, as a result of which the pressure on the lower surface of the piston immediately pushes it and the drain valve up, translating into an open position. The flow of water from the upper chamber of the drain valve is metered, which ensures reliable control of the upward movement of the piston of the drain valve. The noise level is low because the system is hydraulic, not pneumatic.

 The above objectives and advantages of the present invention are achieved in the proposed toilet with flushing under pressure, containing a water tank equipped with an annular valve seat located in the lower part of the tank and formed by the outlet of the tank, a drain valve provided with a cylinder vertically located above the outlet in the aforementioned reservoir and having a piston forming the upper chamber of the cylinder and mounted to move along the axis of the said cylinder under the action cm water pressure difference on opposite sides of said piston, and a collector mounted on said reservoir and comprising an air supply means into the upper chamber of said cylinder and a compound of a pressurized water source to said water tank and said upper chamber of said cylinder drain valve. Moreover, in the normal position, the drain valve through the said piston is mounted on the valve seat of the said water tank and closes the outlet of the tank.

 In an additional embodiment, said means comprise a drain valve actuator and its piston for moving said piston with the valve while lowering the water pressure to the opening position of the tank outlet and connecting the upper chamber of said drain valve cylinder to the surrounding space.

 In yet a further embodiment, said drain valve actuator is located inside said manifold.

 In another further embodiment, said manifold comprises a pressure regulator having means for letting ambient air into the water stream as it passes through said pressure regulator to said water reservoir.

 In a further further embodiment, said pressure regulator comprises two floating check valves to prevent water from flowing back from said water tank through said pressure regulator.

 In a further further embodiment, said drain valve actuator comprises an annular hole with a needle valve located therein, which controls the flow of water into the upper chamber of said cylinder.

 In a further further embodiment, said water tank comprises two spaced-apart compressed air caps separately from said drain valve cylinder.

 In yet a further embodiment, the toilet of the invention comprises a pressure relief pipe located inside said water tank and connected to said drain valve actuator and to an atmosphere opposite the valve with said piston of the outlet side of said water tank.

 In yet a further embodiment, said needle valve is arranged to clean said annular hole when it is reciprocatingly moving therein.

 In another embodiment of the invention, there is provided a toilet pressure flushing system according to the invention, including a disinfectant tank, a water supply pipe from said water tank to said tank, and a disinfectant supply pipe from said tank to said water tank and means for controlling the amount of disinfectant introduced into said water tank with each flush.

 In a further embodiment, said water supply conduit is connected to a drain valve actuator on said water reservoir.

 In yet a further embodiment, said water supply conduit is connected to said water reservoir below the level of the valve seat.

 In another embodiment of the invention, the pressure flushing toilet contains two spatially separated air chambers that prevent the tank from being overfilled with water and located above the tank outlet on opposite sides of the drain valve cylinder.

 In a further embodiment, said air chambers comprise baffles which extend downward from the upper wall of said water tank to its central part.

 In another embodiment of the invention, the system for flushing the toilet with water under pressure comprises a pressure relief valve mounted on said piston with the ability to open and release pressure to the atmosphere when pressure occurs above the pressure specified in the upper chamber of the said cylinder.

 Figure 1 shows a front view of a toilet flushing system with pressurized water in accordance with the present invention.

 Figure 2 shows a top view in the direction of the arrow "2" in figure 1.

 FIG. 3 shows a view of a fully charged flushing system along line 3-3 of FIG. 2.

 FIG. 4 is an enlarged view of a portion of the system inside the ring line “4” in FIG. 3.

 FIG. 5 is a view similar to that of FIG. 3 when the flush is turned on.

 FIG. 6 is a view similar to that of FIG. 3 when the pressure flush is completed, but toilet filling continues.

 Fig. 7 is a view similar to that of Fig. 3, when the filling of the toilet bowl is completed, the drain valve is closed, and filling of the water tank and increasing the pressure therein begins.

 FIG. 8 represents fragments with a partial cross-section, another embodiment of supplying water to a tank with a disinfectant.

 As can be seen in FIGS. 1 and 2, the pressurized toilet flush system 10 according to a preferred embodiment of the present invention is shown in functional connection with a conventional flush cistern 12. The main components of the system 10 are the water tank 14, the internal assembly 16 of the drain valve , a collector 18 with means for supplying air, if necessary, to the upper chamber of said cylinder and connecting a pressurized water source to said water reservoir and upper chamber of said cyl a drain valve indra comprising a built-in drain valve actuator 22, a water pressure regulator 24, an air intake regulator 25 (ambient air inlet means) shown in FIG. 3, and a disinfectant tank 26.

 Water is supplied to the system 10 from a source under pressure (not shown), and passes upward without interference through the inlet pipe 27 and vacuum valve 28, and then in the transverse direction to the manifold 18. Water under pressure freely flows through the pipe 27 into the manifold 18 and then after adjustment to the drain valve assembly 16 and the water tank 14 as described below.

 The size of the water tank 14 is determined by the power requirements of the system 10. In the described preferred embodiment of the invention, the water tank 14 consists of two sections 32 and 34 stacked on top of each other. The upper section 32 of the water tank 14 has two downward-directed partitions 35 and 36, which form isolated air chambers 37 and 38, extending in length to the water level above the weld between sections 32 and 34, which corresponds to a typical state between washings, as will be shown below. Accordingly, due to the fact that the compressed air in the chambers 37 and 38, which drives the system 10, is isolated, leakage in the upper part of the drain valve assembly 16 does not overfill the system 10 with water.

 A manifold 18 comprising a water pressure regulator 24, an air inlet regulator 25, and a drain valve actuator 22 is attached to the upper section 32 of the water tank 14.

 As can be clearly seen in Fig. 4, the air intake system 25 built into the manifold 18 comprises a male thread fitting 42, on which the cap 44 is put on. The cap 44 has an opening 46, the outer part of which serves as a seat for the ball valve 48. In normal condition, the valve 48, the water pressure inside the manifold 18 is kept closed. However, when the internal pressure in the water tank 14 drops to a certain minimum during the water discharge phase in the flush cycle, for example to 14 kPa (2 psi), the resulting flow of water into the water tank 14 causes an air pressure difference across the valve 48, which leads to its opening and absorption of fresh air into the water stream, automatically replenishing the air in the tank 14. To supply air to the water flow flowing into the water tank 14, there is a pipe 50, which goes down into the tank into the hole 52 in the manifold 18. The intake system Bani air also functions as a vacuum valve preventing the movement of water from the system 10 back to the water supply system at falling pressure therein.

 The water pressure regulator 24, mounted on the manifold 18, has a tubular configuration. A tip 64 is attached to it. A ball valve holder 66 having a cross-shaped cross section is located inside the tip 64. If the internal pressure in the water tank 14 is lower than in the water supply network, the valve 68 is pressed by pressure in the water supply network to the annular seat 69 of the tubular part 70 piston 71 pressure regulator. Similarly, the second ball valve 72 is secured in a second holder 74 having a cross-shaped cross section. When the internal pressure in the tank 14 drops below a predetermined limit, the piston 71 moves away from the tip 64 under the action of the regulator spring 76, opening water to the path past the ball valve 68, then past the ball valve 72 further to the drain valve 16 and the water tank 14, as it will be described below.

 In the event of a pressure drop in the water supply network, the ball valves 68 and 72 move to the left, as shown in the figure, pressing against the annular seats 78 and 79 of the tip 64 and the piston 71, respectively, thereby preventing the return of water from the tank 14 to the water supply network.

 The manifold 18 also includes a bleed valve actuator 22, which includes a cylindrical housing 80 with an actuator located inside the spool 82, which can slide inside the sleeve 84. A portion of the spool 82 is a valve 85, which usually rests on the valve seat 86. The continuation of the spool 82 is a needle valve 87 entering a hole 88 in the housing 80, the position of which determines the area of the annular inlet that controls the flow of water entering the drain valve 16.

 When the spool 82 of the drain valve actuator 22, overcoming the resistance of the spring 92, biases the valve 85 from its seat 86, it opens the passage between the upper chamber "C" of the drain valve 16 through the opening 94 to the pressure relief pipe 96, thereby starting the flushing process, as will be described Further. Pipe 96 is connected to atmospheric pressure in the toilet (not shown).

 As can be clearly seen in FIGS. 3 and 5-7, in accordance with an aspect of the present invention, the drain valve assembly 16 comprises a vertically located drain valve cylinder 100 having an upper end portion 102 abutting against the manifold 18. The lower end portion 106 of the cylinder 100 is broken reaching the tapered valve seat 108 of the water discharge passage 109 in the lower section 34 of the water tank 14. The outflow of water from the reservoir 14 through the passage 109 is controlled by an annular valve 110 mounted on the piston rod 114 of the drain valve piston 116.

 The upper end portion 118 of the piston 116 is cup-shaped and elongated so that a completely defined distance remains from it to the upper end portion 102 of the drain valve cylinder 100, for example 10.2 mm (0.4 inches), resulting in a vertical movement of the piston 116 limited to 10.2 mm (0.4 inches).

 An elastomeric piston ring 130 is attached to the drain valve piston 116, which provides sealing against the cylinder 100, thereby separating the cylinder 100 into the upper chamber 132 and the main chamber 134 of the reservoir 14. The piston 116 has a centrally located pressure relief valve 136 that closes in the normal position hole 138 in the piston. In the event of excessive pressure in the upper chamber 132, the valve 136 opens to overcome the force of the spring 139 and relieves the pressure in the upper chamber 132. This small pressure relief in the upper chamber 132, for example, at a pressure of 310 kPa (45 psi) creates a pressure difference between the upper the chamber 132 and the main chamber 134 of the tank 14. As a result, the piston 116 of the drain valve begins to rise, which leads to a decrease in pressure in the main chamber 134 of the tank 14 for water. Fluctuations initially occur when a pressure difference is created that gradually equalizes in both chambers, preventing the pressure in the main chamber 134 of the tank 14 from exceeding the set limit, for example 552 kPa (80 psi).

 According to another aspect of the invention, a disinfectant is automatically injected into a toilet bowl (not shown) when the pressure flushing system 10 is activated. However, the disinfectant is not in the water tank 14 between rinses, thereby preventing exposure to the tank and the sealing seals of the chemical disinfectant. The disinfectant tank 26, containing, for example, water-soluble disinfectant tablets 150, is connected to a manual drive 22 on the manifold 18 via a water inlet tube 152. One of the ends 153 of the water inlet tube 152 is connected to the fitting 154 on the actuator 22, through which it communicates with a valve 85 on the valve spool 82. The size of the hole in the nozzle 154 in combination with the period of time during which the nozzle is under water pressure determines the amount of water passing through the tube 152 into the disinfectant tank 26, as will be described below. The opposite end 156 of the water inlet pipe 152 is connected to the tank 26. The disinfectant discharge pipe 158 is connected at one end 160 to the cap 44 of the air intake system 25 above the inside ball valve 48. The opposite end 162 of the tube 158 is lowered into the tank 26 to a certain depth, as will described later.

 Before flushing the system 10, as is clearly seen in FIG. 3, the disinfectant is located in the tank 26 just below the lower end 162 of the disinfectant discharge pipe 158. As can be clearly seen in FIG. 5, when starting the system 10, due to the left-hand slide of the spool 82 of the manual actuator 22, the water passage opens from the chamber “C” in the drain valve 16 past the valve 85 to the fitting 154, and then through the water inlet pipe 152 tank 26 for disinfectant. The size of the nozzle 154 in combination with the duration of the flushing water determines the amount of water sent through the tube 152 to the tank 26 under the pressure created when the water is released from the main chamber 134 into the toilet bowl. The duration of the water discharge from the main chamber 134 controls the amount of water discharged through the nozzle 154. The volume of water flowing into the tank 26 is designed to raise the level of disinfectant in it by a certain height above the lower end 162 of the disinfectant discharge tube 158. In the normal state, the flow from the tank 26 is blocked by a ball valve 48 of the air exhaust system 25, which is held closed by internal pressure in the manifold 18 and the water tank 14.

 When the flushing process reaches the stage shown in Fig.6, a significant part of the water from the water tank 14 is displaced, and the pressure in the tank 14 is reduced so that due to the pressure difference arising on the ball valve 48 due to the Venturi effect due to the flow of water past the nozzle 50, passing into the opening 52 of the tank 14, the valve 48 opens. When the valve 48 is opened, a flow of disinfectant from the tank 26 through the air inlet system 25 into the water tank 14 occurs. After the level of the disinfectant in the tank 26 drops below the level of the end portion 162 of the tube 158, the flow of the disinfectant stops and through the tube 158 into the air intake system 25 and then, as necessary, a new portion of air is sucked.

 As shown in FIG. 7, tank filling starts and valve 48 of the air intake system 25 is closed by internal pressure inside the manifold 18. From the foregoing, it should be understood that the water in the water tank 14 is free of disinfectant since the ring valve 110 flushing does not block the exit of the tank 14 for a period of time sufficient to ensure that the disinfectant entering the water tank 14 releases the tank 14 and reaches the toilet. This protects the seals and other parts of the flushing system 10 under pressure from damage.

 3, system 10 is shown in a ready state when the water tank 14 is completely filled with air and water under pressure, for example 152 kPa (22 psi). Specifically, zones (A), (B), (C) and (E) are under pressure of 152 kPa (22 psi). Zones (D), (F) and (G) are at atmospheric pressure.

 FIG. 5 shows the state of the system at the beginning of the flushing process. The process begins after pressing the spool 82 of the drain valve actuator 22, when the water under pressure in zone "C" rushes through the actuator 22 into zone "D", then into zone "F", and also through the water inlet pipe 152 into the tank 26, raising the level there. The pressure difference between zones “E” and “C” causes the piston 116 to rise in the drain valve assembly 16, opening the way for water to exit through passage 109 to discharge the toilet into the toilet in zone “F”. It should be noted that the piston 116 of the bleed valve assembly 16 rises, for example, 10.2 mm (0.4 in), allowing only a certain amount of water to leave zone “C”. This amount of water is equal to the amount of water that can exit through the drain valve actuator 22 in 1/4 s. As a result, after each flush, the same amount of water is necessary to re-fill zone "C" and close the valve 110, even if the spool 82 of the drain valve actuator 22 is pressed for longer than 1/4 s.

 As the flushing process develops, the pressure in zone "E" begins to decrease, the regulator 24 begins to open and a flow occurs through zone "A" to zones "B" and "C", and the flow through zones "A" and "B" "reaches its maximum value when the pressure inside the reservoir" E "is zero.

 Figure 6 shows the state of the system when the pressure washer is almost complete, but water and the disinfectant continue to drain through the tank 14 into the toilet bowl to fill it. In this state, water flows into zones "A", "B" and "C", but the disinfectant passes only into zones "B" and "E", and then into zone "F". After a certain amount of disinfectant has passed through zone "B", into zone "B", and then into the water tank 14, air is sucked through the air intake system 25. As long as the water flow in zone “C” presses the drain valve piston 116 and flush annular valve 110 against its seat 108, the water flow in zone “E” will go into zone “F” to fill the toilet bowl (not shown).

 Figure 7 shows the state of the system when the filling of the toilet bowl is completed, the flush valve 110 is closed and the filling of the water tank 14 and the increase in pressure therein begins. In this state, the entire flow through zone “A” is directed through zone “B” to zone “E” of reservoir 14. It should be noted that when the piston 116 of the drain valve assembly 16 is in the closed state and zone “C” is full of water, the intake system 25 air closes due to increasing pressure in zones "A", "B", "C" and "E".

 In accordance with Fig. 8, the modified system for supplying water to the disinfectant tank 26 comprises a water inlet pipe 252, one end of which 254 is connected to a fitting 256, which is connected to the water discharge zone “E”. The size of the hole in the nozzle 256 in combination with the flushing time determines the amount of water flowing through the tube 252 into the tank 26 with a disinfectant. The other end 258 of the water inlet tube 252 is led to the tank 26. The disinfectant is discharged from the tank 26 through the tube 158 as described.

It should be noted that the toilet with flushing water under pressure in accordance with the present invention is fully functional and without the tank 26 for the disinfectant described here. From the above description, it should be clear that the toilet flushing system 10 of the present invention has several features. In particular, the system 10 provides a quiet discharge of water, since the piston 116 of the drain valve opens instantly, but moves upward relatively slowly, so as to gradually fill the passage 109 of the water discharge. This relatively slow opening is controlled by the dimensions of the water passage either from zone "C" or into zone "D". It should also be noted that the dimensions of the hole 88 of the needle valve in combination with the dimensions of the needle valve 87 regulate the flow rate of the fresh water into the upper chamber “C” of the drain valve 16. In the considered embodiment of the invention, the area of the annular hole is 0.50322 mm ² (0, 00078 sq. Inch). The possibility of clogging of the annular hole by particles in tap water is minimized, since the needle valve 87 cleans the hole 88 of any foreign materials when pressed.

 The volume of water for filling the toilet can be controlled by changing the diameter of either the holes 52 or holes 88 in combination with the diameter of the nozzle 50 or the needle valve 87, which changes the ratio of the volumes of water entering the zones "B" and "C", respectively, and accelerates or decelerates the movement of the piston 116 and locking of the drain valve assembly 16 after flushing, and / or the amount of water to fill the toilet passing through the reservoir 14 into the toilet (not shown) is changed. As a result, system 10 can be precisely tailored to different toilet configurations to achieve the best performance and water savings. The volume of water for filling the toilet can also be changed by changing the amount of water discharged from the upper chamber “C” of the drain valve assembly 16. For example, if the amount of vertical movement is increased from 10.2 to 20.3 mm (from 0.4 to 0.8 inches), the time interval when the drain valve is open will more than double, as in the upper chamber "C" more water must flow in order to press the piston 116 against its bearing surface. At the same time, the total volume of flushed water also increases.

 The free-floating ball valves 68 and 72 in the pressure regulator 24 act as internal check valves. With an inverse pressure ratio, when the pressure in the tank 14 is higher than in the water supply network, the ball valves move to the seats 78 and 79, respectively, blocking the return flow.

 Another distinctive feature of the system 10 flushing the toilet with water under pressure in accordance with the present invention is that the system consumes less water at higher pressures in the water supply network (i.e., from 345 to 552 kPa (from 50 to 80 psi)), than at low pressures (that is, at 138 kPa (20 psi). In other words, the relatively high pressure in the water supply system causes the flush valve piston 116 to close relatively quickly after the water exits the tank. In addition, system 10 has a minimal difference in heat water fumes when pressure changes, for example, from 138 to 552 kPa (from 20 to 80 psi).

 Despite the fact that the preferred embodiment of the invention is given above, it should be borne in mind that the invention is subject to change without departing from its essence and within the scope of the claims defined by the appended claims.

Claims (14)

 1. A toilet with a pressure flush containing a water tank equipped with an annular valve seat located at the bottom of the tank and formed by the outlet of the tank, a drain valve provided with a cylinder vertically located above the outlet in the said tank and having a piston mounted with the possibility displacements along the axis of said cylinder under the action of a difference in water pressures from opposite sides of said piston, and a collector mounted on said reservoir, m the drain valve through the said piston is mounted on the valve seat of the said water tank and is located covering the outlet of the tank, characterized in that the piston forms the upper chamber of the cylinder, and the collector contains means for supplying air to the upper chamber of the said cylinder and connecting the pressurized water source to said water tank and upper chamber of said drain valve cylinder.  2. The toilet according to claim 1, characterized in that said means comprise a drain valve actuator and its piston for moving said piston with a valve while lowering the water pressure to the opening position of the tank outlet and connecting the upper chamber of said drain valve cylinder to the surrounding space.  3. The toilet according to claim 2, characterized in that said drain valve actuator is located inside said collector.  4. The toilet according to claim 1, characterized in that said collector comprises a pressure regulator having means for letting in ambient air into the water stream as it passes through said pressure regulator to said water tank.  5. The toilet according to claim 4, characterized in that said pressure regulator comprises two floating non-return check valves installed to prevent back flow of water from said water tank through said pressure regulator.  6. The toilet according to claim 2, characterized in that said drain valve actuator comprises an annular hole with a needle valve located therein, which is arranged to control the flow of water into the upper chamber of the said cylinder.  7. The toilet according to claim 1, characterized in that said water tank contains two spaced apart caps for placing compressed air separately from said cylinder of the drain valve.  8. The toilet according to claim 1, characterized in that it comprises a pressure relief pipe located inside said water tank and connected to said drain valve actuator and to the surrounding atmosphere from the opposite valve with said piston of the outlet side of said water tank.  9. The toilet according to claim 6. characterized in that said needle valve is installed with the possibility of cleaning said annular hole when it is reciprocating in it.  10. System flushing water under pressure of a toilet according to any one of paragraphs. 1-9, characterized in that it includes a tank for disinfectant, a pipeline for supplying water from said water tank to said tank, a pipeline for supplying disinfectant from said tank to said water tank and means for controlling the amount of disinfectant introduced into said water tank with each flush.  11. The system of claim 10, wherein said water supply pipe is connected to a drain valve actuator on said water tank.  12. The system of claim 10, wherein said water supply conduit is connected to said water reservoir below a level of a valve seat.  13. A toilet with pressure flushing, comprising a water tank provided with an annular valve seat located at the bottom of the tank and formed by a water outlet from the tank, a drain valve comprising a cylinder vertically located above said valve seat, characterized in that it contains two spatially separated air chambers to prevent overfilling of the tank with water, located above the outlet of the tank on opposite sides of said drain cylinder valve.  14. The toilet according to claim 13, characterized in that the said air chambers contain partitions made falling down from the upper wall of the said water tank to its central part.

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