RU2100532C1 - Mixer - Google Patents

Abstract

FIELD: sanitary equipment used in water-supply systems. SUBSTANCE: mixer has drain tank with valve, discharge opening and device for dosage and automatic opening and closing of discharge opening. Drain system has curved drain pipe 21 with truncated apex 22 on upper part of curved portion. Ends of drain pipe 21 are communicated through channels 23 and 24 with discharge opening 9. Inlet branch pipes of mixer are provided with locking devices. EFFECT: increased efficiency, simplified construction and enhanced reliability in operation. 8 dwg

Description

 The invention relates to sanitary equipment and can be used in water supply systems, in particular in mixer taps.

 A drain device used in mixers is known, consisting of a tank with a saddle and an outlet and placed inside the tank for dispensing and automatically opening and closing the outlet of the device, made in the form of a spherical valve of positive buoyancy and a L-shaped float, interconnected by a flexible rod ( RU, patent N2005140, CL E 03 C 1/04, 1993).

 The main disadvantage of this device is unstable operation due to the lack of air drainage, uncertain orientation relative to the saddle and the increase in the size of the crane.

 The closest in technical essence to the achieved effect is a known mixer tap, in which the drain device is made in the form of a tank with a saddle and an outlet and placed inside the tank for dispensing and automatically opening and closing the outlet, a device made in the form of a positive buoyancy spherical valve and a siphon tube with a drainage hole at the top of the bend, while the drain end of the siphon tube is connected to a channel in the tank body, communicating with the outlet under valve to (RU, N2005139, cl. E C 03 1 / 04.1993).

 The main disadvantage of this mixer tap is the limited drainage through a siphon tube and the associated limited area for regulating the frequency of water drainage, as well as the presence of far protruding elements in the mixer tap, increasing its size.

 The objective of the invention is to expand the technological capabilities and reliability of mixers and save water. This problem is solved in that in a mixer containing a housing with inlet and outlet nozzles, valves, a drain tank with a saddle and an outlet, and a device for dispensing and automatically opening and closing the outlet, a drainage system, and a drainage system are made in the form of an additional installed above the device for dispensing and automatically opening and closing the outlet of a symmetrically curved drainage tube with a cut top on the upper part of the bend, the ends of the tube with bschayutsya through channels formed in the bottom of the tank, with the outlet, wherein the cross-sectional area of the tube openings in the cutting plane, at least double the opening area in a cross section of the tube.

 In FIG. 1 shows a general view of the mixer, in FIG. 2 a section of the BB along the body of the mixer in FIG. 1 with the image of a tap for switching water from a shower to a drain pipe (and vice versa), in FIG. 3, a section along AA in FIG. 1, in FIG. view In figure 3, figure 5 drain tank with a device for dispensing and automatic opening and closing of the outlet, made in the form of a spherical valve with positive buoyancy and a L-shaped float associated with the valve by a flexible rod, figure 6 shows a variant the location of the lightened drain tank at the end of the drain pipe, see mixer, in Fig.7 shows a mixer for sinks, and in Fig.8 view G of figure 8.

 The mixer (Fig. 1,3,5) consists of a housing 1 with valves 2 and outlet pipes 3 and 4. The base 5 and casing 6 connected together form a drain (measuring) tank, which is connected to the housing 1. The mixer outlet 4 the adapter pipe 7 is connected to the base 5, in which an inlet 8, an outlet 9 and a seat 10 for the valve 11 are made.

 Inside the drain tank there is a device for dispensing water and automatically opening and closing the outlet 9.

 In FIG. 1, this device is made in the form of a spherical valve 11 with positive buoyancy and a siphon tube 12 communicating at one end with the outlet 9 by means of holes 13 and 14 made in the base 5 of the drain tank. When this hole 14 goes under the base of the valve 11 at a right or acute angle to the axis of the outlet 9.

 In Fig. 5, the dispensing device is made in the form of the same spherical valve 11 with positive buoyancy and a L-shaped float 15 with a protrusion 16 located in the zone of the axis of rotation of the float 15. The float 15 is equipped with a drum 17 with a groove on which a flexible rod 18 is wound associated with the valve 11. A flexible rod 18 is located in the groove of the float 15, and its movement in the groove is limited by the protrusions 19 and 20. Inside the drain tank (Fig. 1,3,5) there is a drainage tube 21 located above the dispensing and automatic closing device and open outlet 9. The tube 21 is formed symmetrically with a curved top cut 22 on the upper part of the bend. Both ends of the drainage tube 21 are mounted in the base 5 and communicate with the outlet 9 through openings 23 and 24 made in the base 5. The cross-sectional area of the opening of the tube 21 in the plane of the cut 22 is at least twice the area of the hole in the cross section of the tube.

 The spherical valve 11 and the seat 10 in both devices are designed in such a way that, with positive buoyancy, the valve 11 is held in the seat and does not float due to the buoyant force acting on the flooded part of the valve being less than the weight of the valve itself. In addition, the coupling of the valve 11 with the seat 10 is leaky (which is possible, since the drain tank is located behind the valves on the drain).

Figure 2 shows one of the variants of the tap for switching water to drain through a shower or drain pipe when the output pipes 3 and 4 are located at an angle of 90 ^o . It consists of a fixed sleeve 25 and a spool 26 with the possibility of turning it when rotating by the handle 27. On the spool 26 there are made interconnecting holes 28 and 29 and longitudinal channels 30 and 31 communicating with each other in the area of the spool 26 exit to the outlet of the nozzle 4 (not shown).

 Figure 6 shows the placement of the drain tank directly at the end of a horizontal section of the drain pipe. In this case, the drain tank is made of lighter material (titanium, aluminum alloys or plastic) and reduced size. At the same time, the water switching tap remains existing, since the drain pipe will be connected to the pipe 4, which is already located below the housing 1. The presented mixer is equipped with additional locking devices located on the inlet pipes 32 in front of the lockable valves 2 holes. The locking device consists of a hollow body 33, communicating with the hole of the inlet pipe 32 of the mixer and placed inside the body 33 of the valve 34 with positive buoyancy. The coupling of the valve 34 with the valve-blocked opening in the inlet pipe 32 is leaking.

 In the upper part of the housing 35, a screw 36 is installed with a cone at the end that overlaps the internal drainage hole 37. Radially, a screw 36 in the housing 35 has an external drainage hole 37. The valve 34 is configured to freely lower the inlet pipe 32 to the bottom of the cavity when water leaks from the system.

 In FIG. 7 and 8 show the layout of a sink mixer using the above-described drain tanks with a device for dispensing and automatically opening and closing the outlet and shut-off devices. The designation of the positions of the parts are similar to those described above. On Fig additionally shown by the dashed line of the hole 38, through which hot and cold water is supplied into the pipe, communicating with the cavity of the housing 33 of the locking device. In the breakout zone of Fig. 8, a hole 39 is shown through which water enters through an adapter 7, made in the form of a square, into a drain tank.

 The mixer is as follows. In the initial position, the valves 11 are located in the seat 10 and overlap the outlet 9. The valve 34 is in its highest position. The hole in the inlet pipes 32 from the side of the line with water is open, and from the side of the valves are closed. With a small opening of the valves (one or both) and turning the handle 27 to drain the water through the drain pipe (figure 2), the water is directed through the longitudinal channels 30 and 31 of the spool 26, the hole of the outlet pipe 4, the adapter pipe 7 and the hole 8 of the base 5 into the drain the tank, flooding the valve 11, which is still located in the seat 10, at the beginning due to the fact that the weight of the valve is greater than the buoyant force acting on the flooded part of the valve 11, and then due to the liquid column, additionally pressing the valve 11 to the seat 10. As level increases ode cistern in air freely displaced through the drain pipe 21 and openings 23 and 24 in the outlet 9.

 When this is flooded device for dispensing and automatic opening of the outlet 9.

 Upon reaching a certain level (the siphon is flooded at least 2/3 of the section of the hole) (Fig. 1, 2) in the siphon tube 21 is triggered, i.e. automatic drainage of water by suction through the tube 21, openings 23 and 24 and then into the outlet 9. In the zone of water exit from the hole 24 to the outlet 9, a turbulent turbulence of water from a sharp change in the direction of flow occurs and the valve 11 is already flooded on both sides. The pressure on the valve is equalized and it automatically pops up, additionally opening the drain through the seat 10. From this moment, water is drained simultaneously through two holes: through the opening of the seat 10 and through the siphon tube 21. When the water level drops to the edge of the free end of the siphon tube 21 expiration only through the opening of the seat 10. With a further decrease in the water level, the valve 11 is drawn into the seat 10 and closes the outlet 9. The valve 11, enclosed in the space between the surfaces of the siphon and drainage tubes e may exit this space, and therefore when draining reliably lowered only to the saddle 10. And so the process of the periodic accumulation of water in the cistern and a sharp discharge continues until closed valves. When water enters the drain tank according to FIG. 5, valve 11 is held in the seat 10 in the same way, and the float 15 is in its lowest position until the protrusion 16 is flooded. Air from the tank is also forced out through the drain pipe 21 and openings 23 (not shown) and hole 24.

 When the protrusion 16 is flooded, the float 15 begins to turn into an unstable equilibrium position, and having crossed it, it makes a sharp turn, pulling the flexible rod 18 and opening the valve 11 from the seat. The float 15 occupies its highest position, abutting against the casing 6, and the valve 11 floats to the surface of the water. There is a drain of water from the tank through the outlet 9. The space liberating in the drain tank is compensated by the suction of air through the holes 23 and 24 and the drain pipe 21 and partially continuously flowing water into the drain tank through the hole 8. In the process of draining the water and lowering its level, the valve 11 falls down and is drawn into the saddle 10 by water, and the float 15 returns to its original position. And so the process of periodic draining is repeated until the valves are closed. Flexible rod 18 is selected so long as to ensure that valve 11 is freely positioned in the seat (without thread interference) and that there is no interference interference when the float 15 begins to turn sharply. And only to the moment close to the maximum kinetic energy of the float, flexible traction is in tension. This calculation of the length of the flexible rod does not allow the valve 11 to fall besides the seat 10 and ensures reliable separation of the valve 11. To ensure the best drainage, it is necessary to place the ends of the drainage holes in the outlet 9 below the drain holes, and the outlet 9 should be made larger in cross section (approximately 10- 30%) of the total cross-section of the drain holes from the saddle 10 and from the siphon tube of the hole 24 for the tank in figures 1 and 3.

 In the drain tank in FIG. 5, the drain to the outlet 9 occurs only through one hole (at the seat 10), which is much smaller than the cross section of the outlet 9. The frequency of the drain depends on the degree of opening of the valves. The more valves are opened, the more often a periodic drain will occur until, finally, a continuous drain occurs. In this position, the valves 11 will constantly be located outside the seat 10, and the float 15 (Fig. 5) in its highest position. For emergency drainage of water (when the mixer is in periodic discharge mode) without waiting for the full dose of water to be filled, at which the system automatically responds to drainage, it is enough to cover the drain pipe (or outlet 9 of the drain tank attached to the end of the drain pipe with a palm or finger) figure 6). In this case, the pressure acting on the valve 11 from above and below is equalized and it breaks away from the seat 10 and abruptly floats up. When the mixer is operating, the valve 34 (Fig. 3) is constantly in the upper position and does not interfere with the flow. In the absence of water in the line, the valve 34 of the locking device lowers to the bottom of the cavity of the inlet pipe 32 and remains in this position until the water is supplied.

 When water is supplied and the valve is closed, the valve 34 floats into the cavity of the housing 33. Before operating the mixer, in this case it is necessary to unscrew the screw 36 by 0.5-1 turn and let the air out of the housing 33, as a result of which the water and valve 34 will take their highest position if if this is not done, then when opening the valve, the valve 34 will be tightened by the flow of water into the cavity of the inlet pipe 32 and will block the hole with the valve. After the drainage, screw 36 again locks the hole 37. When water is supplied to the system, but when the valve is not closed, the valve 34 rushes to the hole (behind the valve) and closes it, eliminating flooding and a large overspending of water. When water is supplied to the system, it is necessary to close the tap, and the valve 34 pops up automatically into the cavity of the housing 33. Now it remains only to perform the above operation to bleed air from the housing 33 using the screw 36. In this case, the valve will take its highest position and will remain there until until the water supply is turned off.

 Instead of screw 36, you can install a drain valve that would automatically let air in and out, but experience has shown that under water conditions these valves stop working over time and become unreliable.

 Thus, the proposed mixer allows to increase the reliability, significantly expand its technological capabilities and consumer properties.

These are water saving opportunities due to periodic draining, at which the opening of the valves is minimal, and draining the water as with a large opening of the valves. This is ensured by the accumulation of water for the period when it is not required and a one-time full discharge. The mixer makes it easy to carry out emergency draining of water by simply touching the drain pipe with your palm or finger. In addition, the locking device makes it safe to operate the mixer in conditions where water is often shut off. It eliminates the possible flooding of rooms and a large loss of water. During the hour of the expiration of water through the open one tap, about 1 m ^{3 of} water is poured.

 The proposed mixer retains without alteration all the functional properties of existing mixers, regardless of whether new devices will or will not work, fits into the dimensions of these mixers and does not fundamentally change the design of all the main components. All connecting elements are saved. Without any alteration of communications, you can replace the existing mixer with the proposed mixer. New elements of the proposed mixer are included in the existing mixer according to the principle of embedding and can be manufactured independently (drain tank, shut-off device). At the same time, each functions independently of each other. If necessary, one of them can be used. The rise in price of the mixer is offset by consumer properties that provide water savings, elimination of water losses with open taps and material and moral damage from flooding of their premises and premises in lower floors.

 From the point of view of safe operating conditions, the proposed mixer solves security problems and in this connection the question arises of the validity of the production and use of existing mixers in the name of consumer interests.

Claims (1)

 A mixer comprising a housing with inlet nozzles, valves, a drain tank with a saddle and an outlet and a device for dispensing and automatically opening and closing the outlet, a drainage system, characterized in that the drainage system is made in the form of an additionally mounted above the dispensing device and automatic opening and closing of the inlet of a symmetrically curved drainage tube with a cut top on the upper part of the bend, the ends of the drainage tube are communicated through channels made in the base of the tank, with an outlet, while the cross-sectional area of the hole in the tube in the plane of the cut is not less than twice the area of the hole in the cross section of the tube.

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