FI92085B - Improved vacuum drainage device - Google Patents

Description

92085

IMPROVED VACUUM DRAINAGE SYSTEM - FÖRBÄTTRAD VAKUUM-AVLOPPSANORDNING

The invention relates to a vacuum sewer system according to the preamble of claim 1 and to a method according to the preamble of claim 10 for controlling a vacuum sewer system.

5 One notable problem with vacuum sewer systems is the high noise they cause. Noise is generated when the drain valve opens and closes and when air and sewage mass are absorbed into the drain. Vacuum drainage technology requires a fairly large volume of air to flow into the sewer pipe after the substance being transported in the sewer and for the sewer valve to open and close quickly. These functions produce significant pressure fluctuations that generate noise.

It is known from Finnish patent No. 77082 to allow air to enter the vacuum drain through an air discharge duct at a point downstream of the drain valve 15. Thanks to this technology, the drain valve can be closed immediately after the transported sewage mass is transferred to the vacuum drain, because the air required for transport is obtained from the air discharge duct. In this case, the drain drained under flowing amounts of air are small, and in addition to the drain valve 20 is closed in a situation wherein the air discharge channel due to the drain without flowing into the drain valve inlet and the pressure difference between the discharge side is small. All this is likely to significantly reduce noise levels.

25 Two factors determine how long a drain valve must be kept open. First, the drain valve must be open for so long that the sewage mass to be transported has completely moved into the drain pipe with reasonable certainty. Although normally the sewer mass enters the sewer immediately when 30 sewer valves are opened, it is advisable to allow the sewer mass 92085 2 about two seconds to leave the device to be drained. Secondly, it is important for the operation of the vacuum drainage system that the sewage mass is not merged with the satin upstream or downstream in the sewer. Therefore, the 5 sewer mass must have a relatively long distance in the sewer pipe, for example at least 10 m, before it stops. In commonly used vacuum sewer systems, the maximum velocity of the sewage mass in the sewer is about 5-10 m / s. The drain valve is normally kept open for about 4 s for every 10 drain operations.

The object of the invention is to provide a relatively quiet vacuum sewer system which operates better and more reliably than the device disclosed in Finnish patent 77082. The features of the invention appear from claim 1. By controlling the operation of the air discharge valve so that it is directly dependent on the pressure fluctuations caused by the drainage operation itself, the risk of malfunction is minimized.

By connecting the air outlet duct to the drain pipe as close as possible to the drain valve in the flow direction at the subsequent point, the best operational reliability is achieved.

The air discharge valve can be quite simple in construction. Preferably, it comprises an annular seat 25 surrounding the opening in open communication with the air discharge duct and a closing part which, in its closed position, separates the opening from the surrounding air space. The closure member is movable from the position in which it is attached to the seat to the position in which it is detached from the seat. This is preferably done in such a way that the closing part is limited to a guide chamber, which preferably has a flexible wall 30. By controlling the pressure in the control chamber, the movement of the closing part and thus the desired operation of the air release valve is achieved. Since the vacuum drainage system includes a control device which controls e.g. the operation of the drain valve, this: the control device can advantageously transmit a vacuum not only to the actuator of the drain valve 35 but also to the control chamber of the air discharge valve to provide an opening movement of the air discharge valve.

The noise level of the vacuum toilet according to the invention can be further reduced by providing the toilet bowl 5 in a manner known per se with a tight and preferably quite thick sound-insulating lid. When the tight lid is closed, the amount of air contained in the bowl may be too small, allowing additional air to be supplied to the toilet bowl via a separate line. This line can be connected to the air outlet duct of the vacuum drain 10, as disclosed in Finnish patent 77082, or it can be a completely separate line. The lowest noise level is reached if the the front end of the cable is outside the toilet room and if the cable is also suitably soundproofed. Equipping the line with a non-return valve prevents the odor from spreading through the line from the toilet bowl to the environment.

Thanks to the invention, even more reliable operation is achieved, which makes it possible to limit the opening time of the drain valve even more. The transported sewer masses-20 si generally passes the air outlet duct connection less than a second after the drain valve is opened. Normally, this is done for about 0.5 s after the drain valve has reached its fully open position. The air discharge valve, in turn, can open in less than 2.5 25 s, preferably 1 ... 2 s after the drain valve has opened.

These time intervals shall be selected in relation to the distance between the drain valve and the connection point of the air discharge duct and the assumed speed of movement of the drain mass at the beginning of the transport operation. It is absolutely essential that the 3Γ0 air discharge valve does not open until the transported sewage mass has completely passed the air discharge duct connection point. The air discharge valve can advantageously be open for about 5 s. In this case, more air enters the sewer than in the conventional vacuum sewer system-3p, which tends to prolong the transport distance of the sewer mass in the sewer.

92085 4

The invention also relates to a method for controlling a vacuum sewer system according to the invention. The method is known from the following combination of measures:

Sufficient vacuum is developed in the sewer pipe to transport the sewer mass 5 in the sewer pipe, then the sewer valve is opened, whereby the sewer mass in the drainage device is transferred to the sewer under close the drain valve and stop allowing air to enter the drain pipe through the air outlet duct after the sewer plug has traveled the entire distance of the drain pipe or is at least 10 m from the drain valve. In this way, the advantage is achieved that the separate sewage masses in the sewer pipe cannot be combined, which relatively often causes malfunctions in vacuum sewer devices where the method according to the invention is not applied.

The invention will now be described in more detail with reference to the accompanying drawing, in which Figure 1 schematically on a partially enlarged scale shows an embodiment of the invention. Fig. 2 schematically shows a system according to the invention with several toilets.

25 In the drawing, means 1 toilet bowl and 2 vacuum sewer pipes connected to it. Between the toilet and the drain there is a drain valve 3, the operation of which is controlled by utilizing the vacuum prevailing in the drain pipe 2. Various valves of this type are disclosed in Finnish Patents 49204 and 54173, German Pat. No. 2,652,878 and U.S. Pat. No. 3,807,431. As suitable valves are known, the structure of the valve is not described here.

• 5,92085

Immediately after the drain valve 3 in the drain pipe 2, the air outlet pipe 4 connected to the atmosphere is connected to the atmosphere. The air discharge pipe and the air discharge valve 6 at its upper end are surrounded by an outer pipe 5 20 containing sound-insulating material, which forms an inlet channel leading to the air discharge valve 6. Air flows into this inlet duct from below as indicated by arrows 15.

The system has a control device 7 to which the operating pulse 8 10 generated by the user of the toilet, e.g. at the push of a button, is applied. The operating impulse 8 may depend, for example, on the closing of the lid 17 of the toilet bowl or on other factors which it is desired to take into account in controlling the flushing of the toilet. Since these things are also known per se, neither the generation of the control pulse nor the operation of the control device 7 is described here.

The general principle in a vacuum drain device is that the drain valve only operates when there is sufficient vacuum in the drain pipe. In the embodiment shown in Figure 1, the vacuum required for the operation of the drain valve 3 is obtained from 20 sewers 2 via a branch pipe 9. This branch pipe is connected via a non-return valve 10 to a control device 7, which, when tuned by the operating pulse 8, transmits a vacuum from the sewer pipe 2 via a pipe 13 to the actuator of the sewer valve 3. In this case, the drain valve 3 opens and at the same time 25 the control device 7 also transmits a vacuum through the pipe 34 to the air discharge valve 6, which is then ready to open.

The air vent valve has a shut-off body, e.g. a thick rubber plate 30, which is normally attached to the upper end of the air vent pipe 4 30 but can be raised to the position shown by the dotted lines, allowing air to flow freely into the air vent pipe 4. This movement is provided by a control chamber 32 connected by a narrow tube 34. through the tube 13. The guide chamber 32 communicates partly 35 with a rubber plate 30 and partly with a rigid wall 38 to which the flexible wall 42 of the guide chamber 6 is connected via a flange 44. The resilient rubber wall 42 lightly presses the rubber plate 30 against the upper end of the air vent pipe 4.

Normally, the pressure in the pipe 13 is the same as the pressure in the toilet bowl 5 (e.g. normal atmospheric pressure or the pressure in the cabin of the aircraft in the aircraft), while the air discharge pipe 4 has a much lower pressure because it is in direct contact with the drain pipe 2. As a result, the rubber plate 30 remains firmly in contact with the upper end of the air exhaust pipe 4. Upon receiving the operating impulse 8, the control device 7 transmits a vacuum from the drain pipe 2 to the pipe 13. This opens the drain valve 3 and the sewer mass in the toilet bowl 1 is quickly pressed into the drain pipe 2 by the atmospheric pressure.

The pressure in the pipe 13 is transferred through the pipe 34 to the control chamber 32 and the pressures on both sides of the rubber plate 30 approach the same value. However, the spring force of the resilient wall 42 and the area difference 20 of the surfaces of the tube 4 of the rubber plate 30 and the pressure chamber 32 act so that the rubber plate 30 does not move from the end of the tube 4 and the air release valve remains closed. As the sewage mass from the toilet bowl 1 passes the pipe 4, the connection point 36 and is followed by the air from the toilet bowl 1, the pressure in the drain pipe 2 and pipe 4 rises, but the non-return valve 10 prevents a corresponding pressure rise in pipe 34. Then the rubber plate 30 rises the pipe 4 is inclined to the drain pipe 2. Approximately at the same time as the air discharge valve 6 opens, the control device 7 begins to transmit atmospheric pressure to the pipe 13, whereby the drain valve 30 closes. The same pressure also transfers to the control chamber 32, but with a small delay due to the length of the pipe 34, and thus causes the air discharge valve 6 to close.

*,, The lid 17 of the toilet bowl seals the toilet bowl 1 in its closed position 35 and the operating impulse 8 is transmitted only by the lid

Claims (10)

1. Vacuum discharge system with a capacity (1), 15 and a valve (2) for the use of a vacuum and a standard vacuum to determine the effective transport of the valve (2), and normally a valve (3) , in which case (1) the account is open (2), that the body (7) is connected to the valve 20 functions, that the body (1) is to be used in the form of a valve, and in the case of an airflow channel (4) ti avloppsröret (2) separat f rän. (6), the function of the air flow control (2), the function of the air flow control valve (6), the air flow control (6) erat 30 luftinsläppningskanalens anslutningspunkt (36) account av loppsröret (2). A vacuum drainage system comprising a drainable device (1), a sewer pipe (2), means for subjecting the interior of the sewer pipe to a vacuum capable of providing efficient transport of sewage mass, the sewer pipe 32085 8 in the sewer (3), normally closed , which connects the drainage device (1) to the drain pipe (2), a control device (7) for controlling the operation of the drain valve so that the drainage device (1) can be emptied from the sewer mass therein, and , characterized in that in order to direct the air flow through the air outlet duct (4) to the sewer pipe (2) when it is under the vacuum required for sewage transport, the system has an air release valve (6) controlled by pressure fluctuations in the sewer pipe (2), that the air discharge valve (6) does not open until the sewer has passed the air outlet connection (36) to the drain pipe (2). 2. An arrangement according to claim 1, which comprises the air ducts (4) and is provided with an open valve (3) and an account with an open valve (35) after the open valve (36). 11 92085 System according to Claim 1, characterized in that the air outlet duct (4) is connected to the drain pipe (2) near the drain valve (3) and in the flow direction of the drain mass at a point (36) downstream of the drain valve (3). 3. An arrangement according to claims 1 or 2, which comprises a flap valve (6) having a ring-shaped setting, which means that a flap channel (4) is provided with a flap (5), in which case (5) the terms of reference on the other side of the air and on the other side, on the other hand, on the account, on the other hand, on the other side of the air, on the other hand (30). System according to claim 1 or 2, characterized in that the air discharge valve (6) comprises an annular seat surrounding the opening in the open connection to the air discharge duct (4), a closing part (30) separating the opening from the surrounding air space and movable from a position in which it is attached to the seat, to a position where it is detached from the seat 25, and means for controlling the position of the closure member (30). 4. An arrangement according to claim 3, which can be used as part of a stem chamber (32), which is further adapted to a flexible stem (42), which also comprises a styrofoam (32). rädande trycket. A system according to claim 3, characterized in that the means for controlling the position of the closing part (30) comprise a 'control chamber (32), preferably delimited by a resilient wall (42), and means for controlling the pressure 30 in the control chamber (32). 5. An arrangement according to claim 4, which comprises a styrofoam (7) having a vacuum (13) for applying a vacuum to the valve (3) activating the air valve (6) of the valve (32). System according to claim 4, characterized in that the system control device (7) comprises means (13) for transferring the vacuum both to the operating device of the drain valve (3) and to the control chamber (32) of the air discharge valve (6). 9 92085 The connection 36 of the pipe 4 is so close to the drain valve 3 that the operation of the drain valve directly leads to the operation of the air discharge valve 6. The increase in pressure in the drain pipe 2 after the opening of the drain valve 3 causes the air discharge valve 6 to open, and this does not occur until the drain mass of the toilet bowl 10 has passed connection 36. When the drain valve closes, the pressure drop (increasing vacuum) in the drain pipe causes Therefore, the risk of malfunctions is very small. Fig. 2 shows a system in which a plurality of drain branches 48, each of which connects a unit to be drained via a drain valve 3, e.g. to a drain pipe 2 of a toilet bowl 1. Each drain branch 48 is connected to an air discharge valve 50 and a control device 7 operating according to the embodiment 20 of Fig. 1. The air discharge valves 50 each operate independently in such a way that, for example, the operation of the individual control device 7 tuned by the operating pulse 8 does not affect the operation of the drain valves and air discharge valves of the other toilets. The invention is not limited to the embodiment shown, but several variations are conceivable within the scope of the appended claims. 6. An arrangement according to the preceding claims, which comprises a closure (1) and a closure 20 with a locked air lock (17). System according to one of the preceding claims, characterized in that the drainable device (1) is a toilet bowl with a substantially airtight sound-insulating lid (17). 7. An arrangement according to claim 6, which can be used as a closure (1) and is provided (18) for inserting a lock (17) or a lock. A system according to claim 6, characterized in that a tube (18) is connected to the toilet bowl (1) for allowing air to enter the bowl with the bowl lid (17) closed. 7 92085 17 when closed. When the sewer valve 3 opens and the sewer mass is pressed into the sewer pipe 2, the air required for transporting the sewer mass is supplied to the toilet bowl 1 through a pipe 18 with a non-return valve 19 at the outer end. 8. An arrangement according to claim 7, which is shown in Fig. 25 (18) as a ratchet in the air of the toilet and the valve (19). System according to Claim 7, characterized in that the pipe (18) which allows air into the toilet bowl is provided with a non-return valve (19). 9. A vacuum coupling arrangement according to claim 1, which comprises a flange and a flange of a flap (48), which comprises a flange of a flux (2), the flux 3P being normally flush with a flap (3), in which case 1) account for the sale of the openings- 12 92085 gren (48), styrorgan (7) for the construction of the openings (3) function, air handling unit (4) for the installation of the openings (4) separate of the openings for sale (4) (1), a single airflow-5 channel (4), a single airflow valve (4), a single airflow valve (48), a single airflow valve (50), a single airflow airflow (4), the airflow channel (4), with the transfer of the genome in the same way (4) account for the transfer of the transfer price (48) 10 for the transfer of the transfer to the function of the transfer offer (48) tilen (3). Vacuum drainage system according to claim 1, characterized in that it comprises a plurality of drain branches (48) in open communication with the drain pipe (2), a plurality of normally closed drain valves (3), each of which connects the drainage device (1) to a sewer branch connected thereto. (48), control devices (7) for controlling the operation of the drain valves (3), air outlet ducts (4) for admitting air to the sewer branches (48) separately from a drainable device (1) connected thereto, each of the air outlet ducts (4) connected to a drain valve (48) near its drain valve (3), and air outlet valves (50) each connected to the air outlet duct (4) so that air access through any air outlet duct (4) to the drain branch (48) connected thereto can be controlled in connection with the operation of the drain valve 25 (3) of that drain branch. A method for controlling a vacuum sewer system comprising a drainable device (1), a sewer pipe (2), a normally closed sewer valve (3) connecting a drainable device (1) to a sewer pipe (2), and an air outlet duct (4) for venting air (2) separately from the drainage device (1), the air outlet duct (4) being connected to the drain pipe (2) near the drain valve, characterized by the following combination of measures: 92085 10 a sufficient vacuum is developed in the drain pipe (2) to transport the sewer mass, then 2 a drain valve (3), whereby the sewer mass in the drainage device (1) is transferred to the sewer pipe (2) under the influence of outdoor air pressure, forming a fast moving plug therein, immediately after the drain plug passes the point (36) where the air outlet (4) connects to the drain pipe (2), via vie to the sewer pipe (2) via the air outlet duct (4), close the drain valve and stop supplying air to the sewer pipe (2) via the air outlet duct (4) after the sewer plug has traveled the sewer pipe (2) the entire distance or at least 10 m from the drain valve (3). 10. For example, a styrofoam valve (2), an air valve (2), an air valve (2), an air valve (2), and an air valve (2), and an envelope (2), and an air valve (2); the airflow channel (4), with the airplane in the airflow channel (2) separating the airflow channel (1), the airflow airflow channel (4) being connected to the airflow channel (2) at the 20th airplane (2): ) for the purpose of transport by means of a mass in the form of a mass (2) with the aid of a vacuum, the end of the end of the valve (3) the image is provided in the form of 25 copies, which are shown at the same time as the passageway (36) of the passageway (4) and are shown in the passageway (2), the flywheel in the passageway (2) ftinsläppningskanalen (4), stängs avloppsventilen och avslutas luftinsläppningen account avloppsröret (2) genom .30 luftinsläppningskanalen (4), när avloppsmassaproppen har passerat hela avloppsröret (2) »· I