NL8400069A - Vacuum dewatering plant - for household vacuum sewage systems with pressure controlled vacuum valve - Google Patents

Abstract

In a vacuum dewatering plant having one or more collecting tanks under reduced pressure and vaccum pipes for effluent to which pipes under normal pressure communicating with the units to be dewatered are connected via a suction valve opening automatically whenever a pre-determined quantity of effluent has been collected, the novel feature whereby the suction valve remains open each time it opens for sufficient time for a volume of air two to fifteen times that of the effluent to flow into the vacuum pipe with the effluent and a horizontal or rising vaccum pipe is provided in known manner with rising and falling sections. More especially, the suction valve may be operated by the presence in the vacuum pipeline via a vacuum operated control device. Enables higher transport speeds to be achieved in vacuum dewatering plant than previously and the system is self-cleaning due to the turbulent flow.

Description

N.0. 32.218 ^ - Method for draining domestic waste water from * "a number of house connections.

The invention relates to a control device for a suction valve of a vacuum drainage system, which opens automatically when a certain level of the incoming waste water is reached and which closes again after suction of a certain water quantity and a subsequent air quantity.

A similar control device is known from Dutch patent application 71.04642.

When through a fluid reservoir which is alternately filled to a certain level and then emptied, control functions 10 of, for example, the valve for emptying are to be performed, floats or level sensors are usually used. Waste water, in particular also household waste water, contains both aggressive components which may corrode the float or sensor, as well as components which cause an increasingly strong crust formation thereon in the longer term and which thus render the said organs inoperative.

The object of the invention is to provide a control device of the type mentioned in the preamble, which operates freely for many years independently of the composition of the waste water.

According to the invention, this object is achieved in that the opening and closing of the suction valve is effected by an air cushion enclosed in a riser which communicates with the system of the incoming waste water.

As a result, only the suction valve itself comes into contact with the waste water. The valve is protected from deposits and blockages, as it is continuously cleaned by the liquid and air drawn through it at high speed.

If the air cushion enclosed in the riser were to act immediately on the actuation mechanism of the suction valve, it would open and close only slowly.

This created the danger that larger components in the waste water could get stuck in the valve and clog it. In a preferred embodiment of the invention, therefore, the measure has been taken that the negative pressure of the pipe system is also used for the rapid operation of the suction valve, because the control signal for opening the suction valve is controlled by a control 8400069 * * V - 2 - ring valve can be produced, which is manageable by the air cushion. By operation, the control valve can then connect a vacuum control line branched to the suction valve, branched behind the suction valve of the vacuum line, to a switching servo, which in the actuated final state opens an amplifier valve in a bypass line connected to the vacuilm control line, the first control valve.

The requirement of a low susceptibility to failure is particularly difficult to meet if the suction valve must be kept open for a certain period of time not only during the emptying of the waste water reservoir, but also after the collected waste water has been extracted, in order to obtain an accurately measured air quantity. allow the suctioned water to enter the system. By preference, the time control of the opening of the suction valve is achieved, because the switch servo is simultaneously designed as a relay and that in its operated final state another control valve can be switched, which blocks the connection of the switch servo with the vacuum line and one in communication with the outside atmosphere upright inlet pipe opens, in which a nozzle serving as a throttling point is arranged, wherein the shift servo can be returned to its initial position by its own weight and / or a return spring. The nozzle may preferably be adjustable or interchangeable to set the time period of resetting the shift servo to the home position.

8400069 - 3 -

The invention will be explained in more detail below with reference to the drawing.

The drawing schematically shows the starting point of a vacuum line 10, a suction valve 12 arranged in front of it and the end of a conventional sloping pipe 14 under atmospheric pressure, for example a ventilating discharge pipe of a house. The suction valve 12 may, for example, be of the type described in German patent 1,609 * 245. The vacuum line 10 runs to a collection reservoir, not shown and connected to a vacuum pump, to which the waste water is drawn. At a certain amount of filling, the collected amount is then pumped out of the collection reservoir against the underpressure of the pipe system and fed to a settling device. The vacuum line 10 can have a large number of branches (not shown) to other house connections and is in principle laid in the ground in such a way that at a distance from each other in the form of bags or drops, plugs of liquid can accumulate again and again. , which fill and seal the entire pipe cross section. Such a pipe system is also described, for example, in German patent 1,238,858, but for vacuum toilets. In a particularly simple embodiment, with a basically horizontal pipe run, the pipe is locally lifted at predetermined distances and supported with sand. The tubes are flexible enough to obtain desirably downwardly and re-styled pyping sections with thereby generated lows at which liquid plugs can form.

The suction valve 12 is normally closed and is opened only briefly in order to draw out water collected by the lower end of the housing connection pipe 14.

The actuator and automatic control of the suction valve preferably use the negative pressure available in the vacuum line 10. An additional energy source can be omitted there.

At the lower end of the slope line 14, no special reservoirs are required to collect the domestic waste water before the suction valve 12 is opened at time intervals. The conduit 14 itself preferably serves as a collection container.

Also, not too much waste water should be collected at this location, so that in the first place a rotting process is prevented and in the second place only relatively small amounts of it. -J · * s present water is supplied to the vacuum line.

The control device for the extractor valve 12, the important parts of which are shown in the drawing, is installed in its entirety in a control box, which is connected to the housing connection 14 via a styrofoam line 16 and furthermore via a control line 18 to the extractor valve. 12 and finally connected via a connecting line 20 to the vacuum line 1.0. The connecting line 20 is connected via a continuously opened line connection 22 and a line 24 to a diaphragm valve 26, which in the normal state by the continuously occurring negative pressure in lines 20 and 24 is kept closed. The diaphragm valve 26 opens at a certain pressure build-up in the styrene pipe 16. In the opened state, a connection is made by the diaphragm valve 26 between the pipe 24 and a pipe 28, which in turn communicates with a pipe 30 which is on a control valve 32 is connected. In the initial situation, this valve 32 connects the line 30 to a line 34, via which the vacuum reaches a shift servo 36. The latter has a piston 38 which is pulled upwards by an underpressure in the line 24 against the action of a .20 return spring not shown. A cam 40 is mounted on the piston 38, which in the upper end position actuates an amplifier valve 42 such that it connects the connected lines 20 and 28 together and thereby provides a by-pass, which is connected in parallel with the diaphragm valve 26 working with vacuum losses.

As a result, the line 30 does not receive full negative pressure until after the amplifier valve 42 is brought into the switched state by the cam 40, in which the lines 20 and 28 are connected to each other by the amplifier valve 42.

The control valve 32 is constructed by means of a spring and a snap-30 mechanism in such a way that it is automatically switched over by full negative pressure in the line 30, whereby the connection between the lines 30 and 34 is interrupted and the line 34 with the outer atmosphere connection is made. In this state, air can flow through the conduit 34 and a throttle opening 44 into the servo cylinder 36. By suitable selection of the throttling opening and thus the throttling action, the time period can be set, within which the piston 38 is pushed back into its lowest end position by the return spring (not shown). While the piston 38 drops at the predetermined speed, the cam 40 mounted on the piston 40 actuates another control valve 8400069 via a lever 46: The lever 46 is mounted so that the cam 40 is the control valve. valve 48 operates only during the descent but not during the upward movement of the piston 38.

As long as the cam 40 presses the lever 46 during the lowering of the piston 38, the control valve 48 connects the lines 18 and 20 together. However, the contact between the cam 40 and the lever 46 is only temporary. Before the piston 38 has reached its lowest end position, the control valve 48 closes the connection between the pipes 18 and 20 again. It is thinly understood that the lowering speed of the piston 38, which depends on the force of the return spring (not shown) and the throttling action of the throttle opening 44, as well as the weight of the piston 38, determines the length of time during which the suction valve 12 is connected to the negative pressure via its control line 18, the control valve 48 and the line 2Q and is thereby kept open. After the control valve 48 is closed, the suction valve 12 is also closed again.

Thus, by suitable selection of the opening 44 of the reset spring of the switching servo 38, the opening time of the suction valve 12 can be adjusted such that with each opening operation not only the amount of liquid present in the line I4, but subsequently also such an amount. amount of air is drawn into the vacuum line 10 and that under the pressure conditions of the vacuum line, the air volume is two to fifteen times the amount of liquid drawn in.

The aim is first to draw the waste water and then the air in the vacuum line, because the air has to extend the water for as long as possible. This can be fulfilled by suitable design of the lower end of the slope pipe 14, for example, because the suction valve 12 is connected via an eccentric reducing piece 50 to the pipe 14, through which the section with the decreasing cross section is laid at the lowest level.

The control device described above operates as follows.

In the initial state, the slope 14 and the riser 16 connected thereto are still empty. The atmospheric pressure prevails there. At this pressure, the diaphragm valve 26 keeps the connection between the connected pipes 24 and 28 closed. Thus, the negative pressure prevailing in the lines 20, 22 and 24 only reaches the diaphragm valve 26 and no further.

Wastewater is now present in the house, which is collected in the slope 14 and whose level also rises in the riser 16 ', an air volume is included in the stylet 16, that as the water level rises, it is increasingly compressed and thereby increasingly presses on the membrane of the membrane valve 26. When a certain pressure is reached, which corresponds to the maximum filling height of the waste water in the slope pipe 14, the membrane valve 26 opens the connection between the pipes 24 and 28. Via the pipe 28 the underpressure reaches the pipe 30 and from there via the control valve 32 the conduit 34 and the throttle opening 44 in the cylinder of the shift servo 36, so that the piston 38 thereof is pulled upward. In the upper end position of the piston 38, the cam mounted on the piston actuates the hitherto closed amplifier valve 42 which now establishes a direct connection between the lines 20 and 28. While previously the diaphragm valve 26 has supplied only a weakened vacuum to the pipes 28 and 30 at a loss, these pipes now obtain the full underpressure through the direct connection in the amplifying valve 42 until this underpressure reaches the control valve 32 with its full strength, it is automatically switched and interrupts the connection between lines 30 and 34 and opens the latter to the outer atmosphere. Air now penetrates via the conduit 34 and the throttle opening 44 lm the cylinder of the shift servo 36 and the piston 38 thereof is pushed back down by the return spring not shown. While the piston 38 falls at a speed determined by the size of the throttle opening 44, the cam 40 actuates the control valve 48 via the lever 46 during a certain period of time. In this period of time, the control valve 48 connects the line 20 in which there is an underpressure. the control line 18 of the suction valve 12 so that it is opened. The time period for opening the suction valve 12 30 is dimensioned in such a way that not only the waste water is drawn from the slope 14 and the riser 16 to the vacuum line 10, but also the 2 - 15 fold volume of air via the slope 14 to the vacuum line 10 can flow.

When the piston 38 approaches its lower end position, the cam 40 loses contact with the lever 46 on the control valve 48, so that it is closed again. In the meantime, the diaphragm valve 26 is also closed again, since the waste water is drawn out from the riser 16. Finally, at the end of its descending path, the piston 38 also resets the control valve 32 to the original position, 40 in which the lines 30 and 34 are connected to each other. Thus, the system is now in the initial state again.

8 A 0 0 0 6 9

Claims (8)

1. Control device for a suction valve of a vacuum drainage system, which opens automatically when a "certain level of the incoming waste water is reached and which closes again after the suction of a certain water quantity and a subsequent air quantity, characterized in that the opening and closing of the suction valve (12) is accomplished by an air cushion enclosed in a riser (16) communicating with the effluent water system. Control device according to claim 1, characterized in that the riser (16) is connected to a fall or fall pipe (14) serving as a waste water reservoir. Control device according to claim 1 or 2, characterized in that the control signal for opening the suction valve (12) is produced by a control valve (26) which can be actuated by the air cushion. Control device according to claim 3, characterized in that the control valve (26), by operation, branches off the vacuum line (10) behind the suction valve (12) from the vacuum line (10) and leads to the suction valve (12) with a vacuum control line (20 and 24). switch servo (36) which, in the actuated final state, opens an amplifier valve (42) connected in a short circuit (28, 30) connected to the vacuum control line (20) around the first control valve (26). 25 Control device according to claim 4, characterized in that the switching servo (36, 38) is also designed as a time relay. Control device according to claim 55, characterized in that in the actuated end position of the switch servo 30 (36, 38) a control valve (32) can be switched over, which blocks the connection of the switch servo to the vacuum control line and one with the outside atmosphere. connected input line opens, in which a throttle nozzle (44) is provided, wherein the shift servo (36, 38) can be returned to its initial position by its own weight and / or a reset spring. Control device according to claim 6, characterized in that the throttle nozzle (44) is adjustable and interchangeable in order to set the duration of reset of the switching servo 8400069-9 to the starting position. 8.4 0 0 0 6 9