DE3617284A1 - Process and system for regulating the water discharge from a stormwater tank or a sewage pipe - Google Patents

Abstract

Process for regulating the discharge, taking place through an unsiphoned discharge pipe, from a stormwater tank or a sewage pipe of a sewerage system, and a system for carrying out the process. When a second water level is reached in the stormwater tank or sewage pipe, the regulator is switched on in order to regulate a nominal value of the throughflow of the discharge pipe. The regulator is, at a predetermined, lower first water level, or by time control, switched off again and the discharge pipe is once again shut off, the discharge pipe, however, still being full of waste water in the region of the throughflow measuring point.

Description

Process and system for regulating water drainage

from a rain basin or sewer pipe.

The invention relates to a method for regulating the through an uncovered Drain pipe taking place outflow from a rain basin or a sewer pipe a Sewer system according to the preamble of claim 1 and a system for implementation of the procedure.

Ungrained drainage pipes can also be used in the open throttle body Area of the flow measuring point run completely or partially empty, so that the flow they can become very small in dry weather.

In a known method of this type (DE-OS 29 44 733) the control of the nominal discharge is normally switched off and the throttle member is transferred to a predetermined first position and held in this, in which the uncovered discharge pipe is open for the flow of sewage, so that it can be traversed by sewage draining from the rain basin or sewer pipe even in dry weather. If there is a risk that the flow rate of the drainage pipe will exceed the nominal value, the area of the flow measuring point of the drainage pipe is first completely filled brought about and then switched on the regulation of the nominal discharge. This regulation is ended again, and the throttle element is returned to its first position when the water level in the rain basin or in the sewer pipe falls below a predetermined level, at which point the area of the flow measuring point of the drain pipe is still full. With this method, the drainpipe can run completely or partially empty and only so small amounts of wastewater / time flow through that there is a risk of heavy deposits of sludge, sand, feces or the like.

It is an object of the invention to reduce this risk of heavy deposits to reduce in the sewer pipe or canal downstream of the drainage pipe.

This object is achieved according to the invention by a method according to claim 1 solved. A second solution to this problem according to the invention is described in claim 2.

Both by the measure according to claim 1 and by the measure according to claim 2 it is achieved that the drain pipe with only approximately the nominal value Relatively large amounts of wastewater / time flowed through corresponding to the flow or completely closed off. As long as it is of this relatively large nominal flow is flowed through, which is provided so that no overloading of the downstream Sanaiization, sewage treatment plant or the like. Occurs, is the risk of stronger Deposits in the sewer pipe or canal downstream of the drain pipe because of the relatively high flow velocities of the sewage significantly reduced or completely Fixed. During the rest of the time, the drainpipe is shut off, so that out of it then in the downstream sewer pipe or sewer no mud or sand at all or other impurities can get there.

Since the drain pipe at the flow measuring point is always full, the total flow can be measured by means of an exact, the flow rate Flow meter, preferably by means of a magnetic inductive flow meter can be measured accurately.

According to a development of the invention, this can therefore be according to the invention Process also serve to remove the entire sewage runoff from the rain basin or

the sewer pipe quantitatively by taking the measured values of the flow meter are summed up.

This is an important benefit as it is often desirable, for example for cost accounting, planning, statistical purposes or the like Periods of time or the total amount of wastewater flowing off from the rain basin or the like to add up even in dry weather. In the method according to DE-OS 29 44 733 However, it is not possible to add up the amount of wastewater because the weather is dry the flow measuring point of the uncovered drain pipe run partially or completely empty and the flow meter sensing the flow rate of the sewage then has none can deliver more measured values corresponding to the flow.

Due to the variable adjustability of the second water level, you can the storage volumes of wastewater, the blocking times for the drainage and the switchover between regulated and blocked outflow of the average inflowing water volume adjusted and appropriately adjusted.

Through the development according to claim 6 deposits of dirt intensively removed and washed away in front of the throttle point, if this is done by Time to time is desired. It is usually sufficient to flush this away in each case only by one-time, abnormal switching off of the regulation or switching on of the increased Carry out the setpoint of the regulation and only repeat it at longer intervals.

This abnormal switch-off of the regulation is connected with an increase in the outflow by opening the throttle element appropriately wide. If the setpoint of the regulation is increased, this also causes the throttle element to open further. This increase in the outflow only has to be carried out for as long as the respective removal and flushing away of deposits requires. Normally, the drainage of the sewage takes place under control of the nominal outflow and it can, only if necessary, be provided from time to time, the outflow temporarily with abnormal shutdown of the control of the nominal value or increase of the setpoint of the control, preferably only relatively briefly to increase for the purpose of flushing away dirt and sludge and the like .. Even with the increased drain, the drain pipe at the flow measuring point is fully filled with sewage and the flow meter also measures the flow exactly, so that in the case of totaling the flow rate, this flow is also included recorded. If there is no risk of impermissibly thick deposits in front of the flow measuring point can accumulate, the measure according to claim 6 need of course not be provided.

The invention therefore also enables the entire flow to be recorded through the drain pipe by adding up the flow rate. This summation can be done in an integrator or other counter. The summed up Wastewater volume can, for example.

displayed and / or registered. The display or registration can be done in cubic meters, for example.

This integrator or the like thus forms a wastewater meter.

Exemplary embodiments of the invention are shown in the drawing. They show: FIG. 1 a schematic sectional illustration of a rain basin with an inlet channel and drain pipe according to a first embodiment of the invention in partial Representation, Fig. 2 in a schematic sectional view of a sewer pipe of a sewer system with a drain pipe in a partial illustration, FIG. 3 in a schematic sectional illustration a rain basin with inlet channel and drain pipe according to a further embodiment of the invention in detail.

At the rain basin 10 shown in Fig. 1 are an inlet channel 11 as well as a straight, almost horizontally laid uncovered drainage pipe 13 connected, which penetrates a dry slide shaft 12. This drain pipe 13 is means a throttle member 14 adjustable by an actuator 16 can be variably throttled and lockable. The actuator 16 can be used as a servomotor, for example as Electric motor or electromagnetic actuator, or as a hydraulic or pneumatic lifting cylinder Or the like. Be designed as a slide or pivotable throttle valve trained throttle member 14 acts. Upstream of the throttle member 14 is on Outflow pipe a flow meter 21 is arranged, which in the area of the flow measuring point 33 fully filled drain pipe 13 the flow of water / time (= flow) can measure the flow rate by sensing. This flow meter 21 can preferably an inductive flow meter measuring the flow rate or an ultrasound measuring device, but possibly another suitable one Be a measuring device. Furthermore, two pressure switches 24, 25 are formed in the drain pipe 13 Water level sensor arranged to detect two predetermined water levels W1 and W2 in the rain basin 10 are used. The lower predetermined water level is W1 so provided that with him on the one hand the drain pipe 13 in the area of the flow measuring point 33 is full, so that the measuring device 21 can measure the flow accurately and on the other hand through it at least the one corresponding to the nominal value of the flow Flow through the drain pipe can be effected, preferably one when fully opened Drosselorqan 14 still considerably larger flow.

The output signal of the flowmeter 21 is the actual value Actual value input of a controller 23 switched on, at whose setpoint input the means a setpoint adjuster 22 adjustable setpoint of the nominal discharge of the rain basin 10 is entered.

The controller 23 forms the difference between this setpoint and the measured actual value as control deviation and generates switching signals as a function of this, for regulating the respective system deviation via the actuator 16 and the Throttle member 14 enlarge and reduce the effective cross section at the throttle point or shut off the drain completely when the control is switched off. The regulator 23 is over a bistable switching element 26 can be switched on and off, the pressure switch 24 with its set input S and the pressure switch 25 with its reset input R connected is.

The assemblies 22, 23, 26 are in an electronic control and Contain control device 27, which can preferably be part of a microprocessor.

One, for example, as a signal sequence with a flow rate dependent Frequency present measurement signals of the flow meter 21 on summing integrator 28, which can also be called a wastewater meter, is used to record the total amount of waste water drained through the drain pipe 13. The summing up of the measurement signal can also be carried out in device 27 and the resulting numerical value registered and / or displayed.

For example, the reading of the counter or integrator 28 may be desired Points in time and the difference between the two different points in time read; numerical values then result in the period in question through the drainpipe 13 total flow Amount of wastewater. It can also be provided be that one uses the counter or integrator 28 only temporarily when summing up of the flow is to be carried out.

The method of operation of the system described is described in more detail below to be discribed.

It is assumed that the water level in the rain basin 10 is above the first water level W1, at which the pressure switch 24 responds, is and the controller 23 when the pressure switch previously reached the second water level W2 25 has been switched on. The controller 23 then regulates via the throttle element 14 caused by the outflowing sewage flow of the drain pipe 13 to the through the setpoint adjuster 22 specified nominal value. If the water level falls as a result of the Outflow down to the value W1, the pressure switch 24 generates a set signal for the bistable switching element 26, which thereby switches off the controller 23, which also the actuator 16 for immediately shutting off the drain pipe 13 by means of the throttle member 14 is controlled. This means that there is no longer any drainage of wastewater.

The drain is only restored when the controller is next switched on 26 added. The controller 23 can be switched off, for example, by setting the Setpoint to the value zero. Because of the shut-off of the drain pipe 13 increases the water level in the rain basin 10 rises again. He can never get the value that way Significantly below W1, Qo that the drain pipe 13 at the flow measuring point is always fully filled with sewage and this is still the case when it is open The throttle member 14 also runs completely or partially empty in the area of the flow measuring point 33 could, but this is prevented by the control described. If the Water level with controller 23 switched off the higher value W2 (2nd water level) again, which is, for example, one meter above W1, the second pressure switch speaks 25 and generates a reset signal for the bistable switching element 26. The controller 23 is switched on again and now regulates again via the throttle element 14 the flow of water to the nominal value of the flow of the drain pipe 13. The Sooner or later the water level will drop again until it falls below the value W1 from, and it then repeats the blocking of the drain pipe 13 and switching off of the controller 23.

The response threshold of the second pressure switch 25 is useful adjustable so that the water level W2 can be set appropriately can. Another adjustability is obtained by varying the setpoint the setpoint adjuster 22 or by abnormal shutdown of the controller 23 under, for example. full opening of the throttle member 14 to an amount of outflow above the nominal value to flush away deposits in front of the throttle point 14 from time to time. This abnormal shutdown of the controller 23 or an increase in its setpoint can occur during the total time of a sinking of the water level from W2 to W1 or by a shorter, stronger, preferably maximum opening of the throttle element 14 take place. This shutdown of the regulation or increase of the setpoint for the purpose The outflow can be increased, for example, manually or in a programmed manner, for example at or after every nth regulation of the nominal discharge, where n is 10 to 50, for example can be done, or at other suitable longer time intervals, if at all necessary is.

At that shown in Fig. 2, in a slide shaft 12 according to Fig. 1 arranged drain pipe 13 is installed with a slope instead of a rain basin 10 Sewer pipe 30 connected. To simplify FIG. 2, there are individual assemblies in the slide shaft 12 not shown again.

The mode of operation of the embodiment shown in FIG can correspond to the embodiment described above. When closed Throttle element 14, the water level rises here in sewer pipe 30.

It should also be mentioned that the regulation of the nominal value of the runoff also takes place when, after reaching the second water level, by the the controller has been switched on, this second water level has been exceeded one or more times before it switches off again by falling below the first water level of the controller and closing the throttle element 14 until the next time the second is reached Water level is coming.

The system shown in Fig. 3 differs from that according to Fig. 1 essentially in that the water level sensor 24 for sensing the first Water level W1 in the rain basin 10 has ceased to exist and in its place a timer 32 is provided. This time switch device 32 is by the pressure sensor 25 responding to the second water level W2 at the same time with the one used to regulate the nominal value of the flow through the drain pipe 13 Controller 23 is switched on and then measures a predetermined period of time, for example 10 min to 1 h, which is dimensioned so that even when there is no supply of wastewater to the rain basin 10 by regulating the nominal value of the flow of the drain pipe 13 a predetermined first water level W1 in the rain basin is not fallen below can. This first water level W1, which is not sensed in this case, is considerable lower than the water level W2, but still so large that the flow measuring point at it of the discharge pipe, so its clear cross-section in the area of the flow measuring point is still fully filled with sewage. This the setting of the time switch device 32 time span to be measured with the underlying first water level W1 can, for example like the water level W1 of the system according to FIG. 1, the clear peak height of the in this Embodiment correspond horizontally lying straight drain pipe 13 or lie a little above.

With the expiry of the timer 32 since the beginning of the regulation of the nominal value Period of time is the regulation of the nominal value terminated and the throttle element 14 is then activated by means of the switching element 26 Actuator 16 transferred to its shut-off position and remains in this as long as until the water level has risen again to the value W2, then the controller again 23 is switched on to regulate the flow rate to the nominal value. Even with this one Plant according to Fig. 3 is the drain pipe 13, if it is not shut off, at full filling of the flow measuring point 33 corresponding to the nominal value of the flow traversed by sewage and this gives accurate measurement of the flow and thus exact summation of the total flow through the drain pipe 13 and its Display on counter 28, if this addition is intended or

is switched on.

If at the end of the measured by the timer 32 Period of time the water level in the rain basin 10 is not below the value W2, but For example, as a result of a downpour above him, this has the consequence that the pressure switch 25 with the expiry of the timer 32 from the beginning of the regulation of the nominal value measured time, immediate restart of the timer 32 and of the controller 23 triggers and thus the drain pipe is not shut off, but the nominal value of the drain pipe again over that of the timer again is regulated over a measured time. This can of course be the case with strong Keep repeating the rainfall.

It can also be provided that the time switch device when rising of the water level in the rain basin 10 (or in the sewer pipe) not at the same time as the Controller 23 is switched on, but only when the pressure switch 25 signals that the water level in the rain basin or sewer pipe is below the second water level again W2 has dropped. One can also provide that, if this is done before the expiry the time period under measurement, the water level in the rain basin again Water level W2 reached due to a new rain event, then the timer is switched off again and thus reset to zero and only switched on again is when the second water level W2 is again undershot.

One can therefore provide the timing particularly expediently in such a way that that the regulation of the nominal value of the flow of the drain pipe then or at the latest is ended when the time interval to be measured by the time switch device 32 is measured from the beginning of the last fall below the second water level W2 and by the end of this period of time the second water level was no longer reached is.

- blank page -

Claims (11)

Claims 1. A method for regulating the by an ungedükertes Waste pipe taking place waste water runoff from a rain basin or a sewer pipe a sewerage system by placing a regulator to regulate the flow through the drain pipe by means of a throttle element which is assigned to the discharge pipe and can be adjusted by an actuator regulates temporarily to a nominal value, the actual value of the flow using a flow meter that senses the flow rate of the sewage in the drainpipe in the area of the flow measuring point located upstream of the throttle element is measured fully filled with waste water drain pipe, characterized in that a first predetermined water level (W1) is so high that the drainpipe with it (13) in the area of the flow measuring point is fully filled with wastewater that if the value falls below this first water level (W1) shut off the drain pipe (13) for the waste water drain and the regulation of the nominal value is ended and when a predetermined value is subsequently reached second higher water level (W2) the regulation of the nominal value is started again. 2. A method of regulating the flow through an uncovered drainpipe Wastewater runoff from a rain basin or a sewer pipe of a sewerage system, by regulating the flow through the drain pipe by means of a drain pipe subordinate, adjustable by an actuator Thrush organ regulates temporarily to a nominal value, the actual value of the flow using one of the flow rate of the sewage in the drain pipe sensing flow meter in the area of the flow measuring point located upstream of the throttle element is measured fully filled with waste water drain pipe, characterized in that the area of the flow measuring point of the drain pipe at a predetermined second Water level (W2) is fully filled with sewage that the drain pipe (13) normally it is closed off that if the resulting rise in what was If the second water level is reached in the rain basin or sewer pipe, then the control of the nominal value of the flow is switched on and switched off again time-controlled is, the timing is carried out so that even when there is no supply from sewage to the rain basin or sewer pipe during the regulation of the nominal value of the flow of the drain pipe a predetermined first water level (W1) in the rain basin or sewer pipe, in which the area of the flow measuring point (33) of the drain pipe is still completely filled with sewage, but this first water level is considerably lower than the second water level, and that the drain pipe on completion of the regulation of the nominal value of the flow again is locked and remains locked until the next regulation of the nominal value. 3. The method according to claim 2, characterized in that at the same time with the activation of the regulation of the nominal value of the flow rate or as soon as the value falls below it of the second water level started measuring for a predetermined period of time and that after this period of time the regulation of the nominal value at least is stopped when the water level in the rain basin or sewer pipe during the Measuring this time period does not rise again to the second water level, wherein then, if the water level rises during the measurement of this period of time in the rain basin or sewer pipe comes to the second water level, the regulation of the Nominal value with preferably restarting the measurement of the period of time at least it is continued until the water level falls below the second level again. 4. The method according to claim 1, 2 wire 3, characterized in that the measured values of the flow meter (21) are added up. 5. The method according to any one of the preceding claims, characterized in, that the second water level (W2) is variably adjustable and / or that the first water level approximately the height of the apex of the clear interior of the drain pipe (13) in the area corresponds to the flow measuring point. 6. The method according to any one of the preceding claims, characterized in that that the regulation for the purpose of increasing the drainage to flush away waste storages Can be switched off abnormally at times or to a setpoint that is to be regulated, which is considerable higher than the nominal value, is switchable, whereby the discharge is well above the nominal value is increased. 7. Plant for performing the method according to one of the claims 1 or 3 to 6, characterized in that two sensors (24, 25), preferably pressure switches, are provided for sensing the first water level and the second water level, that also a regulator (23) for regulating the nominal value of the flow of the uncovered Drain pipe (13) is provided, and that control means for shutting off the drain pipe (13) and switching off the controller (23) when the water level falls below the first level and reactivating the controller (23) in the wake of reaching it thereafter of the second water level are provided. 8. Plant for performing the method according to one of the claims 2 to 6, characterized in that a sensor (24, 25), preferably a pressure switch, for sensing the second water level it is provided that a controller (23) to regulate the nominal value of the flow of the uncovered drainpipe (13) it is provided that control means for switching on the controller (23) when reached the predetermined second water level and a timer device (32) for Shutdown of the controller and re-blocking of the drain pipe (13) are provided. 9. Plant according to claim 7 or 8, characterized in that a the measured values of the flow meter (21) totaling integrator (28) or the like. is connected to this flow meter (21). 10. Plant according to one of claims 7 to 9, characterized in that that the controller (23) is part of a microprocessor. 11. Plant according to one of claims 7 to 10, characterized in that that they carry out program means for programmed abnormal increase in the flow rate the drain pipe (13) has for the purpose of flushing away deposits.