EP1894638A1 - Method for rinsing a penstock and wastewater transport device - Google Patents

Abstract

A physical dimension is detected so as to determine a proportion for an amount of water carried through a high-pressure pipeline (HPP) in one or more pumping processes within a preset interval of time (delta T0). The HPP is scoured at the next point in time set in advance according to a plan. An independent claim is also included for a device for carrying sewage/waste water with a sewage/waste water collecting shaft, a pump for carrying sewage/waste water out of this shaft, a scouring device for scouring a high-pressure pipeline linked to the pump and a control device for switching the scouring device on and off.

Description

The invention relates to a method according to the preamble of claim 1 and a corresponding wastewater conveyor according to the preamble of claim 10. A corresponding method and a corresponding device are, for example DE 28 50 202 C2 known.

Pressure pipelines through which batchwise waste water from a sewage collection shaft is routed via a pump in sewage conveyors must be flushed at regular intervals. This is necessary because the effluents in the penstock during pump downtime contain biological loads that initiate biological processes during prolonged rest in the penstock, resulting in odors due to resulting decomposition and decay processes. For flushing such pressure pipelines the pressure pipe is usually flushed with compressed air at regular intervals, so that if possible no biological residues remain in the penstock.

Corresponding periodic rinsing operations are eg in DE 37 16 204 A1 described in which a method for improving the flow of a drain pipe in the sewer system is shown. In the known method, a strong jet is introduced with rinse water at regular intervals in the sewer. The aim of the purge is therefore, the volume of the penstock at least completely replace once in a given time interval.

Said regular flushing of the pressure pipes is uneconomical for various reasons, since the rinses occur even if the flushing of the penstock would not be necessary due to the amount of sewage incurred in the meantime.

Object of the present invention is therefore to improve the aforementioned method and said sewage conveyor to the effect that a more economical flushing of the penstock takes place.

This object is achieved by methods having the features of claim 1 and a sewage conveying device having the features of claim 10. Advantageous embodiments can be found in the subclaims.

According to the invention, the pump is connected to the pressure pipe via the in the sewer manhole, during a predetermined time interval possibly through several pumping operations volume compared with the volume of the penstock. If the volume delivered by the pump is greater than or equal to the volume of the penstock, no rinse cycle will be performed. If a given rinse cycle is imminent, this rinse cycle will be performed as specified.

If less wastewater has been pumped in the given time, i. the volume of the penstock has not been exchanged at least once during this time period, an unscheduled flushing occurs immediately. Alternatively, the detection of the volume can also be done over the switch-on of the pump. Then, the present during a certain time interval, added on times of the pump are compared with a predetermined time, which substantially corresponds to the time within which the contents of the penstock is replaced by the connected pump once.

As a result of the method according to the invention, wastewater conveyed by the pump, still standing in the pressure pipeline, is exchanged as often as necessary, so that disadvantageous biodegradation processes in the pressure pipeline are not made possible.

The method according to the invention is explained in more detail below with reference to a flow chart.

The method is preferably used for wastewater conveying devices, which have a pumping or collecting shaft 1, which is fed via a wastewater inlet 2 with wastewater and optionally via a rainwater inlet 3 with rainwater. In the shaft 1, a pump is provided, which pumps the collected water in the shaft 1 via a pressure pipe.

The apparatus also includes a flushing compressor 4 which flushes the penstock when needed.

Preferably, the flushing takes place with air, but in principle other gaseous or liquid substances are conceivable. For example, the flushing could also be flushed via a water supply line connected to the pressure pipeline. In this case, instead of the compressor 4, e.g. a pump and a leading to the pressure pipe solenoid valve can be used, which is opened in the rinse.

The device according to the invention has the initiation of the rinsing process via a controller, which decides depending on the amount of wastewater available, whether a rinsing process is required or not. The control method will be described below.

The control is set in the initial state so that a flushing of the pressure pipe at regular intervals .DELTA.T, ie at the purge times T _m = mΔT. Since the inflowing wastewater quantity is not constant over time and thus sometimes greatly varies the pumping processes lying in a time interval ΔT ₀ , the control according to the invention evaluates the pumping operations taking place in this interval and adapts the rinsing time points to such conditions.

For this purpose, the volumes pumped by the pump are detected directly or indirectly via the measurement of other physical quantities. Depending on the amount of waste water in the Shaft 1 carries out the pump in a time interval ΔT ₀ to be considered (preferably ΔT ₀ = ΔT) no, one or more pumping operations.

Accordingly, by the connected to the pump pressure pipe, which have the volume V _D , in n pumping operations corresponding volumes V ₁ , V ₂ , ..., V _{n transported} to water, so that in the time interval .DELTA.T ₀ funded total volume V _ges ( ΔT ₀ ) = V ₁ + V ₂ + ... + V _n . According to the invention, flushing of the pressure pipeline is required if the line volume V _{D of} the pressure pipeline has not been completely replaced at least once during the predetermined time ΔT ₀ . If no complete exchange took place in the time interval ΔT ₀ , there is a risk that rotting processes in the biological waste in the wastewater will be used, which should be bypassed by regular rinsing.

Therefore provides the comparison of the volumes V _ges (.DELTA.T ₀ ) and V _D , that V _{ges is} less than V _D , so that in the interval .DELTA.T _0, the volume of the penstock has not been replaced by pumping operations, the controller is a turn-on command to the Druckrohrspülkompressor (DRS) to flush the penstock. On the other hand, if V _ges (ΔT ₀ ) ≥ V _D , a sufficient volume has been exchanged by the pumping operations carried out in ΔT ₀ and an immediate rinsing process is not required, so that the next regular rinsing time T _m can be awaited.

Preference can also be given to the next regular rinsing process, although the pressure pipe volume in the interval ΔT ₀ has not been completely replaced, however, the generated as a result of the generated switch on the DRS at a time close to the next rotational rinse time T _m lying t is output. In this case, it is thus checked whether the time interval between T _m and the current time t is smaller than a predetermined value δt. If this is the case, the DRS compressor is switched on at the predetermined time T _m , if not, the purging process takes place immediately.

According to a preferred variant of the method, the further rotational flushing times T _m are adapted accordingly in the case of an immediate flushing at the time t, ie the flushing operations taking place at regular intervals ΔT are calculated from the time t on (T _m = t + mΔT). Thus, the system according to the invention is able to initiate a rinsing process of the pressure pipeline, if this is also necessary. In particular, the system is able to respond dynamically to the amount of wastewater produced.

In systems in which the shaft 1 has a rainwater inlet 3, the resulting rainwater can be considered in the initiation of rinsing. Reports a rain sensor 3a, for example, to the controller, that in the near future, a sufficient amount of water in the shaft 1 available and thus the possibility will be given to completely replace the line volume V _D by pumping operations, the purging operation is interrupted.

In the foregoing description, the purge control according to the present invention has been explained on the basis of a comparison of the volume of the pressure piping V _D with the total volume V _ges (ΔT ₀ ) delivered within a time interval from the pump through the pressure piping. In principle, however, it is not absolutely necessary for the control of the rinsing process to determine or record the volume directly. It is preferably provided instead of the detection of the volume V _tot to add only the switch-on times of the pump in the interval .DELTA.T ₀ and then to compare the addition result with a predetermined time value. This predetermined time value is determined as a function of the delivery rate of the pump and the volume of the pressure pipeline and corresponds approximately to the time required to deliver a volume of water which corresponds to the volume of the pressure pipeline V _D. This indirect measurement of the pumped by the volume volume consuming flow measuring devices are not required, it must only the operating time of the pump are detected.

In practice, the capacity of the pump is influenced by external factors. Thus, the capacity of the pump (and thus the volume pumped by the pump) depends on the instantaneous resistance in the penstock. If the filling level of the penstock is large, the pump pumps against a great resistance. Depending on the degree of filling in the penstock or its resistance, the operating point of the pump changes during the pumping process.

This has the consequence that the delivery rate of the pump changes during the pumping operation. It follows that the predetermined time value, which is to be compared with the accumulated switch-on times of the pump and which is obtained from the pump characteristic curve, represents only an approximate measure of the actual volume delivered by the pump in the time interval ΔT ₀ . According to the invention, a change in the delivery line can be detected by the controller by measuring the current consumption of the pump and from this the variable operating point (the time-varying delivery rate) of the pump is approximated. This increases the accuracy of the quantity determination.

Claims (12)

Method for flushing a pressure pipeline, in which a pressure pipeline is purged at intervals ΔT,
marked by a) detecting a physical quantity for determining the amount of water transported within a predetermined time interval ΔT ₀ through the penstock in one or more pumping operations; b) rinsing of the pressure pipeline until the next scheduled flushing time, if at a time t
either: b1) the amount of water reaches a given guide value, in particular the minimum reference value, which represents a direct or indirect measure of the volume of the penstock,
or b2) the time difference from time t to the next predetermined flushing time falls below a predetermined value δt; otherwise c) immediate flushing of the penstock. Method according to claim 1,
characterized,
that in step a) the total running time of the pump in Time interval .DELTA.T ₀ detected and this value is compared in step b) with a predetermined time. Method according to claim 1,
characterized,
that in step a) the total delivery volume (V _ges ) of the pump in the time interval .DELTA.T ₀ detected and this value in step b) with the volume (V _D ) of the penstock is compared. Method according to one of the preceding claims,
characterized,
that for determining the amount of water, the current or power consumption of the pump is detected during the pumping operation. Method according to one of the preceding claims,
characterized,
that the rinsing times are determined as a function of the pumped water volume. Method according to one of the preceding claims,
characterized,
that after the execution of step c) at time t, the next scheduled flushing time is set to t + ΔT. Method according to one of the preceding claims,
characterized,
that the intervals between the predetermined flushing times are the same. Method according to claim 7,
characterized,
that ΔT ₀ = ΔT holds. Method according to one of the preceding claims,
characterized,
that the flushing process is interrupted when a certain inflow amount of water to the pump is exceeded. Waste water conveying device with a waste water collecting shaft, a pump for conveying waste water from the waste water collecting shaft (1), a flushing device (4) for flushing a pressure pipeline connected to the pump and a control device for switching on and off the flushing device (4),
characterized,
that the control device is connected to a data acquisition device which detects the physical quantities representing the amount of water delivered by the pump within a predetermined time interval (ΔT ₀ ),
wherein the control device is adapted to a purging operation in dependence on the detected amount of water - Initiate at predetermined time intervals, if at a time t
either: (a) the quantity of water reaches a given guide value, in particular the minimum reference value, which is a direct or indirect measure of the volume of the penstock;
or b) the time difference from the time t to the next predetermined flushing time falls below a predetermined value δt; - Initiate immediately at the moment t, if none of the conditions a), b) applies. Sewer conveyor according to claim 10,
characterized,
in that a rainwater inlet (3) to the sewage collecting shaft (1) is provided, wherein the control device is further designed to interrupt or stop a flushing process when a certain amount of water in the rainwater inlet is exceeded. Sewer conveyor according to one of claims 10 or 11,
characterized,
in that the control device is designed to carry out a method according to one of Claims 1 to 9.

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