DE19951174A1 - Flow limiting device for supply pipeline monitors instantaneous flow and operates blocking device if irregularity occurs - Google Patents

Abstract

The instantaneous flow rate is measured by a device (4) which is connected to a control unit (8) which adds the instantaneous flow rates to form an absolute flow rate, which it compares with a predetermined value. The control unit determines the time at which the instantaneous flow rate returns to zero. When the instantaneous flow rate returns to zero, before the absolute flow rate reaches the predetermined value, the control unit sets the absolute flow rate to an initial value. When the absolute flow rate reaches or exceeds a predetermined value, the control unit acts on a motor-activated blocking device (5) so that it interrupts the supply of flowing medium to various supplied units.

Description

The invention is directed to an arrangement for limiting the flow at a pipeline supply with a flowable medium supplied individual units.

In the case of individual units operated on a common pipeline, there is an emergency maneuverability, the individual units regardless of their respective areas to ensure that conditions are always the same. This ver Terms of care are usually of the terms in the details totally independent. As an example of such a system, public What server supply networks or public gas supply networks serve over one A large number of customers are supplied as individual units. Corresponding Ge However, there are also conditions in residential complexes with individual residential units units for individual units with individual tapping points as individual units or in industrial production plants with production units as individual units in front.

To separate the individual units from the common pipeline supply can, is usually a manually or motor-operated shut-off direction provided, by means of which the flow to the individual units is interrupted can be.  

In the individual units mentioned above, defects often occur, which lead to the medium supplied via the pipeline supply leaves uncontrolled. To prevent this, orders have already been issued provided, when the medium is suddenly removed by the individual unit at maximum flow rate, interrupt the supply and / or one Trigger alarm.

Furthermore, it is known to provide detectors that detect the presence of the record medium in prohibited areas and then use a tax unit block the supply and / or trigger an alarm.

Proceeding from this, the object of the invention is an arrangement to provide, regardless of the location of a defect in the individual units an inadmissible flow and then the supply of the medium to the Interrupts individual units via a shut-off device.

The task is solved by the fact that the mo mental flow rate measuring device is connected, with a Control unit interacts. The control unit can in a first off Form of education be designed so that on the one hand that of the measuring device detected current flow rate to an absolute flow rate sum lubricated and compared with at least one preset value and on the other hand the time at which the current flow rate is zero. Is the momentary flow rate zero, the control unit sets the absolute flow flow rate also to zero. Does the absolute flow rate reach one at the Control unit preset value, the control unit acts on the shut-off device such that this the supply of the medium to the individual unit below breaks. To reset the shut-off device is a manually operable on direction provided when the control unit actuates the shut-off device tion so acted that this opens the flow again.  

The arrangement described above allows the single unit depending ability to exceed a flow defined by the reference value to separate the quantity from the pipeline supply. One of them is advantageous term arrangement that the damage at un controlled discharge of the media transported via the piping system to be limited as a result of a defect. On the other hand, it is disadvantageous that low Quantities that emerge over a longer period of time as a result of a defect are relatively late can be recognized as inadmissible if there are no large ent took place.

In a second embodiment of the arrangement, the tax is provided to equip unit with a timer and to train so that the through Flow time in which the current flow rate is not zero and recorded with we compares at least one preset value. Is the current flow quantity zero, the control unit also sets the measured flow time to zero. If the recorded flow time reaches a preset on the control unit Value, the control unit acts on the shut-off device in such a way that the latter The supply of the medium to the individual unit is interrupted.

An arrangement according to the second form of training allows the individual unit in Dependence on exceeding a defined by the reference value to separate the flow time from the pipeline supply. One of the advantages is like arrangement that over the permissible flow time, the uncontrolled off occur small amounts per unit time of the trans via the piping system ported medium is recognized relatively early due to a defect. Disadvantageous is against that large amounts per unit of time resulting from a defect occur relatively late as inadmissible.

In a further development of the arrangements according to the invention, it can be provided that the training features of the control unit after the first training form the training features of the control unit according to the second form of training to combine. Such a combination makes it possible, on the one hand, to  the permissible flow rate the damage in the event of uncontrolled leakage of the Medium transported via the piping system as a result of a defect limit and ge the uncontrolled leakage over the permissible flow time Ringer quantities per unit of time of the transported via the piping system Detect medium due to a defect relatively early, which causes the fol against a corresponding defect.

With the help of the arrangements described above, it is advantageous possible to unhindered the medium to a normal extent from the pipeline ver supply and on the other hand exceeding the normal dimension and to identify and prevent unauthorized withdrawals in good time, that consequential damage can be kept within limits.

The above-mentioned measuring device for detecting the current Flow rate, the control unit and the shut-off device can be so Probably purely mechanical units as well as electrical or electronic working units.

A further advantageous embodiment is provided by a control unit before, which is assigned an alarm unit, such that the control unit at Er range of a presettable absolute flow rate and / or flow time triggers an alarm.

If the control unit is assigned an alarm unit, it makes sense to arrange it to further develop such that a first flow rate and / or or flow time can be preset and a second flow rate and / or Flow time, which leads to the action of the shut-off device, the first flow rate and / or flow time is less than the second flow flow rate and / or flow time. In this way it is possible to set the alarm prior to the interruption of the inflow by the shut-off unit in order to in the case of supervised removal that exceeds the normal level, by short-term i ges closing the tapping point to reset the control unit, so that too  withdrawals exceeding the normal level with supervised removal of the Medium are possible comfortably.

In a development of the above arrangement, the control unit can be designed in this way forms that the alarm is in a brief closing of the shut-off device tion exists, the control unit the flow rate caused thereby Ignored zero. This means that when the shut-off device is opened again Possibility of closing the tapping point again Reset control unit. Through the alarm directly at the removal comfort is superseded by supervised removal from the normal level quantities in progress increased. In addition, it is advantageous that none further means of alarming are necessary. The use of such Arrangement can be used, for example, in connection with irrigation systems for horticulture and agriculture, where the quantities withdrawn differ greatly and often larger amounts of water are removed in the supervised operation become.

For certain forms of application, e.g. B. in industrial production plants it may make sense to develop the control unit in such a way that a A large number of flow rates and flow times can be preset, whereby too a flow time belongs to a flow rate and the control unit the absolute flow rate currently recorded and the recorded flow time with the preset values. Such a further developed control unit is sensibly designed as an electronic control unit, the through Flow quantities and flow times as digital information in one in the tax digital storage unit are stored. The control unit can be a commercially available microprocessor.

For arrangements that contain a microprocessor as a control unit, it can be in advantageous further development be provided to design the control unit so that by entering it from monitoring mode into an acquisition Mode is shiftable in that it between the detected instantaneous flow  absolute flow rates and / or flow times recorded and stored in their memory. If this is done by entering it accordingly switch back to monitoring mode, the monitoring is carried out with the flow rates and / or flow times learned in the acquisition mode.

In a development of such an arrangement, it can also be provided that also the times in which the current flow rate is zero, so that there is an exact "image" of the removal cycles in the control unit and Any deviation from this is used for switching off and / or alarming that can.

An example of the arrangement according to the invention is below with the help of Drawings explained in more detail.

Show it:

Fig. 1 shows a first embodiment of the arrangement according to the invention in the form of a block diagram,

Fig. 2 shows a second embodiment of the arrangement according to the invention in the form of a block diagram.

A single unit 1 , e.g. B. the water distribution of a house is via a pipe 2 with a Rorleitungsversorgung 3 , z. B. public water supply connected. In the pipe 2 seen in the flow direction egg ne measuring device 4 and a shut-off device 5 is switched. The Meßeinrich device 4 is connected via its output 6 to a measuring input 7 and a reset input 14 of a control unit 8 . The control unit 8 has a control output 9 , which is connected to a motor drive 10 , which in turn acts on the shut-off device 5 . In addition, the control unit 8 has a connection to an input unit 11 , which is preferably carried out with the control unit 8 in a structural unit. At the control unit 8 , an alarm output 12 is also provided, which is connected to an alarm unit 13 .

In order to initialize the arrangement described above, a value is set on the input unit which serves as a reference value for the control unit for the monitoring function. The measuring device 4 delivers at its output 6 a measured quantity proportional to the instantaneous flow rate, which is recorded by the control unit 8 at its measuring input 7 , summed to an absolute value and compared with the reference value. Temporally parallel detects the Steuerein unit 8 via its reset input 14 supplied by the measuring device 4 instantaneous measured value. The control unit is designed internally so that they turn detects a by comparing the absolute value with the reference value the time at which the absolute value exceeds the reference value, and on the other hand, detects the timing on the measured variable at its reset input 14 to which the flow rate through the Pipeline 2 is zero. If the case occurs that the flow rate through the pipeline 2 is zero before the absolute value exceeds the reference value, the control unit resets the absolute value summed via the measuring input 7 to an initial value. If, on the other hand, the absolute value exceeds the reference value before the flow rate through the pipeline 2 is zero, the control unit 8, on the one hand, acts on the motor drive 10 via its control output 9 , which acts on the shut-off device 5 in such a way that it separates the individual unit 1 from the pipeline supply 3 and on the other hand, via its alarm output 12, the alarm unit 13 in such a way that it emits an alarm signal.

Of course, it can be provided that the control unit 8 is connected to a remote alarm device 15 via a corresponding output. To increase safety, a sensor 16 can also be provided, which, in the presence of the medium transported via the piping system, generates an output variable in inadmissible regions, which causes the control unit 8 to close the shut-off device 5 . To increase comfort, a remote input unit 18 can also be provided, which makes it possible to conveniently specify the reference value for the control unit from any point.

In an alternative embodiment, as shown in Fig. 2, the Steuerein unit 8 can be designed so that it contains a resettable time recording element 17 ent. As already stated above, the control unit 8 receives via its reset input 14 the instantaneous measured value supplied by the measuring device 4 . The control unit uses the measured variable at its reset input 14 to determine the point in time at which the flow rate through the pipeline 2 is zero and sets the time recording element 17 to an initial value. Is the flow rate equal to zero, the control unit 8, the time recording by the Zeiterfas sungsglied 17 free and compares the period of time detected by the time detection section 17 with a reference value. Exceeds the from the time detection section 17, he took period the reference value applied to the control unit 8 on the one hand via its control output 9 to the motor drive 10, which acts on the shut-off device 5 such that it separates the individual unit 1 of the pipeline supply 3 and the other, on its alarm output 12, the Alarm unit 13 such that it emits an alarm signal.

The features of the arrays can be of course according to Fig. 1 and combine Fig. 2 with each other is such that both a dose-dependent and time-dependent monitoring ei ne of the flow.

The control unit 8 shown in the above examples is preferably designed as an electronic circuit, in which case both analog and digital circuit technology can be used. The circuits necessary to implement their generally described functions are generally known and do not require any special explanation.

The connections between the control unit 8 and the connected devices can be designed both as a line connection and as a radio link.

Claims (8)

1. Arrangement for flow limitation in the case of individual units supplied with a flowable medium via a pipeline supply, a measuring device measuring the momentary flow rate being connected upstream of a shut-off device, characterized in that the measuring device ( 4 ) detecting the current flow rate is connected to a control unit ( 8 ). to cooperate, which is designed so that it on the one hand sums up the instantaneous flow rate detected by the measuring device ( 4 ) to an absolute flow rate and compares it with at least one presettable value and on the other hand detects the point in time at which the current flow rate becomes zero again and the Control unit ( 8 ), then when the instantaneous flow rate becomes zero again before the absolute flow rate reaches the presettable value, sets the absolute flow rate to an initial value and then when the absolute flow rate is set at the control unit ( 8 ) reached and / or exceeds tellable value, the motor-operated shut-off device ( 5 ) acts on such that it interrupts the supply of the medium to the individual unit ( 1 ). 2. Arrangement according to the preamble of claim 1, characterized in that a control unit ( 8 ) is provided which has a timer ( 17 ) which detects the time in which the instantaneous flow rate is not zero and this detected time with at least one presettable Compares the value and that the control unit ( 8 ) sets the detected flow time to an initial value when the instantaneous flow rate becomes zero and then when the flow time detected reaches and / or exceeds a value that can be preset on the control unit ( 8 ), the motor-operated shut-off device ( 5 ) Beats in such a way that this interrupts the supply of the medium to the individual unit ( 1 ). 3. Arrangement according to the preamble of claim 1, characterized ge indicates that the control unit both the characteristics according to the Kenn  Sign of claim 1, as well as the features according to the indicator of claim 2. 4. Arrangement according to claims 1 and / or 2, characterized in that the control unit ( 8 ) is assigned an alarm unit ( 13 ), the type that the control unit ( 8 ) when reaching and / or exceeding an adjustable absolute flow rate and / or flow time applied to the alarm unit ( 13 ) such that it emits an optical and / or acoustic and / or sensory signal. 5. Arrangement according to claims 1 and / or 2 and 4, characterized in that the control unit ( 8 ) is designed such that a first flow rate and / or flow time can be preset and a second flow rate and / or flow time, the first flow rate and / or flow time is less than the second flow rate and / or flow time and when the first flow rate and / or flow time is reached the control unit ( 8 ) acts on the alarm device ( 13 ) and when it reaches the second flow rate and / or flow time the Shut-off device ( 5 ). 6. Arrangement according to claims 4 and 5, characterized in that the alarm unit ( 13 ) is designed such that it briefly closes the shut-off device when acted upon by the control unit ( 8 ), the control unit ( 8 ) ignoring the resulting flow rate zero . 7. Arrangement according to claims 1 and / or 2, characterized in that a large number of flow rates and flow times are adjustable before, a flow time being assigned to each flow rate and the control unit ( 8 ) the currently detected absolute flow rate and the detected Flow time compared with the preset values. 8. Arrangement according to claim 7, characterized in that the control unit ( 8 ) is designed such that it can be set from the monitoring mode to a detection mode in which it detects absolute flow rates and / or flow times between the detected instantaneous flow rates and stores in its memory and that it can be reset from the detection mode to the monitoring mode and carries out the monitoring in the monitoring mode with the flow quantities and / or flow times learned in the detection mode.