NL2007432C2 - PIPE CLEANING SYSTEM FOR DISEASE PREVENTION, RELATED METHOD AND CONTROL UNIT. - Google Patents

Description

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Pipeline flushing system for disease prevention, and associated method and control unit

The present invention relates to a pipe flushing system for disease prevention, a method for flushing a pipe network and an associated control unit.

It is known that bacteria are always present in small quantities in the pipe network with our drinking water. If these amounts increase, a danger can arise to the health of the users of the water. The amount increases in particular when the water in the pipes is stationary and when its temperature is in a certain temperature range. For example, the legionella bacterium grows between approximately 25 and 50 degrees Celsius, there is hardly any growth below, the bacterium dies above it.

Pipe flushing systems for disease prevention are known. For example, there is a system that is integrated with a shower installation, in which the shower installation is connected to the drinking water network and during operation cold and hot water are mixed into water of approximately 38 degrees Celsius. The shower is activated by the user, that is, the water flows out of the shower 25 by pressing a button. The shower installation has a registration system that keeps track of when the shower was last used. It is thus possible to manually determine from the lapse of time since this last time whether there is a risk that an excessive amount of bacteria will develop in the shower installation, and then manually flush the shower if this danger is too great.

Furthermore, automatic flushing devices are known in which part of a drinking water network is periodically automatically flushed.

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These known devices have the drawback that they are insufficiently reliable.

The object of the invention is to reduce this disadvantage, in particular to obtain more assurance that the amount of bacteria in the drinking water system is low enough to be safe for the health of its users.

To this end, the invention provides a system according to claim 1.

By measuring with the aid of said flow sensor whether flushing has actually taken place and reporting this in the form of a flushing confirmation data, it becomes possible to prevent unexpected and despite the presence of a flushing device and the fact that there is an order rinsing is given, not rinsing on time. This creates a more reliable guarantee that the bacterial population remains sufficiently limited and that no contamination occurs.

In an advantageous embodiment, the system 20 is provided with at least one sensor, in particular a temperature sensor, which sensor for data communication is connected to said control unit and wherein the control unit is adapted to measure a state variable of 25 in continuously or periodically over a period of time. the liquid present in the pipe network or a quantity related to such a state variable with the aid of said sensor, the control unit is adapted to derive, on the basis of the measured values of said at least one sensor, an estimation parameter representative of the estimated size of a bacterial population in said conduit network or a portion thereof, and to output said activation signal when said estimation parameter has reached a predetermined value.

35 In this way, the actual environmental conditions are taken into account, so that the number of rinses can be better matched to the number actually required, in order to keep the risk of bacterial contamination below a certain threshold value.

Thus less unnecessary flushing has to take place. This is particularly the case when the sensor is a room temperature sensor or water flow sensor.

In another embodiment, the control unit is adapted to set said time counter to zero, in each case immediately after observing a predetermined flow rate or a predetermined amount of flow through said flow sensor. In this way, unnecessary rinsing is prevented even better.

In another embodiment, the control unit 15 is adapted to store said coil confirmation data and / or measured values in a digital logbook, which may be remote from the control unit and may be adapted to communicate with said digital logbook via at least one of a GSM connection, a LAN network 20 (ethernet and / or wifi) and internet. Thus, a retrospective check of the rinsing becomes possible without having to constantly pay attention to whether the rinsing confirmation data is actually produced with every rinsing.

The invention also relates to a method for flushing a pipe network, which pipe network comprises one or more liquid pipes as well as at least one liquid supply means and at least one drain valve located downstream thereof, from which drain valve in its open position when operating in the pipe network liquid flows away from the pipe network, which method comprises the following steps: - after determining a need for flushing at least a part of said pipe network for the purpose of preventing a health-threatening bacterial population from arising, which need is determined on the basis of time count and possibly other measurements, by opening a control unit of said drain valve for a period of time, - measuring the liquid flow directly or indirectly through said drain valve, and - giving a rinsing confirmation message, if the measured water flow rate is above a predetermined threshold value.

This method provides similar advantages to the device according to the invention, that is to say that as a result of the observation or flushing, there is actually a smaller risk that unexpectedly no flushing takes place and therefore there is a smaller chance of bacterial contamination.

Other advantageous embodiments of the method correspond to the described embodiments of the device and are defined in the dependent method claims.

The invention further relates to a control unit for a pipe flushing system of a pipe network, which control unit is adapted to open in operation each time a time counter reaches a certain time span value said at least one drain valve 25 for a time span for flushing a part of the conduit network, and to generate a coil confirmation data after a predetermined flow rate or predetermined amount of flow has been detected by said flow sensor with the drain valve open.

The control unit can herein be arranged to collect measurement data continuously or periodically and periodically to derive an estimation parameter from the measurement data collected which is representative of the estimated size of a bacterial population. The advantages of such a control unit are similar to those described for the entire system.

The system according to the present invention will now be further elucidated with reference to the figure below.

Figure 1 shows a schematic representation of a pipe flushing system according to the invention, comprising a water supply pipe 1 connected to a drinking water supply network (not shown) with a boiler 2 connected thereto and a pipe 4 connected to the hot water outlet 3 of the boiler 2, which pipe 4 branches downstream in two branches 5 and 6, of which branch 5 leads to a shower faucet 7 form a shower 8, and of which branch 6 leads to a hot water faucet 9 of a washbasin 10 which is placed in a kitchen.

A control unit 11, in this example mounted against a wall near the conduit 4, is connected via a data bus known per se to (a) two temperature sensors 12, 13 which are mounted on the branches 5 and 4, respectively. 6, and (b) two flow sensors 14, 15 which are located in the branches 5 and 6, respectively, near the drain valves 16 and 16 arranged therein. 17, (c) the two drain valves 16, 17, and.

(d) a temperature sensor 18 The control unit 11, designed as a digital computer, has a CPU 19 and memory means 20, human machine interface 21 with a screen 22 and keyboard 23, in addition a GSM antenna 24 and serial data port 25 of the known type RS-232. These components are interconnected in a known manner.

The operation of the system placed in one or more rooms, the temperature of which can be measured if desired, is as follows. The control unit 11 keeps a time counter for each pipe part to be monitored, in this case the two branches 5 and 6, 35. This time counter is set to zero after measurement of a flow rate through the flow sensor 14 or 15 present in the relevant pipe part, i.e. the relevant branch 5 or 6.

When a time counter reaches a threshold value which may differ per time counter and is dynamically determined in the manner to be described below, the control unit 11 opens the associated drain valve 16 or 17 and leaves it open for a period of time long enough to flush said pipe section clean with respect to bacteria possibly present therein, in particular legionella bacteria.

The threshold value for each pipe part to be monitored is determined by the control unit 11, namely by a computer program included therein and is chosen to allow a maximum amount of bacteria in the pipe part in question to be small enough to reduce the risk of bacterial contamination of users of the water. from the relevant pipe section below a value entered by a user, via the human machine interface 21 or via the GSM antenna 24 or the serial port 25.

In this exemplary embodiment, the threshold value of the time counter is derived from - the permitted risk of contamination, - the measured temperature variation of the relevant pipe section, and - the measured temperature variation of the water in the boiler 2.

Generally speaking, the threshold value will be chosen lower the longer the measured temperature has been between 30 and 60 degrees Celsius. Also when the boiler temperature has been between these two limits, usually it is above it when the boiler is in operation and just below it when the boiler is switched off, the calculated threshold value becomes lower.

Furthermore, a log 35 is kept in the memory means 20 of at least the measured flow rates, and - whether these were from the usual use of the shower tap 8 or the hot water tap 10 or from a rinsing with the aid of the drain valve 16 or the drain valve 17. .

This log can then be read via the screen 22 or remotely via the GSM antenna 24 or the serial port 25. Of course, an additional computer is required for remote reading (not shown).

The invention is not limited to the exemplary embodiment shown here. Thus, a different number of pipe sections 10 can be monitored, and, for example, when determining the threshold value, a room temperature of the room in which the pipes of the pipe flushing system are located can be included, as well as a measured amount of sunshine falling on these pipes. The pipe network can also be intended for cold water only, so it does not have a boiler or other heating device.

Claims (13)

A line prevention system for disease prevention, comprising a line network comprising one or more liquid lines and at least one liquid supply means and at least one drain valve located downstream thereof, from which, in the open position thereof, when the line network is in operation, liquid flows out of the line network, and a control unit connected for data communication with said at least one drain valve, which control unit is arranged to open in operation each time a time counter reaches a certain time span value said at least one drain valve for a time span for flushing a part of the pipe network 15 and the time counter reset to zero, characterized in that the system comprises at least one flow sensor, which is connected to said control unit for data communication and is mounted on or near said tap to sense flow through said door the coil section of the pipe network and / or through said drain valve, and the control unit is adapted to produce a coil confirmation data after said drain sensor has been detected in the pipe part with the drain valve open, or a predetermined amount of flow. 2. Pipe flushing system according to claim 1, wherein the system is provided with at least one further sensor, in particular a temperature sensor, which sensor for data communication is connected to said control unit and wherein the control unit is adapted to measure continuously or periodically during a period of time a state quantity of liquid present in the pipe network or a quantity related to such a state quantity with the aid of said sensor, the control unit is adapted to derive an estimation parameter on the basis of the measured values of at least one of the aforementioned sensors which is an estimate of the extent of a bacterial population in said pipeline network or a portion thereof, and for terminating said time span once said estimation parameter has reached a predetermined value. 10 3. Pipe flushing system according to claim 2, characterized in that at least one sensor or further sensor is a room temperature sensor, liquid temperature sensor, and / or a liquid flow sensor. 15 4. Pipe flushing system as claimed in any of the foregoing claims, characterized in that the control unit is adapted to set said time counter to zero, each time immediately after observing a predetermined flow rate or a predetermined amount of flow through said flow sensor. 5. Pipe flushing system according to one of the preceding claims, characterized in that the control unit is adapted to store said coil confirmation data and / or measured values in a digital logbook. 6. Pipe flushing system according to claim 5, characterized in that said digital log is remote from the control unit. 7. Pipe flushing system according to claim 5 or claim 6, characterized in that the control unit is adapted to communicate with said digital logbook via at least one of a GSM connection, a LAN network (such as ethernet - 10 - and / or wifi ) and internet. 8. Method for flushing a pipe network, which pipe network comprises one or more liquid pipes as well as at least one liquid supply means and at least one drain valve located downstream thereof, from which drain valve in its open position, when the pipe network is in operation, liquid flows out of the pipe network which method comprises the following steps: - after determining a need for flushing at least a part of said pipe network for the purpose of preventing a health-threatening bacterial population from arising, which need is determined on the basis of a time count and optionally other measurements, by a control unit opening said drain valve for a period of time, - measuring the liquid flow directly or indirectly through said drain valve, and giving a flush confirmation message if the measured value of the liquid flow is above a predetermined threshold value. 9. Method as claimed in claim 8, characterized in that said coil confirmation message is stored and / or communicated. 10. Method as claimed in claim 8 or claim 9, characterized in that said time count is reset to zero in each case after detecting a predetermined flow rate or a predetermined amount of flow through said flow sensor. A method according to any one of the preceding claims 8-10, characterized in that said determination of a flushing requirement is made on the basis of an estimation parameter which is representative of the estimated size of a bacterial population in said pipe network or a portion thereof, which estimation parameter is derived from a continuous or periodic measurement of a state quantity of liquid present in the pipe network or a quantity related to such a state quantity. 12. Control unit for a pipe flushing system of a pipe network, which control unit is arranged in operation each time a time counter reaches a certain time span value to open said at least one drain valve for a period of time for the purpose of flushing a part of the pipe network, and to after a predetermined flow rate or predetermined amount of flow has been observed by said flow sensor, with a drain valve open, to produce a coil confirmation data. 20 13. Control unit according to claim 12, wherein it is adapted to collect measurement data continuously or periodically and to periodically derive an estimation parameter from the measurement data collected which is representative of the estimated size of a bacterial population.