NL1032977C2 - Water pipe system for providing water supply in e.g. building, has heating device next to inlet point to allow pipe to be rinsed with hot water which is removed from system end point - Google Patents

Abstract

A heating device (17) is provided next to the inlet point (4) connecting the system (1) to a water distribution network (3), in order to heat the water to a temperature sufficiently high enough to kill pathogens. The end point (9) in the system comprises an outlet (11) for discharging rinsing water. The inlet point, end point and tap point(s) are connected in series by the water pipe in a branch-free configuration so that when the pipe is being rinsed with water supplied via the inlet point, no stagnant water is located in the pipe.

Description

Brief indication: Water supply system and method for installing it.

DESCRIPTION

The present invention relates to a water supply system for supplying water, comprising for providing water, comprising an input point for coupling the water supply system to a water distribution network, an end point, and a plurality of taps for providing water in a facility, such as a building, wherein the entry point, the end point and the water transfer points are connected to each other using a pipe.

The invention further relates to a method for constructing a water supply system as described above.

Water supply systems such as above are known per se for providing water to one or more taps in a building, or other provision such as a campsite, boat, marina, etc. Conventional water supply systems, however, entail the risk of pathogens occurring therein. , as bacteria and viruses can multiply, and then spread throughout the building via the water supply. In recent years, the emergence of, for example, the legionella bacterium in water pipes, which can cause fatal veteran disease in some cases, has proved to be a persistent problem.

Certainly in cases where a water pipe is not frequently used, for example water pipes for supplying water to sprinkler installations, or water pipes in recreational homes or buildings with limited opening and facilities, such as for example campsites, the risk of contamination via the water pipe is considerable. This risk is increased when the ambient temperature is relatively high. A summer heat wave can raise the temperatures in a water pipe to values that are ideal for the propagation of certain bacteria. The legionella bacterium 30 already mentioned above, for example, multiplies extremely rapidly at water temperature values between 30 ° C and 40 ° C. A water pipeline along the jetty of a marina, which not only receives direct sunlight, but also reflected sunlight from the water, can easily become sufficiently warm in the summer to facilitate rapid propagation of the legionella bacteria.

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Published International Patent Application No. WO 2006/059898 discloses a water pipe system in which a heating ribbon is included. With the heating tape, the water in the water pipe can be heated to a temperature sufficiently high for the killing of pathogens. The water supply system can then be flushed through a flushing system, whereby the tapping points can be closed off for safety reasons during heating and flushing.

A drawback of the water pipe system described in the above-mentioned document is that with this system it is not easy to have all the water in the water pipe system reach the desired temperature, and that therefore the user can never be completely sure that after rinsing pathogens may still have remained in the leadership.

It is an object of the present invention to solve the aforementioned problems of the prior art, and to provide a system capable of effectively combating pathogens throughout the water supply system.

To this end, the invention provides a water supply system for supplying water, comprising an input point for coupling the water supply system to a water distribution network, an end point, and a plurality of tap points for providing water in a facility, such as a building, wherein the input point, the end point and the water transfer points are connected to each other by means of a pipe, and in which heating means for heating water to a temperature sufficiently high for killing pathogens are included at least near the inlet point, wherein the end point comprises a drain for discharging rinsing water from the water supply system, and wherein the input point, the end point and the taps are connected in a serial configuration branchlessly through the pipe, so as to be directly from the input point, along all taps, to make the endpoint flushable of the pipeline that is there h there is no motionless water in the pipe during flushing 30.

In the water pipe system according to the present invention, from the point of entry, all tap points and the end point are connected to each other in a serial configuration by the pipe, and there are no taps in the pipe. The conduit connects the different taps and the end point in such a way that the conduit can be flushed directly from the input point, along all taps to the end point, and in such a way that during the flushing of the conduit all water present is moving. There is no motionless water in the pipe when flushing.

Because there is no motionless water in the pipe during flushing of the pipe, it is not only ensured that the transport of heat in the pipe as a result of the flow proceeds so efficiently that all the water that is in the pipe has reached the desired temperature, but the water is also refreshed everywhere in the pipe during flushing. The pipe can be heated and flushed extremely efficiently in this way, so that the user can be sure that with a sufficiently long-term flushing, no pathogens will remain in the water pipe system.

The person skilled in the art will understand that the term "tap point", as used herein, is understood to mean any possible point in a water supply system from which water can be extracted from the water supply system, irrespective of the purpose of the water collection. Such taps may include, for example, taps, showers, water heaters and boilers, etc.

The water supply system as described above is suitable for use in facilities such as buildings, night ports, campsites, factories, vessels, caravans and other mobile residential units, etc. In particular, the water supply system is suitable for providing drinking water, but can can also be used in, for example, fire safety systems (sprinkler installations, etc.), rinsing and / or cooling water systems, etc., in particular when, when the water from the water pipe is taken, this water comes into contact with air that can be inhaled by persons. It has been found that pathogens such as, for example, legionella bacteria can spread through the air.

The pipe used in the water pipe system according to the present invention can be of any type, provided that it is suitable for the water pressure used in the water pipe system, and the temperatures that can be achieved by the pipe when, for example, the water in the pipe is heated.

The heating means must be able to heat the water in the water pipe at least in such a way that the temperature thereof is sufficiently high to kill pathogens. This temperature is different for pathogens of different nature. For example, for the legionella bacterium, the water in the water supply system must be heated to above 60 ° C.

It is furthermore noted here that the term motionless water is understood to mean water that does not move or does not move sufficiently during rinsing to be refreshed or heated during a rinsing action such that the temperature for killing pathogens is sufficiently long in can be maintained.

The heating means used in a water pipe system according to the invention can be formed by known and suitable conventional systems, such as geysers and the like, but can, according to a preferred embodiment, be formed by a heating ribbon included in the pipe. Such a heating ribbon is described, for example, in international patent application WO 2006/059898.

In a further embodiment of the water pipe system according to the invention, a loop is formed by the pipe comprising a forward pipe part and a return pipe part, wherein the end point is on the return pipe near the inlet point, wherein the heating means are located in the forward pipe part, wherein the end point is further adapted to close off the line downstream at the discharge during flushing, and wherein in the line between at least two of the tapping points closing means are included for closing off the line during normal operation of the water supply system outside flushing times.

With a water pipe system according to this embodiment, both a cold water and hot water system can be provided using a single system. Heating means are located in the forward pipe section, preferably in the vicinity of the inlet point. During normal operation of the water supply system (not when the water supply system is flushed), the closing means are sealed between the at least two taps. These closing means therefore provide a separation between the cold water and hot water system in this embodiment of the invention. The outgoing pipe part thereby forms the hot water system, wherein the heating means included in the outgoing pipe part can, for example, ensure heating of the water in the passing pipe part to a temperature that can be set by the user if desired. The return line part of the loop forms the cold water system, and by means of the connection to the input point the taps on the return line section can be supplied with cold water.

When the water pipe system according to this embodiment is to be flushed, the return pipe part is closed at the end point, and the closing means are opened between the at least two taps (which under normal circumstances separate the hot and cold water system). Water can only reach the end point from the input point via the forward pipe part, along the closing means, and back via the return pipe part to the end point. The return line part is therefore closed between the discharge and the input point.

The above-described embodiment offers the advantage that the water supply system according to the invention can simultaneously provide a cold and hot water system, while maintaining the advantages of being able to efficiently heat and flush the water in the pipe.

According to a further embodiment, the closing means comprise thermal insulation means between the two tapping points for thermally insulating the forward pipe section and the return pipe section. Such thermal insulating means prevent the return conduit, which operates as a cold water system, from being co-heated near the closing means between the two tapping points by the hot water in the outgoing conduit section.

The water supply system according to the present invention can further comprise means for periodically flushing the system, which means are adapted to control the heating means during flushing. Flushing can in this way be carried out fully automatically at set times, and according to a further embodiment, these means for flushing can be further arranged for opening and closing the discharge in dependence on flushing. Those skilled in the art will understand that the opening and closing of the closing means can also be controlled fully automatically by the means for flushing, when the water supply system according to claim 3, and described above, including the cold and hot water system is used.

Furthermore, the heating means can be adapted to be switched on in dependence on the use of at least one of the tapping points. This additional option offers the option of simply applying the heating means as heating means for a hot water system.

According to a second aspect of the invention, it provides a method for constructing a water pipe system according to any one of the preceding claims, the water pipe system comprising an input point for coupling the water pipe system to a water distribution network, an end point, and a plurality of taps for providing water in a facility, such as a building, wherein the input point, the end point and the water transfer points are connected to each other by means of a pipe, and in which heating means for heating water up to at least near the input point are included a temperature sufficiently high for killing pathogens, wherein the end point further comprises a drain for discharging flushing water from the water pipe system, and wherein the pipe is laid such that it enters the point of entry, the end point and the taps in a serial configuration connect branch branch for flushing the line directly from the inlet point, along all tap points, to the end point such that there is no motionless water in the line during a flush.

Special embodiments of the method according to the second aspect of the invention are described in dependent claims 9 and 10, aimed at including a heating ribbon in the pipe, and at installing a water pipe system in which the pipe is laid such that it has a loop with an outgoing pipe part and a return pipe part, which water pipe system can be used to provide both a cold water system and a hot water system.

The present invention will be further described with reference to a few preferred embodiments thereof, which are not intended as limiting, with reference to the accompanying figures, in which: figure 1 schematically shows a water pipe system according to the invention; figure 2 schematically shows a house in which a water pipe system according to the present invention is arranged; Figure 3 shows a water pipe system according to a further embodiment of the present invention.

Figure 1 shows a water pipe system 1, which is connected to a water distribution network, schematically indicated by pipeline 3. The water pipe system consists of a pipe 5, and is coupled to the water distribution network 3 by means of an input point 4 which is schematically indicated by a water meter. The entry point 4 forms the demarcation point between the private water supply system and the public water distribution network 3. A number of tapping points 8 are connected to the pipe 5 and at the end of the pipe 5 an end point 9 is provided with a drain 11 which can be controlled with an adjustable valve 10 can be opened and closed.

In the water pipe system 1, heating means are included in pipe 5, formed by a heating ribbon 17 extending in pipe 5 which can be electrically energized. Energization takes place under the management of a management system 13 which is connected to the heating ribbon 17 by means of connecting line 18. The control system 13 is also connected by means of connecting line 19 to the controllable valve 10 of the drain 11 at the end point 9. The drain 11 is adapted to discharge water into the pipe 5 into drain pipe 15 which opens onto the sewer which schematically is indicated by pipeline 16.

The tapping points 8 are schematically indicated in Figure 1. The taps 8 are connected to the pipe 5 in such a way that the pipe 5 is branchless. This is understood to mean that the taps 8 are connected in such a way that there are no pipe parts in the pipe 5 of the water pipe system 1, in which water can be moved without moving during the rinsing of the pipe 5.

Operation of the water supply system according to the invention is, for example, as follows. During normal operation of the water supply system, adjustable valve 10 of the drain 11 is shut off. The tap points 8 can now be used independently of each other for tapping water from the pipe 5. Water will flow from the water distribution network 3 via the input point 4 to the relevant used tap point 8.

The water supply system 1 can be flushed at set times, controlled by the control system 13. To this end, the heating ribbon 17 will be energized by the control system 13, so that the water in the pipe 5 is heated to a temperature at least so high that the pathogens in the water pipe 5 cannot survive therein. This temperature can for instance be maintained for a certain time. Controllable valve 10 is then opened, and the line 5 is flushed at once via the inlet point 4 with fresh water from the water distribution network 3. If desired, the heating ribbon 17 can remain in operation during the rinsing, so that flushing of the water supply system 1 takes place with fresh water heated by the ribbon 17 from the water distribution network 3. It is recommended, for the safety of the system, to switch off after the heating ribbon 17 to flush the pipe 5 for a sufficient length of time so that all the hot water has disappeared from the pipe 5. During flushing, the water from the pipe 5 will be flushed through the drain 11 and drain pipe 15 into the sewer 16.

In Figure 1 a heating ribbon 17 is used which extends substantially over the entire pipe 5 of the water pipe system 1 from the input point 4 to 15 at the end point 9.

Figure 2 shows another embodiment of the invention, in which the water supply system according to the invention is installed in a residential house 22. The residential house 22 has different floors, which are separated from each other by means of floors 20, and each floor can for instance comprise several rooms separated by walls 21, as schematically indicated.

The water pipe system according to the invention is again connected to a water distribution network 3, and comprises an input point 4, and an end point 9 and a pipe 5 extending between the input point 4 and the end point 9. The pipe 5 connects all taps 8 of the water pipe system in such a way with each other that the taps 8 are connected branch-free to the pipe 5. A serial configuration is thus created, and during a flushing action water is prevented from remaining motionless in parts of the pipe, so that it is hardly heated, if at all, and, moreover, is not refreshed by water from the water distribution network 3.

In the present embodiment, the heating ribbon 17 used in the embodiment shown in Figure 2 does not extend over the entire pipe 5, but only over a first part thereof, sufficient to heat the water therein such that during the rinsing of the system the water in pipe 9 can be sufficiently heated. Those skilled in the art will understand that if the heating ribbon, as in Figure 2, does not extend over the entire pipe 5 to the end point 9, longer flushing times are also required to get all the water in the pipe 5 to the desired temperature. Provided that such longer flushing times 5 are taken into account, this embodiment does not affect the efficiency with which the pathogens in the line 5 can be killed.

In the embodiment of Figure 3, a pipe 5 of the water pipe system also connects all tap points 8, to the input point 4 and the end point 9. However, the pipe 5 is formed such that it forms a loop running from the input point 4 via the forward pipe part 28 , the closing means 26, and the return line part 29 to end point 9. The tapping points 8 are distributed over the forward pipe part 28 and the return pipe part 29. In the vicinity of the input point 4, the heating ribbon 17 is arranged in the forward pipe part 28 which is connected with signal line 18 through means of the control system 13 can be energized. The closing means 26 separate the forward pipe part 28 from the return pipe part 29, and can also be opened and closed remotely with the aid of the control system 13. Closing means 26 are operated by means of signal line 24. In the return line part 29, at the end thereof (i.e. in the vicinity of input point 4), end point 9 is located as already described, downstream at end point 9, thus between end point 9 and input point 4, on the return line part 29, there is controllable valve 30. The controllable valve 30 can be controlled with signal line 25 by control system 13. Other components of the end point, such as drain 11, and controllable valve 10 have already been discussed above with respect to the other embodiments.

With the embodiment shown in Figure 3, both a hot water system and a cold water system can be integrally formed using the present invention. In normal operation, controllable valve 26 is shut off, so that the outgoing pipe part 28 forms the hot water system, and the return pipe part 29 forms the cold water system. Adjustable valve 30 is opened during normal operation, so that also the cold water system formed by return line part 29 can be supplied with fresh water. As already discussed, controllable valve 10 is also closed during normal operation. During normal operation, energization of the heating means 17 takes place in a conventional manner by, for example, tapping hot water via one of the tapping points 8 on the outgoing pipe 28. When one of the tapping points 8 is opened, and a pressure change can be felt in the forward pipe section 28, the energizing means 17 will be actuated so that they will heat the passing water in the forward pipe section 28 and so that it is offered to the opened tap 8.

Also, in normal operation, when one of the tapping points 8 is opened on the return line part, cold water can be supplied to the user that comes directly from the input point 4.

When, at periodic times, the control system 13 will flush the water supply system according to the invention, valve 26 will be opened, and valve 30 will be closed. Furthermore, heating means 17 will be energized, and the valve 10 at the end point 9 will also be opened. The opening of the valve 10 will start flowing water from the inlet point 4 via the outgoing pipe part 28 to the return pipe part 29, and the water will flow out via drain 11 into sewer 16. Because the water passes through heating ribbon 17, which is energized, it will water is heated and by rinsing over the entire conduit, so both the forward conduit portion 28 and the return conduit portion 29 are dispersed to kill the pathogens. The entire pipeline is also efficiently flushed.

The person skilled in the art will understand that instead of the heating ribbon used in figures 1, 2 and 3, the water supply system according to the present invention can also be provided with other heating means, such as for instance a conventional geyser.

The embodiments shown in the figures are intended solely to illustrate the system described in the invention. The context of the invention described herein is only limited by the following claims. It will be understood that the embodiments shown and described are therefore not intended to limit the invention.

1032977.

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Claims (10)

A water supply system for providing water, comprising an input point for coupling the water supply system to a water distribution network, an end point, and a plurality of draw points for providing water in a facility, such as a building, wherein the input point, the end point and the water transfer points are connected to each other by means of a conduit, and in which heating means for heating water to a temperature sufficiently high for killing pathogens are included at least near the inlet point, the end point being a drain for draining flushing water from the water supply system, and wherein the input point, the end point and the taps in a serial configuration are interconnected branchlessly through the pipe, so as to be directly from the input point, along all taps, to the end point 15 make the piping flush that is in the pipeline during it no motionless water is present. Water pipe system according to claim 1, wherein the heating means are formed by a heating ribbon included in the pipe. 3. Water pipe system according to claim 1 or 2, wherein a loop is formed by the pipe comprising a forward pipe part and a return pipe part, wherein the end point is on the return pipe near the inlet point, wherein the heating means are located in the forward pipe part, wherein the end point furthermore is arranged for closing the pipe downstream at the discharge during flushing, and wherein closing means are included in the pipe between at least two of the taps for closing the pipe during normal operation of the water pipe system outside flushing times. 4. Water pipe system according to claim 3, wherein the closing means comprise thermal insulation means for thermally insulating the forward pipe part and the return pipe part. Water supply system according to any one of the preceding claims, further comprising means for periodically flushing the system, which means are adapted to control the heating means during flushing. Water pipe system according to claim 5, wherein the heating means are further adapted to be switched on in dependence on the use of at least one of the tapping points. Water pipe system according to claim 5 or 6, wherein the means for flushing are further adapted to open and close the drain, depending on the flushing. 8. Method for constructing a water pipe system according to any one of the preceding claims, the water pipe system comprising an input point for coupling the water pipe system to a water distribution network, an end point, and a plurality of taps for supplying water in a facility, such as a building , wherein the input point, the end point and the water transfer points are connected to each other by means of a pipe, and in which heating means are heated at least near the input point 15 for heating water to a temperature sufficiently high for the water killing pathogens, wherein the end point further comprises a drain for draining rinsing water from the water pipe system, and wherein the pipe is laid such that it connects the input point, the end point and the taps in a serial configuration without branching, so as to directly from the input point, along all t points, making the pipe flushable to the end point that there is no motionless water in the pipe during a flush. 9. Method according to claim 8, wherein the step of including the heating means comprises the step of including a heating ribbon in the pipe. 10. Method as claimed in any of the claims 8 or 9, wherein the pipe is laid such that it forms a loop with an outgoing pipe part and a return pipe part, wherein the end point is arranged on the return pipe near the input point, in which the heating means are arranged in the outgoing pipe part, wherein the end point is adapted for closing the pipe downstream at the drain during flushing, and wherein closing means are included in the pipe between at least two of the taps for closing the pipe during normal operation of the water pipe system outside rinsing times. 1032977