EP1845207A1 - Drinking and domestic water system and method for operating such a system - Google Patents

Abstract

The system has a transfer point of a public drinking water supply net, and a floor line and/or a riser line (2) and a set of closed circular pipes (10), where the pipes are guided to a tapping point (12) and arranged in series in an extension direction of the line. The circular pipes exit in the riser line and discharge in the line in the flow direction of the line. A controllable valve produces a rinsing current in the line in an opened condition, such that water in the line is exchanged and discharged into a sewage disposal network. An independent claim is also included for a method for operating a drinking or an industrial water system.

Description

The following invention relates to a drinking or service water system with a transfer point from a public drinking water supply network and with at least one floor or riser and several in the extension direction of the strand arranged one behind the other and each leading to at least one withdrawal point lines that depart from the strand.

The present invention relates in particular to a drinking or service water system according to the DE-U-93 02 446 out. This is considered in view of the preamble features of claim 1 as generic.

In particular, the present invention relates to a drinking and service water system in a building. In the context of the invention, floor ducting is understood in particular to mean a horizontally extending pipe which supplies a group or all rooms of a floor, for example a hotel or a hospital, with drinking or service water. A riser connects different floors of a building with each other and usually extends only in the vertical. From the riser pipe go from lines that usually supply superimposed wet cells of the building with drinking or service water. The present invention may be configured as a cold water system; but also conceivable is the training as a hot water system. The invention primarily intends to specify a corresponding drinking or service water system without permanent circulation.

In the above systems in a building there is the problem that if there is no extraction of drinking or service water at a consumer, the water in the line stagnates. If, for example, water is taken from a front consumer in the flow direction, only the line section of the water system leading to this front region is flowed through. The situation is similar for a riser pipe, if only in a lower floor water is removed. The water in the rest of the strand is in danger of becoming contaminated.

The present invention is based on the problem to provide a drinking or service water system, which ensures the most hygienic operation and with which the risk of contamination can be effectively countered. Furthermore, the present invention wants to specify a method for operating a drinking or service water system, by which the risk of contamination of the drinking or domestic water system can be effectively countered.

In order to solve the above problem in accordance with the present invention, the present invention provides a drinking or service water system having the features of claim 1. This drinking or service water system has at least one floor or riser pipe, which is fed via a transfer point from the public drinking water supply network. In the extension direction of the strand several ring lines are arranged one behind the other, each leading to at least one consumer. These loops go from the strand at a branch and open in the strand at an orifice which lies downstream of the branch in the flow direction. At the downstream end of the strand, a controllable valve is also provided, which allows flow in the strand in the open state and which connects the drinking or service water system with a discharge point for waste water to the public sewer network. The controllable valve can be operated in different ways to ensure flow in the entire strand at predetermined intervals even if water is not taken from the strand or only via a single loop. The controllable valve is an adjustable via a control signal valve and may for example be provided with a servomotor motor-driven valve. By opening the controllable valve, the standing in the strand including the connected ring lines water can be exchanged and discharged into the sewage disposal network. This effectively counteracts the risk of microbial contamination.

According to an alternative embodiment of the present invention, the ring lines and their branch or mouth on the strand are designed such that upon removal of drinking or service water to a consumer connected to the strand by a flow in the strand between the branch and the mouth or the Ring lines of the strand a pressure difference is generated by which in the consumer assigned and the one or more lying in the flow direction of the ring lines a purge flow is generated. The flow in the drinking or service water system takes place here solely due to the difference in pressure between the transfer point and the delivery point or the sampling point. In other words, the present invention, with its sidelined aspect, proposes a passive drinking or service water system which does not require a pump to provide flow in the system. The flow in the system is effected solely by the pressure potential which, due to the overpressure at the transfer point, rests against the pressure at a removal point. The driving force for a flow within the drinking or service water system according to the independent aspect of the present invention is thereafter only the overpressure in the line system, which rests on the public network in this. The drinking water system according to the invention is then designed so that a ring line with consumer, which is used for water extraction, upstream ring lines are flowed through because of the pressure difference in the strand with a purge flow. The pressure difference is effected by the flow generated in the strand to the consumer. In the case of a hotel, only the last hotel room in the direction of flow must be assigned an assigned sanitary unit in order to flow through the water in this room through the entire floor space of the assigned hotel floor. In this way, effective sterilization of all arranged on the strand loops can be prevented.

With the present invention, a drinking or service water system is to be specified, which ensures in a simple manner that a consumer can tap fresh water at a sampling point. According to the first alternative of the present invention, this is a controllable valve, that is usually provided a motor-driven valve, which can provide a flow and thus an exchange of spent water with fresh water. It is also about providing, for example, fresh cold water at the sampling points. The present invention wants to specify a simple as possible drinking or service water system. This should do without a circulation pump or the like. The flow in the drinking water system is accordingly effected in accordance with the sidelined aspect of the present invention solely by the difference between the pressure at the transfer point and the pressure at the delivery point. This means that the drinking or service water system according to the invention in particular a passive system that lacks a circulation pump that provides a constant flow. In connection with a controllable valve, although a corresponding circulation pump may be part of the drinking or service water system. With the present invention, but in particular by the delivery at the delivery point or a removal at the extraction point driven by the relative pressure at the feed point, ie the transfer point of the public network in the drinking or service water exchange of the water take place in the system. Accordingly, the present invention desirably seeks to prevent the water contained in the system from being purified by circulating and passing through a water treatment, as disclosed in US Pat DE 93 02 446 or DE 89 15 477 is known. In this prior art, although the flow of ring lines is effected by a Venturi effect. The flow through the entire drinking or service water system but takes place in this prior art via a pump which circulates the water contained in the system and processed in a separate treatment plant, in particular germ-free. Accordingly, in the context of the present invention, the piping systems described in the prior art are understood as active systems with circulation pump and active water treatment plant, whereas the present invention proposes a passive system in which to dispense with a pump and / or a water treatment plant. However, this does not mean that a drinking or service water system with a pump or a water treatment plant inevitably falls outside the scope of the patent, if this makes use of the subject matter of the independent claims 1 and / or 2 use.

In particular, the combination of the two sibling device-related solution aspects indicates a drinking or service water system, which can be effectively and selectively flushed both by targeted removal of a consumer as well as by providing the controllable valve. For example, should stay at a hotel for a long time an entire floor unoccupied, so by controlling the controllable valve, which is located at the end of the corresponding strand in the floor, the strand and the connected ring lines can be flowed through.

The ring lines and the branch to the respective ring line or the mouth of the respective ring line in the strand are dimensioned so that a flushing flow in the ring lines in any case results if, when water is removed from a consumer, which is connected via a ring lines this fluidically downstream ring line to the strand, respectively, a pressure difference between branch and mouth is generated through which a purge flow is generated in the upstream ring lines. As a common consumer is, for example, a hand basin, a toilet, a bath or a shower into consideration. Leakage flows, eg a dripping faucet, are usually considered insufficient. The flow to the consumer must be substantial, ie correspond to a normal consumption at the consumer. It is currently thought to derive due to the pressure difference about 10% of the volume flow through the strand in the respective loop. Such a flow rate is considered sufficient to sufficiently flow through the loop and to exchange the stagnant water there. Through the loop, the guided in the drinking or domestic water system water is brought very close to the respective consumers connected to the loop, so that almost all stagnant in the loop water is exchanged.

In the present application, a substantially continuous line extending in one floor is also referred to as a "strand", namely as a floor string. This is done for the sake of clear technical teaching in the present application. Such a floor string in the sense of the application is referred to in the art as a distribution line.

According to a preferred development of the present invention, the controllable valve is associated with a consumer which is connected to the ring line provided in the strand region. In particular, the strand end region is considered to be the end of the strand to which the last ring line in the direction of flow is connected. The controllable valve may be, for example, an indirectly controllable valve, for example, a toilet flush with cistern. Such valves are usually closed by a float. The dishwasher can eg have a controllable trigger, so that after triggered triggering of the cistern water flows in a conventional manner and the valve is closed by the float, ie indirectly after controlled actuation of the trigger. As this example shows, even with an indirectly controlled valve, a flow through the strand inevitably results. In this example, however not the valve directly, but a actuation of the valve indirectly causing trigger lever of the toilet box driven. At this point, water initially flows off. Thereafter, the valve causing the flow in the strand to open the cistern is opened. The embodiment described above facilitates the design effort for the implementation of the service or sewage system according to the invention and increases the safety of the user, since the possibly contaminated water is discharged through the sewer pipe of the toilet in the sewer system. Therefore, it is particularly suitable for housing vacancy over a long period of time to prevent contamination of the drinking water.

In a further preferred embodiment, the controllable valve is provided at the strand end and connects the strand with a connecting line. By activating the controllable valve provided at the end of the strand, the strand is flowed through and in this case preferably all the ring lines which are connected via the strand are flushed through. If several strands are provided one above the other in the case of storey strands or side by side in the case of riser strands, one controllable valve can be provided on each strand end. By simultaneous or offset driving the controllable valves, these strands can flow through simultaneously or offset in time, this longer exchanged stagnant water in the strand and the associated loops and replaced by fresh water. For a centrally controlled flushing is proposed according to a preferred embodiment of the present invention to equip a sewer at its rear in the flow direction, the connection of all strands following end with a controllable, for example motorized flush valve, which leads to the transfer to the public sewage disposal network. With such a purge valve, it is possible to flush through the entire service or sewage system by a single operation of a single valve. If individual controllable valves are provided at the end of the respective strands, the flushing of the drinking or service water system can be limited to those areas in which the water provided over the area has stood for a long time due to different uses compared to other areas.

A central flushing of all strands is made possible in a simple manner in that all strands are looped through, ie all strands are connected by extending transversely to the strands lines. Through suitable utilization concepts, In particular, by activating customers in the downstreammost strand, it is possible to reach the respective upstream strands and preferably the connected ring lines by consumption already at a consumer the necessary flushing of the drinking or service water system. If, for example, in a hotel used only seasonally a single controllable valve at the end of durchgeschliffener strands is provided, by operating the controllable valve, the entire drinking or domestic water system can be flowed through in the hotel.

The controllable valve or valves can be controlled in different ways to allow a cyclic, possibly alone demand-dependent flushing of or all strands. In a particularly simple embodiment, each controllable valve is time-controlled, for example by a battery-operated time module which is provided directly on the controllable valve. Such a configuration can dispense with all cabling for central control of the controllable valves.

With regard to a demand-oriented flushing of individual or all strands, however, it is preferable to control the controllable valves via a central control unit. In this control unit, the past occupancy, for example, of a hotel in the targeted control of the valves can be considered by the operator to flush only those strands, in which due to inadequate use is to be feared contamination. The replacement of potentially contaminated water from the drinking or service water system can be done in this preferred embodiment with careful use of water.

Particularly preferred is the development of the invention, in which flow and / or temperature sensors are provided on the drinking or service water unit whose measured values are processed in the central control unit for controlling the controllable or the controllable valves. Thus, for example, a flow meter and / or temperature sensor can be provided at the end of each individual strand, by means of which, for example, the actual removal via the last ring line in the direction of flow and / or the water temperature in the state are ascertained. Should this removal be at an insufficient level, the central controller will open the controllable valve associated with that string for purging. Any temperature sensors can handle the cycles of Rinses vary. These temperature sensors can reduce flushing intervals at high temperatures, such as in spa areas or in the summer months. The temperature sensors can determine current measured temperature values in the area of the drinking or service water system and compare them with given values for supercritical temperatures. In very cold temperatures can be omitted by appropriate signals of the temperature sensors flushing for a long time.

According to a preferred development, each strand for each connected thereto ring lines to a connection fitting, which is designed in the manner of a throttle and which has the mouth for the associated ring line. By the connection fitting with throttle function of the line pressure is reduced in the region of the mouth of the loop, whereby the flushing flow is effected in the associated ring line in flow in the strand. Preferably, the connection fitting with throttle for the mouth of the ring line is integrally formed with a further pipe section, which realizes the branch of the respective ring line of the strand. The strand then has to each arranged on this strand ring line a one-piece fitting, which forms a branch and an orifice for the associated ring line. By this configuration, the assembly effort for the realization of the drinking or domestic water system according to the invention can be reduced.

The above-mentioned, the branch and the mouth realizing valve is realized as a unitary Ringleitungsspülarmatur. Preferably, regardless of the specific configuration of branch and mouth of the branch and the mouth of a single loop a distance in the extension direction of the strand of less than 0.3 m.

For practical reasons, it is preferable to provide each full-flow Abspenventile between the branch and the mouth of a single loop on the strand and the associated ring line. These shut-off valves should preferably be free of dead space. In addition, it is preferable to form the shut-off valves with a relatively small pressure difference. According to the concept underlying the invention for generating a scavenging flow in the respective ring line, this is effected solely by the pressure difference which results due to the flow in the strand. On a forced flow by a pump installed in the drinking or domestic water system for flushing the individual loops or strand should be dispensed with, and so it is preferable to form the full-flow shut-off valve as a ball valve, preferably with a flow diameter which is approximately the flow diameter the ring line corresponds. The low, generated by the full flow shut-off valves pressure loss across the valves allows a relatively high flow even at low pressure difference between the branch and the mouth of the respective loop.

According to a further preferred embodiment of the drinking or service water system according to the invention this has a circulation line which connects the end of the last strand in the flow direction with the beginning of the first strand in the flow direction. By this circulation passage, it is possible to establish circulation within the water system due to a pump installed in the circulation passage. This also has a water treatment unit, which can be formed, for example, by a biological elimination unit in which germs of the drinking water are killed. This development can be essential to the invention and makes it possible to intensively treat water that has possibly been germinated by circulation of water within the water system through the water purification system, even from the ring pipes. In the cleaning unit, for example, chemicals or the like may be added, which circulate for cleaning and disinfection of the drinking or service water system in this multiple times before the treated cleaning water is discharged through the sewage disposal network.

To solve the procedural aspect of the present invention, a method for operating a service or sewage system with at least one story or riser and several in the extension direction of the strand arranged one behind the other and each leading to at least one consumer loops proposed, which branch off from the strand and in Flow direction of the strand behind it open into the strand. For exchanging stale water from the drinking or service water system is proposed by the method according to the present invention, by opening a provided at the end of a strand controllable valve between the branch and the mouth of each loop of the strand to produce a pressure difference through which the associated ring line a scavenging flow is produced. In this case, the used water is preferably delivered to the public sewage disposal network downstream of a delivery point downstream of the controllable valve.

Fig. 1

eine schematische Ansicht eines ersten Ausführungsbeispiels eines Trink- bzw. Brauchwassersystems;

Fig. 2

eine Detailansicht einer in Fig. 1 gezeigten Nasszelle;

Fig. 3

eine schematische Darstellung eines zweiten Ausführungsbeispiels eines Trink- oder Brauchwassersystems;

Fig. 4

eine schematische Darstellung eines dritten Ausführungsbeispiels;

Fig. 5

eine schematische Darstellung eines vierten Ausführungsbeispiels;

Fig. 6

eine schematische Darstellung eines fünften Ausführungsbeispiels und

Fig. 7

eine schematische Darstellung eines Ausführungsbeispiels einer in dem Strang zu installierenden Ringleitungsspülarmatur.

Further advantages and details of the present invention will become apparent from the following description and some embodiments in conjunction with the drawings. In this show:

Fig. 1

a schematic view of a first embodiment of a drinking or domestic water system;

Fig. 2

a detailed view of a wet cell shown in Figure 1;

Fig. 3

a schematic representation of a second embodiment of a drinking or domestic water system;

Fig. 4

a schematic representation of a third embodiment;

Fig. 5

a schematic representation of a fourth embodiment;

Fig. 6

a schematic representation of a fifth embodiment and

Fig. 7

a schematic representation of an embodiment of a to be installed in the strand Ringleitungsspülarmatur.

The embodiment shown in FIGS. 1 and 2 illustrates a drinking and service water installation on the example of a hotel or a hospital. On a floor schematically shown runs a cold water line 2 and parallel thereto, a hot water pipe 4 and a hot water circulation pipe 6 is provided. The hot water circulation line leads in a manner not shown, but well known to each individual wet cell 8. Each wet cell 8 also has a ring line 10 for cold water, which is connected to the cold water line 2 each. Every ring line 10 has a plurality of consumers 12, which are schematically indicated in the embodiment in FIGS. 1 and 2 with a dot.

Consumers may be a toilet 12a, a shower 12b, a bathtub 12c or a hand basin 12d. The removal point 12a-d are connected in series in the ring line 10. The ring line 10 goes via a branch 14 from the cold water strand 2 and flows through an orifice 16 in this strand 2 a. The branch 14 of each individual ring line is upstream of the mouth 16 in the direction of flow (arrow S in the cold water line 2). From the corridor or the respective wet cell 8 are available in the loop 10 ball valves as full flow shut-off valves 18a, 18b provided, through which the connected thereto ring line 10 can be shut off from the cold water strand 2, for example, perform assembly work on the corresponding loop 10. At the same place are also the shut-off valves 20a, 20b for the hot water 4 and the hot water circulation line 6 for the respective wet cell. The valves 18, 20 are dead-space-free valves that meet the legal requirements that are placed on valves that are installed in drinking and service water systems. In the embodiment shown, the valves comply with the European standard EN 13828 and the certification guideline according to DVGW worksheet W 570. The valves 18, 20 are provided as flush valves.

In Fig. 3 cold water pipes of a drinking water system in a multi-storey house, such as a hospital are shown. In each floor water pipes can be laid as shown in FIGS. 1 and 2. The cold water line system shown in Fig. 3 has a transfer point 22 from the public drinking water supply network, extending in the vertical direction riser 24, from which in each floor a horizontally extending floor string 2 goes off, a running in the vertical connecting line 26, with the interposition of a controllable Valve 28 is in each case connected to the individual floor strands 2 and leads via a likewise controllable flush valve 30 to a discharge point 32 for used water to the public sewage disposal network. The individual cold water floor strands 2 run in a horizontal direction and one above the other. In each floor a strand 2 is provided. In the second embodiment of the present invention shown in FIG Each strand 2 has six ring lines 10, which depart via branches 14 and orifices 16 from the individual strands 2 and open into them.

In the third exemplary embodiment shown in FIG. 4, a plurality of riser strands 2.1 to 2.4 laid in the vertical direction are provided. At the front end in the flow direction of the respective strands 2 are shut-off valves 33, which are provided between the individual strands 2.1 to 2.3 and a horizontal distribution line. The individual riser strands 2.1 to 2.4 enforce four superimposed floors in the embodiment shown. For reasons of simplified illustration, only a single wet cell 8 is shown schematically. In the upper floor all ring lines 10 are shown schematically. The underlying wet cells with the associated loops are not shown. The corresponding embodiment is indicated only by the mouth 16 provided on the floor. At the end of the three left branches 2.1 to 2.3 are the controllable valves 28. These valves 28 are provided between the individual strands 2.1 to 2.3 and a transverse line 36, whose distal end is connected to the last strand 2.4, which a falling in the vertical direction Flow leads and has at its end the purge valve 30, which leads to the discharge point.

In the fourth embodiment of the present invention shown in Fig. 5 horizontally laid parallel floor strands 2 are provided, which are looped through. Accordingly, located at the end of each strand 2 a riser 35, which leads to the next floor strand 2 and is connected to the upstream end of the overlying floor strand 2 in the flow direction. The uppermost strand 2.4 terminates in a sewer line 26 provided with a purge valve 30 leading to the spent water discharge point 32. In the embodiment shown in Fig. 5, this purge valve 30 is located in a basement. However, it can be provided at any point behind the last loop 10 of the uppermost strand 2.4.

In the embodiment shown in Fig. 6, a cold water circulation system with two parallel riser strands 2 is shown. Each individual riser string 2 supplies two opposite wet cells 8 with cold water per floor. That in the direction of flow Rear end of the first, in Fig. 6 left strand 2.1 is connected via a transverse line 36 with the front end in the flow direction of the second right strand 2.2. However, the second riser 2.2 opens into a controllable flush valve 30, which leads to a discharge point 32 for spent water to the sewer. Before connecting to this flush valve 30, however, a tee is provided which leads to a circulation line 38 which comprises a pump 40 and a biological elimination unit 42 and connected via a further T-piece to the upstream end of the first riser string 2.1 is. The circulation line 38 can be closed by controllable control valves, for example. Usually, the cold water provided in the exemplary embodiment shown in FIG. 6 is guided from the transfer point 22 via the first riser strand 2.1, the transverse line 36 and through the second riser strand 2.2. If the flow is insufficient, the flushing valve 30 can be opened and any cold water in the piping system can be discharged to the sewage system. In the case of heavy soiling, it is possible to guide the water which is intrinsically in the line system by operating the pump 40 through the biological elimination unit 42 and to treat it there. Thereafter, the treated water may be returned to the system, but preferably drained via the sewage network after opening the purge valve 30.

Fig. 7 shows schematically the connection of each ring line 10 shown schematically in the previous embodiments to the associated strand 2. Branch 14 and mouth 16 are provided on a uniform Ringleitungsspülarmatur 44, which is designed as a branch and connection fitting. In a front region of the ring-line flushing fitting 44 in the direction of flow, a branch piece 46 extends transversely to the direction of extension of the strand 2 from the ring-line flushing fitting 44. This branch pipe 46 is connected to the ring line 10. The rear end of the ring line 10 in the direction of flow is connected to a likewise extending transversely to the extension of the strand 2 return pipe 48. This return pipe 48 opens in the narrowed cross-section of a throttle 50, which is provided at the downstream end of the Ringleitungsspülarmatur 44, or immediately thereafter. The branch pipe 46 and the return pipe 48 are spaced less than 30 cm apart. The throttle 50 is designed such that between the branch 14 and the mouth 16, a pressure difference of about 20 to 50 mbar is set, for example, if at the respective End of the corresponding strand 2 provided valve 28 is operated to flush the strand or a downstream sampling point. This pressure difference is sufficient to generate a circulating flushing flow within the respective ring line 10. As a guideline, a velocity of the flow S in the strand of about 1.5 m / second is assumed. The orifice 16, the branch 14 and the throttle 50 are designed such that about 10% of the flow S in the strand as loop flow R flush the respective loop 10, whereas about 90% as the main flow H continue the line flush and in the throttle 50th be throttled.

To avoid microbial contamination of the embodiment shown in FIG. 3, the individual valves 28 can be controlled, for example, by a central controller. Usually, the valves 28.1 to 28.4 are each first opened and closed in order to flush the respective ring lines in the strands 2.1 to 2.4 in the respective areas in succession. The flush valve 30 remains open in such a procedure, so that any contaminated water from the individual strands 2.1 to 2.4 can be discharged directly into the sewer system. If care is taken to ensure sufficient hydraulic balancing between the individual strands 2.1 to 2.4, the individual valves 28 can optionally also be dispensed with and all the strands 2.1 to 2.4 can be purged by opening the flushing valve 30 alone. The embodiment shown in Fig. 3, however, is based on the finding that safe flushing can be ensured only by effectively shutting off and opening the individual strands 2.1 to 2.4 for each individual area.

In the embodiment shown in Fig. 4, the individual vertical riser strands can be flushed in the same way. In each case, the right riser string 2.4 is flowed through and purged with each flush, which leads to the discharge point 32.

In the exemplary embodiment shown in FIG. 5, only the flushing valve 30 has to be opened in order to flush the looped-through floor strands as a whole and thus to exchange the cold water contained in the cold water system. The same applies to the embodiment shown in Fig. 6.

Due to the design of branch 14 and orifice 16 shown schematically in FIG. 7, each rinse of a single strand leads at least to a rinsing flow within the ring lines 10 of the associated strand 2. In addition, the design of branch 14, mouth 16 and throttle 50 takes place to each individual ring line 10 of the system preferably in such a way that a targeted removal at a removal point 12 which is arranged on a downstream in the direction of the ring line to a scavenging flow upstream of the upstream ring lines 10. Will, for example, in the embodiment shown in Fig. 5 used in the upper floor at the last in the direction of flow ring line 10 a sampling point, this leads to a flow within the entire water system, since the individual strands 2.1 to 2.4 are looped through. The removal of water from a hand basin, rinsing a toilet, showers or bathing regularly leads to a flow and thus between each branch and each mouth of a single, said last ring line in the flow direction upstream ring line to a pressure difference, which causes a water exchange in the respective loop , The same results, for example, in the embodiment shown in Fig. 3 when operating a removal point 12 which is connected to the respective right loop line 10, for the two in the flow direction before mounted ring lines 10 of the strand 2.1.

In the same way behaves in principle, the third embodiment of the invention shown in Fig. 4. If this is, for example, a hotel in which only the upper floor is occupied, it can be achieved by temporarily occupying all rooms in the top floor flushing the respectively arranged under the rooms ring lines 10 of the underlying room.

In the embodiment shown in Fig. 7, the throttle is designed as a nozzle with fixed nozzle cross-sections and transitions. Alternatively, and for better adaptation of the flow resistance within a strand or in different juxtaposed or superimposed strands 2, it may be preferable to make the throttle adjustable. The adjustment of the throttle should preferably be done automatically. Such a controllable throttle should preferably be connected to the central control unit. With such controllable throttles, for example, a hydraulic balancing between individual ring lines 10 or individual strands 2 can be achieved.

Incidentally, it should be noted that the return line flush valve 44 shown schematically in the embodiments may also include the full-flow shut-off valves to minimize the assembly effort in the realization of the drinking or domestic water system. The formation of such a uniform fitting significantly reduces the assembly effort, since only at four points of the strand or the associated ring line must be connected to the valve.

The present invention further relates to a method for operating a drinking or service water system with at least one storey or riser pipe 2 and several in the extension direction of the strand 2 arranged one behind the other and each leading to at least one removal point 12 ring lines 10, which branch off from the strand and in the flow direction behind the strand lead into the strand. According to the invention, a pressure difference is generated at removal of drinking or service water connected to the strand extraction point 12 by a flow in the strand between the branch 14 and the mouth 16 upstream of the consumer 12 ring line (s) 10 of the strand , through which in the or the upstream ring line (s) 10 a purge flow is generated. The driving force for each flow through the drinking or service water system is preferably only the overpressure, which rests at the transfer point from the public drinking or service water supply network. In the method according to the invention, in particular, a pump is dispensed with for circulating the drinking or service water in the system.

LIST OF REFERENCE NUMBERS

2

Cold water line

4

Hot water line

6

Hot water circulation pipe

8th

wet

10

loop

12

sampling point

12a

Toilet

12b

shower

12c

bathtub

12d

hand basin

14

junction

16

muzzle

18a

Full flow shut-off valve

18b

Full flow shut-off valve

20a

shut-off valve

20b

shut-off valve

22

Transfer point

24

riser

26

connecting line

28

Valve

30

flush valve

32

delivery point

33

shut-off valve

35

riser

36

cross line

38

circulation line

40

pump

42

biological elimination unit

44

Ringleitungsspülarmatur

46

branch connection

48

Recirculation port

50

throttle

Claims (20)

Drinking or process water system with a transfer point (22) from a public drinking water supply network and at least one floor or riser (2) and several in the extension direction of the strand (2) arranged one behind the other and each leading to at least one withdrawal point (12) ring lines ( 10), which depart from the strand (2) and open in the flow direction of the strand (2) behind it in the strand (2),
marked by
at least one controllable valve (28, 30) which, when open, generates a purge flow in the string and connects the drinking or utility water system to a waste water discharge point (32) to the public sanitation network. Drinking or service water system with a transfer point (22) from a public drinking water supply network and at least one floor or riser pipe (2) and several in the extension direction of the strand arranged one behind the other and each leading to at least one removal point (12) ring lines (10), derive from the strand (2) and in the flow direction of the strand behind it in the strand (2) open, in particular according to claim 1, wherein the ring lines (10) and / or a branch (14) or an orifice (16) of the respective Ring line (10) on the strand (2) are formed such that upon removal of drinking or service water at a connected to the strand removal point (12) by a flow in the strand between the branch (14) and the mouth (16) of the in the flow direction of the consumer (12) upstream ring line (s) (10) of the strand, a pressure difference is generated, through which in the or the upstream ring line (s) (1 0) a purge flow is generated, and wherein a flow in the drinking or service water system is generated solely due to the difference between the pressure at the transfer point (22) and the delivery point (32) and the removal point (12). Drinking or process water system according to claim 1 or 2, characterized in that the controllable valve (28) is associated with a removal point (12) which is connected to the provided in the strand region ring line (10). Drinking or process water system according to one of claims 1 to 3, characterized in that the controllable valve (28) is provided at the strand end and the strand (2) with a connecting line (26) connects. Drinking or service water system according to one of the preceding claims, characterized in that a plurality of strands (2) are provided which are provided in their Stranggendbereich each with a controllable valve (28) and connected to the connecting line (26). Drinking or service water system according to claim 4 or 5, characterized in that the connecting line (26) in the flow direction behind the connection of the or all strands a controllable flushing valve (30) which leads to the transfer point (22) to the public sewage disposal network. Drinking or process water system according to one of the preceding claims, characterized in that the controllable valve (28) at the end of several looped strands (2) is provided. Drinking or service water system according to one of the preceding claims, characterized in that the or the controllable valves are shown time-controlled. Drinking or service water system according to one of the preceding claims, characterized in that the one or more controllable valves (28, 30) are controllable by a central control unit. Drinking or process water system according to one of the preceding claims, characterized by flow and / or temperature sensors whose measured values are processed in the central control unit for controlling the controllable valve or valves (28). Drinking or process water system according to one of the preceding claims, characterized in that the branch (14) and the mouth (16) of the ring line (10) are realized in a uniform Ringleitungsspülarmatur (44). Drinking or process water system according to one of the preceding claims, characterized in that the strand between the branch (14) and the mouth (16) of a single loop (10) has a length of less than 0.3 m. Drinking or service water system according to one of the preceding claims, characterized in that each ring line (10) in a on the strand in the manner of a throttle (50) formed Ringleitungsspülarmatur (44) opens. Drinking or service water system according to claim 13, characterized in that the throttle (50) is designed as a nozzle. Drinking or service water system according to claim 13 or 14, characterized in that the throttle is designed to be adjustable. Drinking or process water system according to one of the preceding claims, characterized in that between the branch (14) and the mouth (16) of the ring line (10) on the strand (2) and the associated ring line (10) each dead space-free full-flow shut-off valves (18a , 18b) are provided. Drinking or process water system according to claim 16, characterized in that the full-flow shut-off valves (18a, 18b) are ball valves. Drinking or process water system according to claim 16 or 17, characterized in that the full-flow shut-off valves (18a, 18b) from the branch (14) or the mouth (16) in the Ringleitungsspülarmatur (44) are integrated. Drinking or process water system according to one of the preceding claims, characterized by a circulation line (38) which is the end of the flow direction last strand (2) connects to the beginning of the first strand in the flow direction and comprises a water treatment unit (42) and a pump (40), so that a circulation system is formed. Method for operating a drinking or service water system with at least one floor or riser pipe (2) and several in the extension direction of the strand (2) arranged one behind the other and each to at least one removal point (12) leading ring lines (10) of the strand (2 ) and in the flow direction of the strand behind it open into the strand, characterized in that by opening a at the end of a strand (2) provided controllable valve (28) in the strand (2) a flow is generated through which between the branch ( 14) and the mouth (16) of each ring line (10) of the strand, a pressure difference is generated, through which in the associated ring lines (10) a purge flow is generated.

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