WO2013171050A1 - Method for operating a hot water supply system and a hot water supply system for implementation of the method - Google Patents

Abstract

According to a method for operating a hot water supply system (10a), fresh water is supplied to the hot water supply system (10a) by means of a cold water supply (17), the supplied fresh water is heated and the generated hot water is supplied to one or more consumers (21) by means of a hot water line (28), wherein the hot water is generated with a specified hot water volume (V) and held ready for use. A bacteria-related health risk is prevented in a simple manner in that hot water from the hot water volume (V) is replaced to a sufficient extent with fresh water in the hot water volume for prevention of harmful bacteria concentrations, particularly of legionella.

Description

 Method for operating a hot water supply system and hot water supply system for carrying out the method

TECHNICAL FIELD The present invention relates to the field of hot water supply. It relates to a method for operating a hot water supply system according to the preamble of claim 1.

It further relates to a hot water supply system for carrying out the method. STATE OF THE ART

It has been known for decades that hot water supply systems can, under certain conditions, develop bacteria that can cause damage to the health of consumers of hot water. These harmful bacteria include the so-called legionella. The most well-known type of Legionella is the Legionella pneumophila, which also causes most Legionella diseases. Propagation of these Legionella takes place at temperatures between about 25 ° C and 45 ° C with the optimum temperature for growth being about 36 ° C. At temperatures above 55 ° C, the Legionella begin to die. This process is faster, the higher the temperature is above 55 ° C. In contrast, at a temperature of drinking water to about 1 5 ° C (cold water) no significant increase of Legionella takes place. The number of Legionella, which are practically always present in water, is below a value that is significant for humans under these cold water conditions. Legionella is transmitted mainly via the lungs during breathing of fine legionella-contaminated water droplets, such as those that occur during showering. Transmission of Legionella via drinking water or washing with water, on the other hand, is unlikely.

Various proposals have been made in the past for reducing, eliminating or eliminating the health hazards of bacteria, especially Legionella, in hot water supply systems. This includes, for example, the thermal, chemical or radiation-based killing of bacteria.

The document DE 1 99 32 436 A1 discloses a domestic hot water system with at least one drinking water heater / storage tank for domestic hot water, a Trinkkaltwasserleitung for the supply of cold drinking water in the container, a conduit system which forms a closed circulation circuit with the container, consisting of a container on the connected output line with at least one tap for the removal of domestic hot water and connected to the output line and the container Engangsleitung for returning the not removed domestic hot water in the container, at least one pumping device for the circulation of the domestic hot water in the circulation circuit and at least one connected to a heating circuit heat exchanger Heating the cold drinking water supplied by the drinking cold water line and maintaining the drinking hot water temperature in the circulation circuit.

In an arrangement known as Legionellenschaltung the Engangsleitung has at least one branch with at least one branch line, wherein the Engangsleitung is connected in the central region of the container just above the heat exchanger, the drinking water line below the Engangsleitung in the lower is rich connected to the container, the branch line is connected below the drinking water line at the bottom of the container and a first balancing valve in the Bngangsleitung in the flow direction after the branch ung angeord net and a second balancing valve in the branch line is arranged. As a result, the circulation temperature in the entire piping network is maintained at a level such that the hot water is largely free of microorganisms, in particular Legionella, and that during a relatively short period of time an increased circulating temperature in a largely shortened branch of the container of microorganisms thermally disinfected.

The document EP 1 094 279 A2 describes a storage tank system with a hot water reservoir, a heater for heating water, a cold water supply, which is connected to the storage tank system and supplies it with cold tap water, a tapping point connected to the reservoir for the discharge of hot water from the reservoir. Means are provided in the reservoir for moving water from a lower portion of the reservoir to another portion of the reservoir.

The document DE 36 29 532 A1 discloses a device with a water heater, a connected to this tap fitting and connected to this shower line with shower head, a drain valve is provided with which the shower is drainable.

From the document DE 38 32 837 A1 a line arrangement for hot water supply is known, in which a hot water pressure line from a water heater to a tap fitting and a discharge line from the tap fitting lead to a tapping point and to the tap fitting a cold water line is connected. At the Zapfar matur a purge valve is provided, which is located on the one hand to the cold water line and on the other hand connected to the hot water pressure line and / or to the discharge line.

The document EP 0 296 630 A1 shows a hot water heater with a water-carrying storage tank with a cold water inlet in the lower tank area and a hot water outlet in the upper tank area and with a storage container angeord Neten heating element. In the lower tank area a cold water drain is provided.

Document WO 0240906 A1 describes a method of reducing bacterial growth in a water mixer comprising a cold water supply pipe, a hot water supply pipe and a mixing chamber. In this case, the mixer's mixing chamber and the consumer line are emptied of hot water or mixed water after consumption, with the mixer being supplied with additional cold water to lower the temperature in the mixer and in the consumer line, and then the cold water supplied to be discharged to the expert and the consumer.

The document FR 2 876 1 78 A1 discloses a device with bypass valves for the passage of cold and hot water from hot water and cold water supply lines to cold and hot water chambers. Bne mixing chamber mixes the cold and hot water. The mixed water is discharged through a solenoid valve which is opened by an electric pulse from a 6-volt lithium battery when corresponding information is detected by a detection unit and which is closed by another pulse when a certain state is reached , A similar solution is known from WO 01/61 224 A1. The document FR 2 891 1 69 A1 finally discloses an automatic shower purging system, which consists of a Mag netventil, which is installed in a bypass line between the hot water supply line under the line between the M ischereinheit and the shower head. For example, the valve is opened twice a day for 10 minutes by a central controller or timer to prevent the build-up of dormant water and to reduce or avoid the possibility of spreading Legionnaires' disease.

The problem with all known solutions is that they are either limited only to the hot water boiler, or only on the leads to the consumer (especially the shower). In addition, in these solutions usually additional fittings and lines are necessary, which are sometimes expensive and sometimes not suitable for retrofitting.

In fact, however, large bacterial populations not only occur in certain parts of a hot water system, but in all parts where the right conditions for growth prevail, in particular also growth temperatures.

PRESENTATION OF THE INVENTORY

It is therefore an object of the invention to provide a hot water system and a method for their operation with which in a simple way without chemicals, radiation or temperature increases the health endangerment of bacteria such as Legionella can be safely excluded.

These and other objects are achieved by the features of claims 1 and 9. The subject of the e ^r invention is a method for operating a hot water supply system, in which method a cold water inlet of the hot water supply system supplied fresh water, heats the supplied fresh water and the hot water produced is fed through a hot water pipe to one or more consumers, wherein the hot water with a predetermined hot water Volume generated and kept available for consumption. Major avoidance of harmful bacterial concentrations, in particular of Legionella, in the hot water volume is replaced to a sufficient extent hot water from the hot water volume of fresh water. According to one embodiment of the invention, taking into account the amount of hot water withdrawn by the consumers, the entire hot water volume is completely replaced by fresh water in a given period of time.

Bne other embodiment is characterized in that the removal of hot water from the hot water volume is monitored by the consumer, and that in addition hot water is replaced by fresh water when the consumption of hot water is insufficient to the entire hot water volume in the given period completely replaced by fresh water.

In particular, hot water is deliberately drained from the hot water volume for additional FJsetzen of hot water by fresh water. Another embodiment is characterized in that the hot water is drained from the hot water volume via a valve present at a consumer. Likewise, however, the hot water from the hot water volume can be drained via a specially designated valve.

In particular, the valve for draining the hot water is designed as a controllable valve, wherein the targeted draining of the hot water is controlled by a controller.

Still another embodiment of the method according to the invention is characterized in that the controller controls the valve according to the time-dependent hot water consumption.

The hot water supply system according to the invention for carrying out the method comprises first means for & warming and storing a hot water volume, a cold water inlet, which is in communication with the first means, and connection means, via which one or more hot water consumers can be connected to the first means or are connected. It is characterized in that a controllable valve for the controlled discharge of hot water from the hot water volume is connected to the first means, and a control is provided which controls the controllable valve.

According to one embodiment of the hot water supply system according to the E ^r invention, the controllable valve is assigned to a consumer.

The controllable valve can also be a separate outlet valve.

Another embodiment of the hot water supply system according to the invention is characterized in that second means for monitoring the hot water supply are provided. Consumption from the hot water volume are provided, and that the second M medium are connected to the controller.

In particular, the second means comprise a flow meter which is arranged between the cold water inlet and the first means.

Another embodiment is characterized in that the first means comprise a hot water circuit with a circulating pump.

In this case, the hot water circuit may have a heat exchanger, which is net angeord in a hot water tank.

But it is also conceivable that a hot water tank is part of the hot water cycle.

Bne another embodiment of the invention ^r e is characterized in that the first M edium include cooperating with a hot water tank hot water pipe.

The hot water pipe can be connected directly to an outlet of the hot water tank.

But it is also conceivable that the hot water pipe is coupled via a heat exchanger with the hot water tank.

KU RZE EXPLANATION OF THE FIGURES

The invention will be explained in more detail with reference to embodiments in conjunction with the drawings. Show it : a greatly simplified scheme of a hot water supply system according to an embodiment of the invention, with a hot water circuit, which is thermally coupled via a heat exchanger to a hot water tank (water heater principle); a greatly simplified scheme of a hot water supply system according to another embodiment of the invention, with a simple hot water line, which is thermally coupled via a heat exchanger to a hot water tank (water heater principle); a greatly simplified scheme of a hot water supply system according to another embodiment of the invention, with a hot water circuit in which a hot water tank is turned on (fresh water storage system); and a greatly simplified scheme of a hot water supply system according to yet another embodiment of the invention, with a simple hot water pipe into which a hot water tank is turned on (fresh water storage system).

WAY TO RUNNING THE INVENTORY

The present invention is based on the situation that it comes in drinking, service or fresh water area under appropriate conditions (low water consumption, water temperature between 25 -45 ° C) like a Legionella contamination in drinking hot water, which at the consumer Diseases can lead to death. In many industrialized countries (such as Switzerland or Germany), the water is periodically heated to over 60 ° C in order to prevent this danger, thereby killing the Legionella (see the Legionella circuit mentioned above).

However, this heating of the water needs a lot of energy and is not always successful (for example, in non-flowed lines or volumes, or if the connected shower heads are not flowed through, etc.).

In principle, two types of domestic hot water treatment systems can be distinguished:

One type of system has a lot of water content because the domestic hot water is stored in a domestic hot water tank.

The other type of system has relatively little water content, since the domestic hot water is heated in a water-heater process and the heat energy storage takes place in a closed circuit (fresh water Mod ul technology).

The new solution described below is basically suitable for both systems, but has many advantages in connection with the freshwater module technology.

Legionella have so far been mainly fought by raising the water temperature to> 60 ° C. Furthermore, in particular in connection with the associated standards, it is the viewpoint that water should / must always flow. Hot water pipes, which are not or rarely flowed through, should be avoided if possible. By contrast, the present invention is based on a solution which does not focus on thermal control of the bacteria by continuous or periodic heating of the fresh water, but on the "dilution" of the fresh water., Of course, barbing can also be combined with this dilution become.

E3In the dilution it is intended that the contents of a hot water network including a possibly contained therein storage volume (hereinafter also referred to as hot water volume V) in a period of about 8 hours (better 4 hours) is consumed and thus new, fresh water in the Net or volume refills (no stagnant water in the network or volume over a period> 8h or 4h).

In a fresh water storage system with a 5000 liter hot water tank and a net capacity of approx. 200 liters (Fig. 3, 4), approx. 5200 liters of water would have to be consumed or passed through every 4 to 8 hours.

In a fresh-water Mod ul technology using the instantaneous water heater principle (Fig. 1, 2), only the net capacity of approx. 200 liters must be consumed or passed through every 4 -8 hours.

In an ideal temperature range for Legionella (about 25 ° C-50 ° C), the number of Legionella doubles very much to a level that is harmful or fatal to humans.

However, a "dilution" (by a safe water consumption) every 4 -8 hours, as new research shows, the number of Legionella can never assume a concentration harmful to humans. With regard to the consumption situation, one can distinguish in particular between old and new buildings, residential buildings, hospitals, nursing homes, industrial and commercial buildings, sports facilities, hotels, etc., large and small buildings with one or more supply lines (spur lines) and / or with or without circulation line (Hot water circuit) over all or only a few taps. Some of these buildings (spur lines, tapping points) are regularly operated and the required dilution can be achieved automatically with professional water heater system, especially with the instantaneous water heater system.

Other objects have parts of the building that may not be needed periodically or for a long time, such as "cold beds" in holiday apartments, conversion into farm buildings, sports facilities during the holiday season, hotels in the mid-season, older existing properties, etc.

On the one hand to save energy and on the other hand to improve hygiene (flow through the taps as showers heads, etc.) should according to the inventive idea, where necessary and / or useful, with the forced (controlled) "dilution" of Legionella by draining as cold as possible Water from the hot water volume and simultaneous running of cold fresh water) are worked.

The following options are available individually or in combination with regard to the procedure:

• calculating the contents of the hot water system (hot water volume) and automatic, periodic draining at the correct, important, or all taps, until the water content is renewed and or the required dilution is achieved (controlled eg over time, or special measuring systems) ; Draining via the circulation line (the taps are, however, not flowed through, but this is easier and also corresponds to the state of the art in the "heat destruction");

The temporal or periodic discharge of fresh water on the hot water side as cold as possible can be controlled by means of fixed time intervals (eg opening the corresponding emptying points every 8 hours for 2 minutes) or automatically with adapted time intervals via temperature and / or volume flow detection (for example at a sports facility during showers never during the season and periodically during the holidays).

In this case, only individual strands can be "diluted" in an object, if the other strands experience enough "dilution" through the use.

The fact that the dilution can be done with cold water, this type of Legionellen- control requires less energy and the disadvantage of temperature in the Legionella "hot" lines (> 60 ° C, which may cool to room temperature and thus falls back into the critical growth range for legionella which leads to a large increase in legionella),

If the taps are included in the "dilution", there are plenty of systems on the market with automatic opening mechanisms that can be used (automatic water dispensers with cessation, etc. such as time ATMs in showers on campsites or on public toilets hold the hand, then the water flows and if you pull away the hand closes the tapping point, water valves, etc.).

• So the idea is that "dilution" dilutes the areas that are at risk and this is eliminated with the least possible energy and water consumption and thus the legionella hazard, and that - if necessary - also the whole Hot water volume is "diluted".

Fig. 1 shows a greatly simplified scheme of a hot water supply system according to an embodiment of the invention. The water supply system 1 0a of Fg. 1 comprises a closed hot water circuit 1 5, in which the hot water by means of a U mwälzpumpe 1 6 (or by gravity) circulates. The hot water circuit 1 5 is thermally coupled via a heat exchanger 1 4 to a hot water tank 1 2 1 (water heater principle), the water content of a heater 1 1 via a further heat exchanger 1 3 is heated.

The hot water circuit 1 5 can be removed 30 via a Ausspeicherleitung hot water and routed to a tap, which is a shower 21 in the example shown. Of course, further taps of this or another type can be connected to the hot water circuit 1 5. The hot water circuit 1 5 is supplied via a cold water connection line 1 8 of a cold water inlet 1 7 cold water, which replaces the withdrawn via the Ausspeicherleitung 30 hot water in the hot water circuit 1 5. At the same time leads from the cold water inlet 1 7 a cold water line 20 to tapping point 21 so that the desired water temperature can be achieved at the shower by a M ischung of hot water and cold water, which is set by a hot water valve 22 and a cold water valve 23.

In the in Fg. 1, the hot water volume V is substantially equal to the content of the hot water circuit 1 5. The above described controllable dilution of the hot water volume by cold fresh water is now achieved in this example, that the hot water circuit 1 5 a controllable outlet valve 29 is arranged , which are opened by a controller 24 via a control line 27 can, to selectively run hot water from the hot water cycle 1 5 or expire the hot water volume. The leaked over the outlet valve 29 hot water is replaced at the same time by cold water, which flows via the cold water connection line 1 8 in the hot water circuit 1 5. In this way, controlled by the controller 24, the hot water volume V can be completely exchanged in a predetermined period, with the exchanged water and the bacteria or Legionella contained therein are removed from the system. Through this procedure, the bacterial population in the hot water system can be kept controlled at a low and thus harmless level.

When replacing the hot water can generally be the heating of the water in the hot water tank 1 2 by the heater (eg by means of a charging pump, not shown) are interrupted so as not to unnecessarily lose energy due to the expiring hot water. Since this water exchange or the "dilution" takes place via the existing lines of the system, virtually no constructional changes to the system are necessary if the bacterial attack is to be combated in the manner proposed In the exemplary embodiment of FIG. 1, only the outlet valve would be in addition to the control 24 29 to provide that can be arranged at any point of the hot water circuit 1 5. In the simplest case, but also - as in Fig. 4 by the dashed control line 27 'indicated - the hot water valve 22 of the tap (shower 21) may be formed as a controllable valve and forcibly opened by the controller 24 for purposes of "dilution". In this case, the structural changes are limited to the construction of the controller 24. The controller 24 may control the dilution process, for example by means of a timer, which ensures that in a given period of time the water in the hot water system is replaced. However, such a simplified procedure would not take account of the fact that sufficient replacement can already be achieved by normal operation at the tap (shower 21). In order to avoid unnecessary water losses in this regard, according to FIGS. 1 be installed in the cold water connection line 1 8 a flow meter, which is the Control 24 indicates in which U mfang and in which periods hot water from the hot water circuit 1 5 and the hot water volume V has been exchanged for fresh water from the cold water inlet 1 7.

If the controller 24 on the basis of the data of the flow meter 1 9 determines that in a period of for example 4 or 8 h, the hot water volume V has been exchanged for cold fresh water only half, the controller 24, the outlet valve 29 open to the hot water - Dilute volume further.

The same procedure can also be applied in a hot water supply system 1 0 b, as shown in Fig. 2. In this case, a simple hot water line 28 is led to the tap instead of the hot water circuit, wherein in the hot water line 28, a heat exchanger 1 4 is inserted, which in turn is in the hot water tank 1 2. The hot water volume V is in this case the volume of the hot water pipe 28 from the input to the hot water tank 1 2 to the outlet valve 29. En substantially larger hot water volume V must - as already mentioned above - replaced or diluted if the contents of the hot water tank 1 2 part of the hot water circuit 1 5 is inserted (hot water supply system 1 0c in Fg. 3) or in the hot water line 28 (hot water supply system 1 0d in Fg. 4). In these two cases, not only individual lines are affected by the exchange or dilution, but the content of the hot water tank 1 2 itself, which leads to higher water losses in the forced dilution.

LIST OF REFERENCES 1 0a-d hot water supply system

1 1 heater

1 2 DHW cylinder 1 3, 1 4 heat exchanger

1 5 hot water circuit 1 6 Circulation pump

 1 7 cold water inlet

 1 8 cold water connection pipe

1 9 flow meter

 20 cold water pipe

 21 shower

 22 hot water valve

 23 cold water valve

 24 control

 25 hot water supply

 26 hot water return

27.27 'control line

 28 hot water pipe

 29 outlet valve

 30 discharge line

Claims

Patent claims

1. Method for operating a hot water supply system (1 0a-cT), in which method fresh water is supplied to the hot water supply system (1 0a-d) via a cold water inlet (1 7), the fresh water supplied is heated and the hot water produced is supplied via a hot water pipe (28). or several consumers (21), the hot water being generated with a predetermined hot water volume (V) and kept ready for consumption, characterized in that in order to avoid harmful bacteria concentrations, in particular legionella, in the hot water volume (V ) a sufficient amount of hot water from the hot water volume is replaced by fresh water.

2. The method according to claim 1, characterized in that, taking into account the amount of hot water withdrawn by the consumers (21), the entire hot water volume (V) is completely replaced by fresh water within a predetermined period of time.

3. The method according to claim 2, characterized in that the removal of hot water from the hot water volume (V) by the consumer (21) is monitored, and that additional hot water is replaced by fresh water if the consumption of hot water is not sufficient to completely replace the entire hot water volume (V) with fresh water within the specified period of time.

Method according to claim 3, characterized in that in order to additionally replace hot water with fresh water, hot water is specifically drained from the hot water volume (V).

Method according to claim 4, characterized in that the hot water is drained from the hot water volume (V) via a valve (22) present in a consumer (21).

Method according to claim 4, characterized in that the hot water is drained from the hot water volume (V) via a specially designed valve (29).

Method according to claim 5 or 6, characterized in that the valve (22, 29) for draining the hot water is designed as a controllable valve, and that the targeted draining of the hot water is controlled by a controller (24).

Method according to claim 7, characterized in that the controller (24) controls the valve (22, 29) in accordance with the time-dependent hot water consumption.

Hot water supply system (10a-d) for carrying out the method, comprising first means (12, 14, 15, 28) for heating and storing a hot water volume (V), a cold water inlet (17), which is connected to the first means (12, 14 , 15, 28) is connected, as well as connection means (30), via which one or more hot water consumers (21) can be connected or connected to the first means (12, 14, 15, 28), characterized in that the first th means (12, 14, 15, 28) a controllable valve (22, 29) for the controlled draining of hot water from the hot water volume (v) is connected, and that a control (24) is provided which controls the controllable valve ( 22, 29) controls.

10. Hot water supply system according to claim 9, characterized in that the controllable valve (22) is assigned to a consumer (21).

11. Hot water supply system according to claim 9, characterized in that the controllable valve is a separate outlet valve (29).

12. Hot water supply system according to one of claims 9-11, characterized in that second means (19) are provided for monitoring the hot water consumption from the hot water volume (V), and that the second means (19) are connected to the control (24). are.

13. Hot water supply system according to claim 12, characterized in that the second means comprise a flow meter (19) which is arranged between the cold water inlet (17) and the first means (12, 14, 15, 28).

14. Hot water supply system according to one of claims 9-13, characterized in that the first means (12, 14, 15, 28) comprise a hot water circuit (15) with a circulation pump (16).

15. Hot water supply system according to claim 14, characterized in that the hot water circuit (15) has a heat exchanger (14) which is arranged in a hot water tank (12).

16. Hot water supply system according to claim 14, characterized in that a hot water tank (12) is part of the hot water circuit (15).

Hot water supply system according to one of claims 9-13, characterized in that the first means (12, 14, 15, 28) comprise a hot water pipe (28) which interacts with a hot water storage tank (12).

Hot water supply system according to claim 17, characterized in that the hot water pipe (28) is connected directly to an output of the hot water tank (12).

Hot water supply system according to claim 17, characterized in that the hot water pipe (28) is coupled to the hot water tank (12) via a heat exchanger (14).