DE9214861U1 - System for heating domestic water and killing legionella in this domestic water - Google Patents

Description

30 Oct. 1992 HSP 2100a/92

Description:

The invention relates to a system for heating domestic water and for killing Legionella in this domestic water with a cold water supply line to a heat exchanger for preheating the cold water supplied and for cooling the domestic water supplied via a domestic water outlet line and heated to disinfection temperature from a storage domestic water heater, whereby the heat exchanger is equipped with a

Circulation water circuit, which consists of a domestic water distribution line to taps, a circulation line, a circulation pump and a
Domestic water collection line is formed.

A known system of this type according to GB-2 099 559 A, Fig. 3, has the disadvantage that only a portion of the water heated to disinfection temperature from the storage domestic water heater reaches the heat exchanger via the domestic water outlet pipe, while another portion in a heated state is directly on the hot water side via a backflow preventer and a

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Three-way mixing valve in the

Circulation water circuit. At the disinfection temperatures of £60 ⁰ C disclosed here, the inevitable limescale deposits can lead to malfunctions in the three-way mixing valve and/or the backflow preventer and thus lead to scalding at the taps when hot domestic water heated to disinfection temperature is introduced into the circulation water circuit. Behind the circulation pump there is a branch, one branch of which leads to the three-way mixing valve and the other branch to the domestic water storage heater. According to the disclosure content of this publication, the amount of water that returns from the circulation pump to the storage domestic water heater via the second branch mentioned is only designed to be large enough so that the enthalpy losses related to this amount of water within the circulation water circuit can be compensated for by the enthalpy transported in the branch of the domestic water outlet pipe that continues to the three-way mixing valve. In this respect, this system can only be used to a very limited extent to kill legionella in domestic water, especially in the circulation water circuit.

Furthermore, extensive investigations have since shown that in the circulating water circuit

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Legionella cannot be avoided even when disinfected water is fed into the service water outlet pipe. According to the results of these investigations, the reason for the formation of legionella is essentially that legionella was already present in the system when the system was first filled with filling water.

They are introduced into the circulating water circuit, from which they cannot be removed using conventional thermal disinfection methods.

This applies even if, according to DE-PS 38 40 516, a self-contained disinfection circuit with buffer is formed according to Fig. 4 and 4a, which is hydromechanically and thermally separated from the circulating water circuit. The thermal disinfection described in DE-PS 38 40 516 in column 1 in the third paragraph by gradually adjusting the temperature in the

In practice, heating the domestic water distribution pipe to 70 ^° C in large facilities such as hospitals, retirement homes, hotels and barracks cannot be carried out with sufficient safety using conventional means and procedures in the event of a breakdown, and this is also not guaranteed in single-family and two-family houses.

Based on this state of the art, the invention is based on the object of creating a system of the type mentioned at the beginning, with which in an energy-related operation

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and inexpensive production, the legionella that have entered the circulating water circuit can be either significantly reduced or killed in both small and large systems.

This object is achieved in accordance with the invention in connection with the generic term mentioned at the outset in that the
Storage domestic water heater is connected to the domestic water collecting line, a backflow preventer, a water flow limiter and the heat exchanger for preheating the circulation water and an access line with the circulation water circuit to form a complete circuit. This is of course done in such a way that/3 the disinfection temperature in the
Storage domestic water heater is constantly and permanently maintained, whereby this high temperature range and the associated limescale deposits are limited to a very localized area of the entire system. Furthermore, despite the connection of the storage domestic water heater with the circulating water circuit to form an overall circuit, energy-efficient operation is maintained. The legionella bacteria present in the circulating water circuit due to the initial filling or a breakdown are permanently introduced into the storage domestic water heater and killed there. This reduces the

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Concentration of legionella in the circulation water circuit is significant. If the entire system is not used for a long period of time, the entire circulation water can be passed through the storage domestic water heater several times, heated to disinfection temperature again and in this way the legionella can be completely killed.

The water flow limiter in conjunction with the backflow preventer ensures that only as much circulation water as is needed to

Storage domestic water heater is promoted because a safe and constant disinfection temperature is always maintained. The backflow preventer in the entire circuit ensures a clear flow direction. Since, according to relevant publications, the growth of legionella bacteria requires longer periods of time and can only double in two to three hours, the legionella from both the circulating water circuit and the cold water network are significantly reduced by disinfection and completely killed off if there is a longer period of inactivity. The "heat swing" between the storage domestic water heater and the heat exchanger ensures a
energy industry operation.

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Since, in contrast to the state of the art according to GB 2 099 559 A, the
Circulation water circuit also via the heat exchanger to preheat the circulation water with the

This system is characterized by particularly energy-efficient operation, as it is connected to the storage domestic water heater, both hydromechanically and thermally in terms of heat transfer. Furthermore, limescale deposits are limited to the hot water side, i.e. to the storage domestic water heater and the domestic water outlet pipe up to the heat exchanger, with all other fittings in the form of the backflow preventer and the
Water flow limiter and the control valves to be described below are basically arranged on the cold water or tap temperature side, either in the domestic water collecting line or in the access line to the storage domestic water heater, in which the water has a temperature well below 60 ⁰ C, e.g. 40 ⁰ C. Finally, with this system, by including the

Circulation water circuit both during tapping and during idle time with the
Storage domestic water heater to a complete circuit also ensures a significant reduction or killing of legionella, since the water of the circulation water circuit is permanently fed to the storage domestic water heater

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pumped around and thus always heated to the disinfection temperature again, if and as long as it does not previously leave the overall circuit via the taps.

As a result, the circulation pump in relation to the circulation water circuit also fulfils the function of a charging pump to achieve largely germ-free domestic water in the storage domestic water heater and the connected pipes of the overall circuit.

According to an advantageous development of the invention, the entire water quantity of the circulation water circuit on the suction side of the circulation pump can be pumped via a circulation water distribution valve with three paths in the domestic water collection line to the storage domestic water heater, of which the first path is connected to the circulation pump, the second path to the backflow preventer and the third path via a first bypass line to the domestic water distribution line to the taps.
Circulation water distribution valve can be regulated either depending on the disinfection temperature in the storage domestic water heater by a temperature sensor arranged there or depending on the time via a timer in such a way that/3 the total circulation water quantity or only a portion of this water from the circulation water circuit to the heat exchanger

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and the rest

Total circulation water or partial quantity via the first bypass line into the

The water can be pumped through the service water distribution line to the taps.

Circulation water distribution valve is ensured when drawing from the circulation water circuit, since/3 via the
Only the absolutely necessary amount of disinfected water at a selectable, constant temperature can flow into the circulating water circuit via the service water distribution line.

According to an advantageous embodiment, a two-way cold water quantity control valve is arranged in a second bypass line in the flow direction upstream of the heat exchanger between the cold water supply line and the access line to the storage domestic water heater.

After another advantageous

In this embodiment, a cold water quantity control valve with three paths is arranged in the cold water supply line to the heat exchanger, the first path of which is connected to the cold water supply line, the second path of which is connected to the heat exchanger via an intermediate line and the third path of which is connected to the access line to the storage domestic water heater via a third bypass line. The cold water quantity control valves are advantageously connected to a temperature sensor in the

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The service water distribution line to the taps is adjustable. This ensures that when water is drawn from the taps, service water of a selectable, constant temperature can flow into the circulation water circuit via the service water distribution line without affecting the water temperature in the
Storage domestic water heater having to be increased.

According to a particularly advantageous development of the invention, the heat exchanger consists of a total of three compactly combined partial heat exchangers, of which the first is connected at its inlet to the domestic water outlet line and at its outlet to the domestic water distribution line to the taps, the second at its inlet to the cold water supply line and at its outlet to the access line to the storage domestic water heater, and the third partial heat exchanger is connected at its inlet to the domestic water collection line and at its outlet to the access line to the storage domestic water heater. This design significantly simplifies the structure of the overall circuit, whereby control valves can be dispensed with.

According to a first design alternative, the domestic water collection line is connected in the flow direction upstream of the third partial heat exchanger via a fourth bypass line to the access line to the

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Storage domestic water heater, in which a circulation water quantity control valve with two ways is arranged.

According to a second design alternative, a

Circulation water quantity control valve with three ways, the first way of which is connected to the water quantity limiter, the second way to the inlet and the third way to the outlet of the third partial heat transfer and together with this outlet to the access line to the storage domestic water heater. The circulation water quantity control valve and the cold water quantity control valve can be used to select and control the water outlet temperature from the heat exchanger to the domestic water distribution line. The two control valves are each controlled by a temperature sensor in the domestic water distribution line.

According to an advantageous development of the invention, the domestic water heater of the storage domestic water heater is formed from a heating medium circuit with a heating medium pump, which can be switched together with the circulation pump by a temperature sensor in the storage domestic water heater.

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According to a particularly advantageous development of the invention, several storage domestic water heaters with the same or different storage volumes are connected in series. Such a system is particularly suitable for larger building units with a correspondingly large storage volume, whereby the technical effort is significantly reduced compared to other proposals.

In every system according to the invention, the storage volume of the storage domestic water heater is matched to the maximum inflow of cold water and to the delivery capacity of the circulation pump in such a way that the domestic water can only be conveyed from the storage domestic water heater via the domestic water outlet line to the heat exchanger in a disinfected state. This means that freshly disinfected domestic water is constantly fed directly to the taps, even when there is no tapping, while at the same time the domestic water previously located at this point is fed by the circulation pump into the

Storage domestic water heater is pumped. Since this process takes place continuously when there is no tapping and when there is tapping, freshly disinfected domestic water is always available when it is drawn from the taps, which means that the formation of Legionella can be reduced to zero. It is important that, according to recent studies, with a germ load of approx.

10 CFU/ml (colony forming units per

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Milliliters) the time required to kill legionella of serogroups 4 and 6 at a service water temperature of 7 0 ⁰ C is approx. 4 min - 6 min, at 66 ⁰ C approx. 45 min and at 60 ⁰ C 60 min - 120 min. For the systems according to the invention this means that at a disinfection temperature of 70 ⁰ C in the storage domestic water heater with maximum withdrawal at the taps and thus with maximum inflow of cold water, the respective storage volume and the delivery rate of the circulation pump must be coordinated in such a way that the cold water entering the storage domestic water heater in a preheated state must require at least 6 minutes to flow through the storage domestic water heater/3, without having the possibility of being able to "shoot through" from the inlet to the outlet in the storage domestic water heater in a shorter time. This can be done with appropriately coordinated storage volumes, for example with known baffles or similar known devices within the storage container.

Several embodiments of the invention are shown in the drawings.

Fig. 1 shows a first embodiment of the invention with a second bypass line between the cold water supply line and the access line to the

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Storage domestic water heater and a two-way cold water quantity control valve located therein,

Fig. 2 a second embodiment with a circulation water distribution valve with three ways and a first bypass line in the

Circulation water circuit and a three-way cold water quantity control valve in the cold water supply line,

Fig. 3 the embodiment of Fig. 1 with a compact heat exchanger consisting of three partial heat exchangers without the cold water control valve,

Fig. 4 the embodiment of Fig.3 with a

Circulation water quantity control valve and a cold water quantity control valve with two ways each,

Fig. 5 the embodiment of Fig.4, but each with a

Circulation water quantity control valve and a cold water quantity control valve with three ways each and

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Fig. 6 the embodiment of Fig.4, but with the

Circulation water distribution valve from Fig.2 in the circulation water circuit.

Each of the systems described below has at least one

Storage domestic water heater 1 and a circulation water circuit 2. The storage domestic water heater 1, of which one may be sufficient for single and two-family houses and several with the same or different storage volumes may be connected in series in larger building units, essentially consists of a storage tank la and a heating medium circuit 3 with a heating medium pump 4. In the embodiments of Figs. 1, 2, 3 and 5, the heating medium circuit 3 heats the domestic water in the interior of the storage tank la via a heating coil 5. In the embodiments of Figs. 4 and 6, the

Heating medium circuit 3 via an outer jacket 6 the storage tank la. Which of these heating methods of the storage tank la is preferred depends essentially on the heating medium, its primary energy and the storage concept.

The domestic water heated to disinfection temperature in the storage domestic water heater 1 goes via the domestic water outlet line 7 to the heat exchanger 8, which then transports it via the domestic water distribution line 9 to the

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The water not taken from the taps 10 is pumped by the circulation pump 12 via the circulation line 11 to the
Domestic water collection line 13 through the backflow preventer 14, the
Water flow limiter 15 pumps the water via the cold water supply line 16 to the heat exchanger 8, which it leaves via the access line 17 to the storage domestic water heater 1.

According to Fig.l and 2, the heat exchanger 8 is
The domestic water outlet line 7 and the cold water supply line 16 are subjected to countercurrent flow.

As can be seen from the above description, the

Storage domestic water heater 1 is connected to the circulation water circuit 2 via the domestic water outlet line 7, the heat exchanger 8 and the inlet line 17 to form an overall circuit 1, 2.

According to Fig.l, to regulate the

Cold water quantity in a second bypass line 18 in the flow direction upstream of the heat exchanger 8 between the cold water supply line 16 and the access line 17 to the
A cold water quantity control valve 19 with two ways 19a and 19b is arranged in the storage domestic water heater 1. This
Cold water quantity control valve 19 is controlled by a

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the service water distribution line 9.

According to the embodiment of Fig. 2, the entire amount of water of the circulation water circuit 2 present on the suction side 12a of the circulation pump 12 can be pumped via a circulation water distribution valve 21 with three paths 21a, 21b and 21c in the domestic water collection line 13 to the storage domestic water heater 1, whereby the first path 21a of the

Circulation water distribution valve 21 is connected to the circulation pump 12, the second path 21b to the backflow preventer 14 and the third path 21c is connected via a first bypass line 22 to the service water distribution line 9 to the taps 10.

As can also be seen from Fig. 2, the circulation water distribution valve 21 is either controlled depending on the disinfection temperature in the

Storage domestic water heater 1 from a temperature sensor 2 3 arranged there or from a temperature sensor 36 in the
Domestic water distribution line 9 or, depending on the time, via a timer 24, in such a way that the total circulation water quantity or only a partial quantity of this water from the circulation water circuit 2 reaches the domestic water storage heater 1 and the

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remaining total circulation water or partial quantity
via the first bypass line 22 into the
Domestic water distribution line 9 to the
Taps 10 are pumped.

In addition, in Fig.2 in the

Cold water supply line 16 to the heat exchanger 8 a cold water quantity control valve 25 with three
Ways 25a, 25b and 25c arranged, the first path 25a with the cold water supply line 16, the
second path 25b via an intermediate line 26 with the heat exchanger 8 and its third path 25c via a third bypass line 27 with the
Access line 17 to

Storage domestic hot water heater 1 is connected.
This cold water quantity control valve 25 is also controlled by the temperature sensor 20 in the
Domestic water distribution line 9 to the
Taps 10 regulated.

In all of the following
Figures are corresponding parts of Fig.l
and 2 are designated with the same reference numbers. In all figures, the arrows in the lines indicate the flow direction of the
Domestic water or circulating water.

According to the embodiment of Fig. 3, the heat exchanger 8 consists of a total of three compactly combined partial heat exchangers 8a, 8b
and 8c, of which the first 8a is connected at its inlet to the domestic water outlet pipe 7 and
its outcome with the

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Domestic water distribution line 9 to the taps 10, the second 8b at its inlet with the cold water supply line 16 and at its outlet via a connecting line 2 8 with the access line 17 to the

Storage domestic water heater 1 and the third partial transformer 8c are connected with its input to the domestic water collecting line 13 and with its output also to the access line 17 to the storage domestic water heater 1. With regard to the

The cold water supply line leading to the second partial heat exchanger 8b is connected in parallel flow in the domestic water outlet line 7 of the first partial heat exchanger 8a, and the domestic water collecting line 13 leading to the third partial heat exchanger 8c is connected in counter flow. The direct current connection of the cold water supply line limits the temperature on the domestic water outlet side to the average temperature between hot water and cold water. This means that in individual systems, the arrangement of control valves can be dispensed with or their function can be made easier.

According to Fig. 3 and 4, the

Circulation pump 12 and the heating medium pump 4 together from the temperature sensor 2 3 in the storage tank la of the
Storage domestic water heater 1 switched on.

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In addition, Fig. 4 shows the

Domestic water collection line 13 is connected in the flow direction upstream of the third partial heat exchanger 8c via a fourth bypass line 29 to the access line to the storage domestic water heater 1, in which 29 a

Circulation water quantity control valve 30 with two ways 30a and 30b is arranged. This circulation water quantity control valve 30 is controlled by a temperature sensor 31, which, like the temperature sensor 20, is in the
Domestic water distribution line 9 is arranged to the taps 10.

In a fifth bypass line 34 between the cold water supply line and the connecting line 28, a
Cold water quantity control valve 35 arranged with two ways 35a, 35b.

The design of the system according to Fig. 5 differs from that according to Fig. 4, apart from the different design of the storage domestic water heater 1, essentially in that the cold water quantity control valve 35, which only has two ways, and the circulation water quantity control valve 30, which also only has two ways, have been replaced by control valves with three ways. For this purpose, according to Fig. 5, a circulation water quantity control valve 32 with three ways is installed in the domestic water collecting line 13 in the flow direction upstream of the third partial heat exchanger 8c.

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Arranged paths 32a, 32b and 32c, the first path 32a of which is connected to the water flow limiter 15, the second path 32b of which is connected to the inlet and the third path 32c of which is connected to the outlet of the third partial heat exchanger 8c and together with this outlet to the access line 17 to the storage domestic water heater 1.

Furthermore, in the embodiment of Fig. 5, a cold water quantity control valve 33 with three paths 33a, 33b and 33c is arranged in the cold water supply line 16, the first path 33a of which is connected to the cold water supply line 16, the second path 33b of which is connected to the inlet to the second partial heat exchanger 8b and the third path 33c of which is connected to the outlet from the second partial heat exchanger 8b and together with this outlet is connected to the access line 17 to the storage domestic water heater 1. This cold water quantity control valve 33 is also controlled by the temperature sensor 20 and the circulation water control valve 32 by the temperature sensor 31 in the
Domestic water distribution line 9 regulated.

In the embodiments of Fig. 4 and 6, the cold water supply line 16 is in the flow direction upstream of the second partial heat exchanger 8b with the

Connecting line 28 to the access line 17 to the storage domestic water heater 1 via a fifth bypass line 34, in which a cold water quantity control valve 35 with two ways 35a

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and 35b.

The embodiment of Fig. 6 differs from that of Fig. 4 in that the circulation water distribution valve 21 is arranged in the domestic water collection line 13 according to the embodiment of Fig. 2. In this respect, reference is made to the relevant statements on Fig. 2.

All of the above embodiments are suitable not only for relatively small systems in single or two-family houses, but also for large building units. The cold water enters the heat exchanger 8 via the cold water supply line 16, in which it is preheated by the hot domestic water flowing in simultaneously in parallel or countercurrent via the domestic water outlet line 7, before it reaches the storage domestic water heater 1 via the line 17. This cold water from

For example, 10 ⁰ C has only a small number of Legionella bacteria, which
Storage domestic water heater 1 can be completely killed. In this respect, the legionella bacteria in the cold water do not pose a significant problem.

However, the formation of legionella in the

Circulation water circuit 2 after an initial filling or a breakdown. Since the water from the service water outlet line 7 in

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In these cases, if the water supply has not only been disinfected before entry, the legionella bacteria find excellent thermal growth conditions in the circulating water circuit 2, which allows them to multiply explosively. The legionella bacteria can then, for example, escape from a shower head via the taps 10, be inhaled by the user with the water vapor, and thus develop their life-threatening effects.

The invention counteracts the growth of legionella because the circulation water circuit 2 is now constantly connected to the storage domestic water heater 1 to form a complete circuit 1, 2, especially when there is no water being drawn. As a result, the water in the storage domestic water heater is permanently circulated by the circulation pump 12, which also acts as a circulation pump for the entire circuit.

Circulation water circuit 2 for renewed disinfection in the

Storage domestic water heater 1 is pumped, whereby the legionella in the circulating water circuit 2 is significantly reduced and can even be completely killed during longer breaks in tapping.

The above-described embodiments can be used in single- and two-family houses as well as in larger building units. In the latter case, it is advantageous to install several storage domestic water heaters 1 with the same or different storage volumes in series.

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connected in series. Here too, the storage volume of the storage tank la of the storage domestic water heater 1 is always adjusted to the maximum withdrawal quantity and thus to the maximum inflow quantity of cold water as well as to the delivery capacity of the circulation pump 12 in such a way that the domestic water at the respective disinfection temperature must pass through the storage tank(s) la in a period of time corresponding to this disinfection temperature before it reaches the heat exchanger 8 from the storage domestic water heater 1 via the domestic water outlet line 7 in a safely disinfected state. Since lime deposits are unavoidable at disinfection temperatures above 60 ⁰ C, these are limited to the hot water side, i.e. to the storage domestic water heater 1 and to a partial area of the heat exchanger 8. All of the above-described

Control valves 14, 15, 19, 21, 25, 30, 32, 33 and 35 as well as the circulation pump 12 are arranged on the tap side or cold water side which is considerably below 60 ⁰ C. In contrast, the service water outlet line 7, in which hot service water is conveyed at disinfection temperature to the heat exchanger 8, as well as the service water distribution line 9 remain basically free of the aforementioned control devices, whereby malfunctions of the above-described control valves due to limescale precipitation are excluded.

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As the embodiment of Fig. 3 shows, when using a compact heat exchanger 8 consisting of a total of three partial heat exchangers 8a, 8b, 8c, no control valve is required.

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List of reference symbols:

Storage domestic water heater 1

Memory la

Circulation water circuit 2

Total circuit 1,

Heating medium circuit 3

Heating medium pump 4

Heating coil 5

External jacket water heater 6

Domestic water outlet line 7

Heat exchanger 8

Partial heat exchanger 8a, 8b

8c

Domestic water distribution line 9

Tap points circulation line

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Circulation pump 12

Suction side of the circulation pump 12 12a

Domestic water collection line 13

Backflow preventer 14

Water flow limiter 15

Cold water supply 16

Access line 17

Bypass line

Cold water quantity control valve

Valve paths 19 Temperature sensor circulation water distribution valve Valve paths 21

Timer 24

Ways of the valve 25 25a, 25b,

25c

18,
27,
34 22,
29 19, 25, 33, 35 19a, 19b 20, 23, 31, 36 21 21a, 21b, 21c

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Intermediate line 2 6

Connecting line 28

Circulation water quantity control valve 30, 32

Ways of the valve 30 30a, 30b

Ways of the valve 32 32a, 32b,

32c

Ways of the valve 35 35a, 35b

Claims (15)

30 Oct. 1992 HSP 2100a/92 Protection claims: 1. System for heating domestic water and for killing legionella in this domestic water with a cold water supply line to a heat exchanger for preheating the supplied cold water and for cooling the domestic water supplied via a domestic water outlet line and heated to disinfection temperature from a storage domestic water heater, whereby the heat exchanger is connected to a Circulation water circuit, which consists of a domestic water distribution line to taps, a circulation line, a circulation pump and a
Domestic water manifold is formed, characterized in that/3 the storage domestic water heater (1) is connected to the circulation water circuit (2) to form an overall circuit (1, 2) via the domestic water manifold (13), a backflow preventer (14), a water quantity limiter (15) and via the heat exchanger (8) also for preheating the circulation water and an access line (17). 30 Oct. 1992 HSP 2100a/92 2. System according to claim 1, characterized in that the entire amount of water present on the suction side (12a) of the circulation pump (12) of the Circulation water circuit (2) can be pumped via a circulation water distribution valve (21) with three paths (21a, 21b, 21c) in the domestic water collection line (13) to the storage domestic water heater (1), of which the first path (21a) is connected to the circulation pump (12), the second path (21b) to the backflow preventer (14) and the third path (21c) is connected via a first bypass line (22) to the domestic water distribution line (9) to the taps (10). (Fig.2 and 6) 3. System according to claim 2, characterized in that the circulation water distribution valve (21) can be regulated either as a function of the disinfection temperature in the storage domestic water heater (1) by a temperature sensor (23) arranged there or as a function of time via a timer (24) in such a way that the total circulation water quantity or only a partial quantity of this water is released from the circulation water circuit (2) to the heat exchanger (8) and the remaining total circulation water or partial quantity can be conveyed via the first bypass line (22) into the domestic water distribution line (9) to the taps (10). (Fig. 2 and 6) 30 Oct. 1992 HSP 2100a/92 4. Plant according to one of claims 1 to 3, characterized in that in a second bypass line (18) in the flow direction upstream of the heat exchanger (8) between the cold water supply line (16) and the access line (17) to the
A cold water quantity control valve (19) with two ways (19a and 19b) is arranged in the storage domestic water heater (1). (Fig.l) 5. System according to one of claims 1 to 3, characterized in that in the cold water supply line (16) to the heat exchanger (8) a Cold water quantity control valve (25) with three paths (25a, 25b, 25c) is arranged, the first path (25a) of which is connected to the cold water supply line (16), the second path (25b) of which is connected to the heat exchanger (8) via an intermediate line (26) and the third path (25c) of which is connected to the access line (17) to the storage domestic water heater (1) via a third bypass line (27). (Fig. 2 and 5) 6. System according to claims 4 and 5, characterized in that the cold water quantity control valves (19, 25) can be controlled by a temperature sensor (20) in the service water distribution line (9) to the taps (10). (Fig. 1, 2 and 6) 30 Oct. 1992 HSP 2100a/92 7. System according to one of claims 1 to 6, characterized in that the heat exchanger (8) consists of a total of three compactly combined partial heat exchangers (8a, 8b, 8c), of which the first (8a) is connected at its inlet to the domestic water outlet line (7) and at its outlet to the domestic water distribution line (9) to the taps (10), the second (8b) is connected at its inlet to the cold water supply line (16) and at its outlet to the access line (17) to the storage domestic water heater (1) and the third partial heat exchanger (8c) is connected at its inlet to the domestic water collection line (13) and at its outlet to the access line (17) to the storage domestic water heater (1). (Fig. 3 to 8) 8. System according to claim 7, characterized in that the service water collecting line (13) is connected in the flow direction upstream of the third partial heat exchanger (8c) via a fourth bypass line (29) to the access line (17) to the storage service water heater (1), in which (29) a Circulation water quantity control valve (30) with two ways (30a, 30b) is arranged. (Fig.4) 30 Oct. 1992 HSP 2100a/92 9. Plant according to claim 7 or 8,
characterized in that/3 in the service water collecting line (13) in the flow direction before the third
Partial heat exchanger (8c) Circulation water quantity control valve (32) with three ways (32a, 32b, 32c) is arranged, the first way (32a) of which is connected to the
Water flow limiter (15), the second Path (32b) to the entrance of the third
Partial heat exchanger (8c) and its third path (32c) is connected to its output and together with this output to the access line (17) to the storage domestic water heater (1). (Fig.5) 10. Plant according to one of claims 7 to 9, characterized in that da/3 the cold water supply line (16) in
Flow direction before the second
Partial heat exchanger (8b) with the
Access line (17) to Storage domestic water heater (1) is connected via a fifth bypass line (34) in which a cold water quantity control valve (35) with two
Ways (35a, 35b) are arranged. 30 Oct. 1992 HSP 2100a/92 11. Plant according to one of claims 7 to 10, characterized in that da/3 a cold water quantity control valve (33) with three ways (33a, 33b, 33c) is arranged in the cold water supply line (16), the first way (33a) of which is connected to the cold water supply line (16), the second way (33b) of which is connected to the inlet to the second partial heat exchanger (8b) and the third way (33c) of which is connected to the outlet from the second partial heat exchanger (8b) and together with this outlet to the access line (17) to the storage domestic water heater (1). (Fig.5) 12. Installation according to one of claims 8 to 11, characterized in that the The circulation water quantity control valve (30, 32) and the cold water quantity control valve (33, 35) can each be controlled by a temperature sensor (31, 20) of the domestic water distribution line (9). 13. Installation according to one of claims 1 to 12, characterized in that the domestic water heater of the storage domestic water heater (1) is formed from a heating medium circuit (3) with a heating medium pump (4), which (4) is controlled together with the circulation pump (12) by a temperature sensor (23) in the
Storage domestic water heater (1) can be switched. 30 Oct. 1992 HSP 2100a/92 14. System according to one of claims 1 to 13, characterized in that several storage domestic water heaters (1) with the same or different storage volumes are connected in series. 15. Plant according to one of claims 1 to 14, characterized in that/3 the storage volume of the
Storage domestic water heater (1) is adjusted to the maximum inflow of cold water and to the flow rate of the circulation pump (12) in such a way that/3 the domestic water is only discharged from the
Storage domestic water heater (1) can be conveyed to the heat exchanger (8) via the domestic water outlet line (7).