DE4236959A1 - Mains water heating and legionella destruction appts. - has storage water heater connected to circulating water circuit - Google Patents

Abstract

A mains water heating and legionella killing installation has a heat exchanger which preheats the cold water supply and which cools the hot disinfected water from a storage water heater, the heat exchanger being in communication with a circulating water circuit formed by a mains water distribution line to a tap, a circulation line, a circulation pump and a mains water collection line. The novelty is that the storage water heater (1) is connected to the circulating water circuit (2) to form an overall circuit (1,2) via the mains water collection line (13), a backflow preventer (14), a water quantity limiter (15), the heat exchanger (8) which thus preheats the circulating water, and an entry line (17). ADVANTAGE - The installation has energy efficient operation and low mfg. cost over a wide installation size range.

Description

The invention relates to a system for Heating domestic water and killing Legionella in this process water with a Cold water supply to a heat exchanger for Preheating the cold water supplied and Cooling down via a service water outlet pipe brought up to disinfection temperature heated domestic water from a DHW cylinder, with the Heat exchanger with one Circulating water circuit is connected, from a domestic water distribution line to Taps, a circulation line, one Circulation pump and one Service water manifold is formed.

A known system of this type according to GB-2 099 559 A, Fig. 3, has the disadvantage that only part of the water heated to the disinfection temperature from the DHW cylinder reaches the heat exchanger via the DHW outlet line, but another A portion of the heated state reaches the circulation water circuit directly on the hot water side via a backflow preventer and a three-way mixing valve. As a result, at the disinfection temperatures of 60 ° C disclosed here, the unavoidable lime deposits can lead to malfunctions in the three-way mixing valve and / or the non-return valve and thus lead to scalding from the hot process water heated to the disinfection temperature in the circulation water circuit at the taps. There is a branch behind the circulation pump, which leads with one branch to the three-way mixing valve and with its other branch to the DHW cylinder. According to the disclosure content of this document, the amount of water that returns from the circulation pump via the second branch to the storage water heater is designed so large that the enthalpy losses related to this amount of water within the circulation water circuit through the branch leading to the three-way mixing valve Process water outgoing pipe can be compensated for by the enthalpy transported in it. In this respect, this system can only be used to a very limited extent to kill legionella in the process water, especially in the circulation water circuit.

Furthermore, in the meantime extensive investigations are found that is in the circulation water cycle  Legionella even when loading disinfected water over the In principle, the hot water outlet pipe is not avoid. According to the result of this Research is the cause of education of Legionella essentially in that already the first time the system is filled with the Filling water legionella in the Circulating water circuit can be introduced, out of which they with the usual means thermal disinfection cannot be eliminated.

This applies even if according to the DE-PS 38 40 516 according to FIGS. 4 and 4a in closed disinfection cycle with Is formed, the hydromechanical and thermally from the circulation water circuit is separated. Also in DE-PS 38 40 516 in Column 1 thermal described in the third paragraph Disinfection through a gradual setting the temperature in the Domestic water distribution line to 70 ° C in practice with large systems, such as in Hospitals, retirement homes, hotels and barracks, in the event of a breakdown with the conventional Means and procedures not sufficiently safe perform and is also with on and Two-family houses not guaranteed.

Based on this state of the art the invention has for its object a system to create the genus mentioned above with which in an energy business  and inexpensive manufacture both for small as well as in the case of large systems Circulation water circulation came Legionella either significantly reduced or killed can.

This task is done in conjunction with the generic term according to the invention solved in that the DHW cylinder via the Process water manifold, one Backflow preventer, a water flow limiter and also for preheating via the heat exchanger of the circulation water and an access pipe with the circulation water circuit into one Overall cycle is connected. Doing so of course, proceed in such a way that the Disinfection temperature in DHW cylinders constantly and is permanently maintained, whereby this high temperature range as well as the accompanying lime deposits on a local very limited area of the entire facility remain limited. Furthermore, despite the Connection of the DHW cylinder with the circulation water cycle into one Overall cycle an energy economy Maintain operation. The in Circulation water cycle through the Initial filling or due to a breakdown existing legionella are permanently in the DHW cylinder introduced and killed there. This reduces the  Concentration of Legionella in Circulation water cycle considerably. Will the entire system over a long period of time mastered in this way, the whole Circulation water several times through the Storage water heater sluiced, there again heated to disinfection temperature and on ultimately a complete one Legionella can be killed.

Through the water flow limiter in connection with the backflow preventer is achieved from the process water manifold is just such a big one Circulation water quantity for Storage hot water heater is promoted that always a safe and constant Disinfection temperature is maintained. The backflow reducer ensures Overall cycle for a clear Flow direction. As per relevant Publications the germ growth of Legionella requires longer periods and one Doubling only in two to three hours can be done, the Legionella are both made the circulation water cycle as well as from the Chilled water network significantly through disinfection reduced and completely with longer tapping rest killed. The "warming swing" ensures between DHW cylinder and Heat exchanger even with multiple disinfection of process water for one energy industry operation.  

Since now in contrast to the prior art according to GB 2 099 559 A the Circulation water cycle also over the Heat exchanger for preheating the Circulation water with the DHW cylinder is connected, and both hydromechanically and in terms of a heat transfer thermal, stands out this facility by a special energy industry operation. Further the lime deposits remain on the Hot water side, that is on the DHW cylinder as well as on the Process water outgoing line up to Heat exchangers limited, all further arm fittings in the form of the Backflow preventer and Water flow limiter and the still too descriptive control valves basically on the Cold water or tap temperature side arranged be it in the process water manifold or be it in the access line to the DHW cylinder in which the water a temperature well below 60 ° C of z. B. 40 ° C. Finally, with this facility by including the Circulation water circuit both at the tap as well as with the nozzle DHW cylinder in one Overall cycle also a significant reduction or killing the Legionella guaranteed, because the water of the circulation water circuit permanent to the DHW cylinder  pumped over and over again to the Disinfection temperature is heated if and as far as it is not previously on the tap from the Overall cycle.

As a result, the circulation pump meets in related to the circulation water cycle also the function of a charge pump Achieving a largely aseptic Domestic hot water in the DHW cylinder and the connecting lines of the Overall cycle.

After an advantageous development of Invention is the whole on the suction side of the Circulation pump pending water quantity of the Circulation water cycle over one Circulating water distribution valve with three ways in the process water manifold to Storage hot water pumpable, of which the first way with the circulation pump, the second way with the backflow preventer and the third way via a first bypass line with the Process water distribution line to the taps connected is. It is Circulating water distribution valve either in Dependence on the disinfection temperature in the Storage water heater from one there arranged temperature sensor or depending from time to time adjustable that the total amount of circulation water or just a subset of this water from the Circulation water circuit to the heat exchanger  release and the rest Total circulation water or partial quantity over the first bypass line in the Process water distribution line to the taps is eligible. Because of this Circulation water distribution valve is used at a Tap from the circulation water circuit ensured that over the Process water distribution line in the Circulation water circuit only the absolutely amount of water required for disinfected water with a selectable, constant temperature can flow in.

According to an advantageous embodiment in a second bypass line in Flow direction before the heat exchanger between the cold water supply line and the access line to the DHW cylinder on Cold water flow control valve with two ways arranged.

After another advantageous one Embodiment is in the cold water supply line Heat exchanger a cold water flow control valve is arranged with three paths, the first of which with the cold water supply, its second way via an intermediate line with the heat exchanger and its third way via a third Bypass line with the access line to the DHW cylinder is connected. The Cold water flow control valves are advantageous from a temperature sensor in the  Process water distribution line to the taps adjustable. This ensures that at Withdrawals at the taps via the Process water distribution line in the DHW circulation water from selectable, constant temperature can flow in, without the water temperature in the DHW cylinder must be increased.

After a particularly advantageous one Further development of the invention consists of Heat exchanger made of three compact summarized partial heat exchangers, of which the first at his entrance with the Process water outlet pipe and at its outlet with the domestic water distribution line to the Taps, the second at its entrance with the Cold water supply and at its outlet with the Access line to DHW cylinder and the third partial heat exchanger with its Entrance to the process water manifold and with its exit to the access line to DHW cylinders are connected. This training becomes a significant one Simplification of the structure of the overall cycle reached, where control valves can be dispensed with can.

According to a first alternative execution the process water manifold in Flow direction before the third Partial heat exchanger via a fourth Bypass line with the access line to the  DHW cylinder connected, in which is a circulation water quantity control valve is arranged with two paths.

According to a second alternative execution in the process water manifold in Flow direction before the third Partial heat exchanger Circulating water quantity control valve with three Arranged because its first path with the Water flow limiter, the second way to the Entrance and its third way to the exit of the third partial heat transfer and together with this exit to the access line to DHW cylinder is connected. With the circulation water quantity control valve and with the cold water flow control valve, the Water outlet temperature from the heat exchanger chosen for the domestic water distribution line and be managed. The regulation of two control valves each with a temperature sensor in the process water distribution line.

After an advantageous development of Invention is the hot water heater of the DHW cylinder from one Heating medium circuit formed with heating medium pump, the together with the circulation pump from one Temperature sensor in the DHW cylinder is switchable.  

After a particularly advantageous one Further development of the invention are several DHW cylinder with the same or different storage volumes in series connected in series. Such a facility is particularly useful for larger building units suitable for a large storage volume, the technical effort compared to others Proposals is significantly reduced.

In each system according to the invention, the storage volume of the DHW cylinder is matched to the maximum supply of cold water and to the delivery rate of the circulation pump in such a way that the DHW can only be conveyed from the DHW cylinder via the process water outflow line to the heat exchanger in the disinfected state. As a result, freshly disinfected process water is constantly fed directly in front of the tap points, even when the water is tapped, while at the same time the process water previously located at this point is pumped into the DHW cylinder for further disinfection. Since this process is carried out continuously when the tap is tapped and when it is tapped, freshly disinfected service water is always available at the tap, which means that new legionella formation can be reduced to zero. It is essential that according to recent studies with a bacterial load of approx. 10 ⁹ CFU / ml (colony-forming units per milliliter) the time until Legionella from serogroups 4 and 6 is killed at a process water temperature of 70 ° C approx. 4 min-6 min, at 66 ° C approx. 45 min and at 60 ° C 60 min-120 min. For the systems according to the invention, this means that at a disinfection temperature of 70 ° C in the storage hot water heater with maximum withdrawal at the tapping points and thus with the maximum supply of cold water, the respective storage volume and the delivery rate of the circulation pump must be coordinated in such a way that the preheated condition Cold water entering the DHW cylinder must pass at least 6 minutes to pass through the DHW cylinder without being able to shoot through the DHW cylinder in a shorter time from entry to exit. With appropriately coordinated storage volumes, this can be done, for example, using known baffles or similarly known devices within the storage container.

Several training examples of the invention are shown in the drawings. Show:

Fig. 1 shows a first embodiment of the invention with a second bypass duct between the cold water supply line and the access line to the memory and the water heater disposed therein cold water quantity control valve with two ways,

Fig. 2 shows a second embodiment with a circulating water distribution valve with three ways and a first bypass pipe in the circulation water circuit and a cold water quantity control valve with three ways in the cold water supply,

Fig. 3 shows the embodiment of Fig. 1 with a compact, consisting of three Teilwärmeübertragern heat exchanger on cessation of the cold water control valve,

Fig. 4 shows the embodiment of Fig. 3 with a circulating water quantity control valve and a cold water quantity control valve with two ways,

Fig. 5 shows the embodiment of Fig. 4, but each with a circulation water quantity and a cold water quantity control valve, each with three paths and

Fig. 6 shows the embodiment of Fig. 4, but with the circulation water distribution valve of Fig. 2 in the circulation water circuit.

Each of the systems described below has at least one DHW cylinder 1 and a circulation water circuit 2 . The storage hot water heater 1 , one of which can be sufficient in single and two-family houses and several can be connected in series in larger building units with the same or different storage volumes, consists essentially of a storage 1 a and a heating medium circuit 3 with a heating medium pump 4th In the embodiments of FIGS. 1, 2, 3 and 5, the heating medium circuit 3 heats the domestic water located in the interior of the storage 1 a via a heating coil 5 . In the exemplary embodiments in FIGS. 4 and 6, the heating medium circuit 3 acts on the reservoir 1 a via an outer jacket 6 . Which of these types of heating of the storage 1 a is to be preferred depends essentially on the heating medium, its primary energy and the storage concept.

The hot water heated to the disinfection temperature in the hot water heater 1 passes through the hot water outlet line 7 to the heat exchanger 8 , which it leaves via the hot water distribution line 9 to the tapping points 10 . About the circulation line 11 , the hot water not taken from the taps 10 is pumped from the circulation pump 12 via the hot water manifold 13 through the backflow preventer 14 , the water flow limiter 15 via the cold water supply line 16 to the heat exchanger 8 , to which it is fed via the access line 17 to the hot water heater 1 leaves.

Referring to FIGS. 1 and 2, the heat exchanger 8 is acted upon from the service water output line 7 and the cold water supply line 16 in countercurrent.

As can be seen from the above description, the storage domestic hot water heater 1 is connected to the circulation water circuit 2 via the process water outflow line 7 , the heat exchanger 8 and the access line 17 to form an overall circuit 1 , 2 .

According to Fig. 1 is for controlling the amount of cold water in a second bypass line 18 upstream of the heat exchanger 8 between the cold water supply line 16 and access line 17 to the memory utility water heater 1, a cold water quantity control valve 19 with two ways 19 a and disposed b 19. This cold water quantity control valve 19 is controlled via a temperature sensor 20 located in the process water distribution line 9 .

According to the embodiment of FIG. 2, the entire, at the suction side 12 a of the circulation pump 12 pending water amount of the circulation water circuit 2 can via a circulating water distribution valve 21 with three paths 21 a, 21 b and 21 c in the hot water collection line 13 for Storage hot water heater 1 are pumped, the first way 21 a of the circulation water distribution valve 21 with the circulation pump 12 , the second way 21 b with the backflow preventer 14 and the third way 21 c via a first bypass line 22 with the hot water distribution line 9 is connected to the tap 10 .

As can also be seen from Fig. 2, the circulation water distribution valve 21 is either depending on the disinfection temperature in the storage hot water heater 1 by a temperature sensor 23 arranged there or by a temperature sensor 36 in the hot water distribution line 9 or depending on the time Regulated via a timer 24 such that the total amount of circulation water or only a partial amount of this water from the circulation water circuit 2 reaches the storage water heater 1 and the remaining total circulation water or partial amount via the first bypass line 22 into the domestic water distribution line 9 is promoted to the taps 10 .

2 also is shown in Fig. In the cold water supply line 16 to the heat exchanger 8 a cold water quantity control valve 25 with three paths 25 a, 25 b and 25 c arranged, the first path 25 a to the cold water supply line 16, the second path 25 b via an intermediate line 26 is connected to the heat exchanger 8 and its third path 25 c via a third bypass line 27 to the access line 17 to the storage water heater 1 . This cold water quantity control valve 25 is also controlled by the temperature sensor 20 in the process water distribution line 9 to the taps 10 .

In all the figures described below, corresponding parts of FIGS . 1 and 2 are designated by the same reference numerals. In all figures, the arrows in the lines indicate the direction of flow of the process water or of the circulation water.

According to the embodiment of FIG. 3, the heat exchanger 8 of a total of three compact combined Teilwärmeübertragern 8 a, 8 b and 8 c, of which the first 8 a at its input to the service water output line 7, and at its output to the service water distribution line 9 to the tapping points 10 , the second 8b at its entrance with the cold water supply line 16 and at its output via a connecting line 28 with the access line 17 to the storage water heater 1 and the third partial transformer 8 c with its input to the service water collecting line 13 and with its output is also connected to the access line 17 to the DHW cylinder 1 . With regard to the process water outflow line 7 of the first partial heat exchanger 8 a, the cold water supply line leading to the second partial heat exchanger 8 b is connected in cocurrent and the process water collecting line 13 leading to the third partial heat exchanger 8 c is connected in counterflow. Due to the DC connection of the cold water supply line, the temperature on the hot water outlet side is limited to the mean temperature between hot water and cold water. As a result, control valves can be dispensed with in individual systems or their function can be facilitated.

According to Fig. 3 and 4, the circulation pump 12 and the Heizmediumpumpe 4 jointly by the temperature sensor 23 in the storage container 1 a of the memory Brauchwassererwärmers 1 are switched.

In addition, in Fig. 4 the hot water manifold 13 is connected in the flow direction upstream of the third partial heat exchanger 8 c via a fourth bypass line 29 to the access line 17 to the hot water heater 1 , in which 29 a circulation water quantity control valve 30 with two paths 30 a and 30 b is arranged. This circulation water quantity control valve 30 is controlled by a temperature sensor 31 which, like the temperature sensor 20, is arranged in the process water distribution line 9 to the tapping points 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 is arranged with two paths 35 a, 35 b.

The embodiment of the system according to FIG. 5 differs from that according to FIG. 4, except for the other design of the storage hot water heater 1 , essentially in that the two-way cold water quantity control valve 35 and the two-way circulation water quantity Control valve 30 have been replaced by three-way control valves. To this end, FIG. 5, according to c in the hot water manifold 13 in the direction of flow before the third partial heat exchanger 8, a circulating water quantity control valve 32 with three paths 32 a, 32 b and 32 c arranged, the first path 32 a with the Wassermengenbegrenzer 15 whose second path 32 b is connected to the input and the third path 32 c to the output of the third partial heat exchanger 8 c and together with this output to the access line 17 to the storage water heater 1 .

In addition, in the embodiment of FIG. 5 in the cold water supply line 16, a cold water quantity control valve 33 with three paths 33 a, 33 b and 33 c is arranged, the first path 33 a with the cold water supply line 16 , the second path 33 b with the entrance to second partial heat exchanger 8 b and its third way 33 c is connected to the output from the second partial heat exchanger 8 b and is connected together with this output to the access line 17 to the storage 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 process water distribution line 9 .

In the exemplary embodiments in FIGS . 4 and 6, the cold water supply line 16 is connected in the flow direction upstream of the second partial heat exchanger 8 b to the connecting line 28 to the access line 17 to the storage water heater 1 via a fifth bypass line 34 , in which a cold water quantity control valve 35 is connected two paths 35 a and 35 b is arranged.

The embodiment of FIG. 6 differs from that of FIG. 4 in that the circulation water distribution valve 21 according to the embodiment of FIG. 2 is arranged in the process water collecting line 13 . In this respect, reference is made to the relevant statements relating to FIG. 2.

All of the above embodiments are suitable not only for relatively small systems of one 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 hot water flowing in simultaneously or in countercurrent via the hot water outlet line 7 , before it is fed via line 17 to the hot water heater 1 reached. This cold water of, for example, 10 ° C. has only a small number of Legionella, which can be completely destroyed in the storage water heater 1 . In this respect, the legionella in the cold water is not a significant problem.

However, legionella formation in the circulation water circuit 2 becomes problematic after an initial filling or a breakdown. Since the water from the service water discharge line 7 was not only disinfected in these cases before the entry, the legionellae in the circulation water circuit 2 find excellent thermal growth conditions, which means that they can multiply explosively. Then, for example, the legionella can emerge from the tap 10, for example from a shower, inhaled with the water vapor by the user and thereby develop their life-threatening effects.

The invention counteracts a growth of the regional by the fact that now the circulation water circuit 2 is constantly connected to the DHW cylinder 1 to form an overall circuit 1 , 2 , especially when the water is at rest. As a result, the circulation pump 12, which also acts as a circulating pump for the entire circuit, permanently promotes the water in the circulation water circuit 2 for renewed disinfection in the storage water heater 1 , which considerably reduces the legionella in the circulation water circuit 2 and also kills them completely in the event of longer dispensing breaks can.

The above-described embodiments can be used both in single and two-family houses and in larger building units. In the latter case, a plurality of DHW cylinders 1 with the same or different storage volume are advantageously connected in series. Here, too, the storage volume of the storage 1 a of the storage water heater 1 is always matched to the maximum withdrawal quantity and thus to the maximum inflow amount of cold water and to the delivery capacity of the circulation pump 12 such that the used water at the respective disinfection temperature or storage 1 a must pass in a period belonging to this disinfection temperature before it arrives in the safely disinfected state from the storage hot water heater 1 via the hot water outlet line 7 to the heat exchanger 8 . Since lime precipitations are unavoidable at disinfection temperatures above 60 ° C, they remain limited to the hot water side, that is, to the storage hot water heater 1 and to a partial area of the heat exchanger 8 . All the above-described control arm fittings 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 ° C. On the other hand, the process water outflow line 7 , in which hot process water is conveyed to the heat exchanger 8 at the disinfection temperature, and the process water distribution line 9 are fundamentally free of the aforementioned control devices, thereby preventing malfunctions of the control valves described above due to lime deposits.

Like the embodiment of Fig has. 3, with the use of a compact, a total of three Teilwärmeübertragern 8 a, 8 b, 8 c composing heat exchanger 8, no control valve is required.

Reference list

1 DHW cylinder
1 a memory
2 circulation water circuit
1, 2 overall circuit
3 heating medium circuit
4 heating medium pump
5 heating coil
6 outer jacket water heater
7 Process water outlet pipe
8 heat exchangers
8 a, 8 b, 8 c partial heat exchangers
9 Service water distribution line
10 taps
11 Circulation line
12 circulation pump
12 a suction side of the circulation pump 12
13 Process water manifold
14 non-return valve
15 water flow limiter
16 cold water supply
17 Access line 17
18, 22, 27, 29, 34 bypass line
19, 25, 33, 35 cold water flow control valve
19 a, 19 b ways of the valve 19
20, 23, 31, 36 temperature sensors
21 Circulating water distribution valve
21 a, 21 b, 21 c ways of valve 21
24 timer
25 a, 25 b, 25 c ways of valve 25
26 intermediate line
28 connecting line
30, 32 circulation water quantity control valve
30 a, 30 b ways of the valve 30
32 a, 32 b, 32 c ways of the valve 32
35 a, 35 b ways of the valve 35

Claims (15)

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 cold water supplied and for cooling the domestic water which is brought to a disinfection temperature and heated to a disinfection temperature from a storage domestic water heater, the heat exchanger is connected to a circulation water circuit which is formed by a domestic water distribution line to taps, a circulation line, a circulation pump and a domestic water collecting line, characterized in that the storage domestic water heater ( 1 ) via the domestic water collecting line ( 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 ) with the circulation water circuit ( 2 ) to form an overall circuit ( 1 , 2 ) connected is. 2. Installation according to claim 1, characterized in that the entire on the suction side (12 a) of the circulation pump water quantity pending (12) of the circulation water circuit (2) via a circulating water distribution valve (21) with three paths (21 a, 21 b, 21 c) can be pumped in the process water collecting line ( 13 ) to the storage process water heater ( 1 ), of which the first route ( 21 a) with the circulation pump ( 12 ), the second route ( 21 b) with the backflow preventer ( 14 ) and the third path ( 21 c) is connected via a first bypass line ( 22 ) with the process water distribution line ( 9 ) to the tapping points ( 10 ). ( Figs. 2 and 6). 3. Installation according to claim 2, characterized in that the circulation water distribution valve ( 21 ) either as a function of the disinfection temperature in the DHW cylinder ( 1 ) from a temperature sensor ( 23 ) arranged there or as a function of time via a timer ( 24 ) can be regulated in such a way that the total circulation water quantity or only a partial quantity of this water from the circulation water circuit ( 2 ) to the heat exchanger ( 8 ) is released and the remaining total circulation water quantity or partial quantity via the first bypass line ( 22 ) into the process water Distribution line ( 9 ) to the tap ( 10 ) can be promoted. ( Figs. 2 and 6). 4. Installation according to one of claims 1 to 3, characterized in that in a second bypass line ( 18 ) in the flow direction in front of the heat exchanger ( 8 ) between the cold water supply line ( 16 ) and the access line ( 17 ) to the DHW cylinder ( 1 ) a cold water flow control valve ( 19 ) with two paths ( 19 a and 19 b) is arranged. ( Fig. 1). 5. Plant 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 ( 25 a, 25 b, 25 c) is arranged, the first route ( 25 a) with the cold water supply line ( 16 ), the second route ( 25 b) via an intermediate line ( 26 ) with the heat exchanger ( 8 ) and the third route ( 25 c) via a third bypass line ( 27 ) the access line ( 17 ) to the DHW cylinder ( 1 ) is connected. ( Figs. 2 and 5). 6. System according to claims 4 and 5, characterized in that the cold water quantity control valves ( 19 , 25 ) from a temperature sensor ( 20 ) in the process water distribution line ( 9 ) to the taps ( 10 ) can be regulated. ( Figs. 1, 2 and 6). 7. Installation according to one of claims 1 to 6, characterized in that the heat exchanger (8), of which the first (8 a) at its input with a total of three compact combined Teilwärmeübertragern (8 c 8 a 8 b) the process water outlet pipe ( 7 ) and at its outlet with the process water distribution pipe ( 9 ) to the taps ( 10 ), the second ( 8 b) at its inlet with the cold water supply pipe ( 16 ) and at its outlet with the access pipe ( 17 ) to the DHW cylinder ( 1 ) and the third partial heat exchanger ( 8 c) with its input to the DHW manifold ( 13 ) and with its outlet to the access line ( 17 ) to the DHW cylinder ( 1 ). ( Figs. 3 to 8). 8. Installation according to claim 7, characterized in that the process water manifold ( 13 ) in the direction of flow upstream of the third partial heat exchanger ( 8 c) via a fourth bypass line ( 29 ) with the access line ( 17 ) to the store process water heater ( 1 ) is connected, in which ( 29 ) a circulation water quantity control valve ( 30 ) with two paths ( 30 a, 30 b) is arranged. ( Fig. 4). 9. Plant according to claim 7 or 8, characterized in that in the process water manifold ( 13 ) in the direction of flow in front of the third partial heat exchanger ( 8 c) a circulation water quantity control valve ( 32 ) with three paths ( 32 a, 32 b, 32 c ) is arranged, the first way ( 32 a) with the water flow limiter ( 15 ), the second way ( 32 b) to the input of the third partial heat exchanger ( 8 c) and the third way ( 32 c) at the outlet and together with this Output is connected to the access line ( 17 ) to the DHW cylinder ( 1 ). ( Fig. 5). 10. Installation according to one of claims 7 to 9, characterized in that the cold water supply line ( 16 ) in the direction of flow before the second partial heat exchanger ( 8 b) with the access line ( 17 ) to the DHW cylinder ( 1 ) via a fifth bypass line ( 34 ) is connected, in which a cold water quantity control valve ( 35 ) with two paths ( 35 a, 35 b) is arranged. 11. Plant according to one of claims 7 to 10, characterized in that in the cold water supply line ( 16 ) a cold water quantity control valve ( 33 ) with three ways ( 33 a, 33 b, 33 c) is arranged, the first way ( 33 a ) with the cold water supply line ( 16 ), the second way ( 33 b) with the entrance to the second partial heat exchanger ( 8 b) and the third way ( 33 c) with the output from the second partial heat exchanger ( 8 b) and together with this output is connected to the access line ( 17 ) to the DHW cylinder ( 1 ). ( Fig. 5). 12. Plant according to one of claims 8 to 11, characterized in that the circulation water quantity control valve ( 30 , 32 ) and the cold water quantity control valve ( 33 , 35 ) each have a temperature sensor ( 31 , 20 ) of the process water distribution line ( 9 ) are adjustable. 13. Plant according to one of claims 1 to 12, characterized in that the hot water heater of the storage hot water heater ( 1 ) from a heating medium circuit ( 3 ) with heating medium pump ( 4 ) is formed ( 4 ) together with the circulation pump ( 12 ) can be switched by a temperature sensor ( 23 ) in the DHW cylinder ( 1 ). 14. Plant according to one of claims 1 to 13, characterized in that a plurality of storage water heaters ( 1 ) with the same or different storage volume are connected in series. 15. Installation according to one of claims 1 to 14, characterized in that the storage volume of the storage hot water heater ( 1 ) is matched to the maximum inflow of cold water and to the delivery rate of the circulation pump ( 12 ) such that the hot water only in the disinfected state the DHW cylinder ( 1 ) can be conveyed to the heat exchanger ( 8 ) via the DHW outlet line ( 7 ).