DE29615555U1 - Shower system - Google Patents

Description

G 12 012 Gb : ;:**· * '♦ t *.#&idiag; · %*|4**? ^e P ^{tember 1996}

Rainer SchneLls, Schmerbach 4, D-42799 Leichlingen

Shower system

The invention relates to a shower system for heating the water used to clean the user, with a shower area, at least one cold water inlet, at least one hot water inlet leading into the shower area and at least one water outlet leading out of the shower area and with at least one heating element that heats the water to the shower temperature, the heating element being connected to the cold water inlet via a first line and to the hot water inlet via a second line.

In practice, different shower systems are known for heating the water used to clean the user, with differently designed heating elements.

On the one hand, shower systems are known that have a boiler as a heating element, in which the water is stored and heated to the desired shower temperature or is kept at the desired shower temperature. The boiler is connected to a cold water supply via a first line and to the hot water supply of the shower area via a second line. When the user takes a shower, the water (fresh water) that has already been heated to the shower temperature is fed to the shower area via the second line and leaves it - after the user has cleaned himself - as waste water through the water drain leading from the shower area.

On the other hand, shower systems are known that have a continuous flow heater as the heating element, which is connected to the cold water supply via a first line and to the hot water supply leading to the shower area via a second line. When the user takes a shower, the water that cleans the user is warmed to the desired shower temperature while it passes through the continuous flow heater. For example, continuous flow heaters are known in which a desired specific water temperature can be set manually on the outside of the housing.

The shower systems known to date in the state of the art are not optimally designed. The energy required to heat the water used to clean the user is very high. With the heating element designed as a boiler, the water must be heated to the

The water can be heated to the desired temperature and then kept at this temperature for a longer period of time. With the heating element designed as a continuous flow heater, the water is heated to the desired shower temperature in a relatively short period of time as it flows through the continuous flow heater. The energy required to heat the water is very high.

The invention is therefore based on the object of designing and developing the known shower system in such a way that the energy required to heat the water is reduced.

The previously indicated task is now solved by at least one heat exchanger element being arranged in such a way that the water to be supplied to the heating element can be heated by the waste water leaving the shower area through the water outlet. Because the water is already preheated before it reaches the heating element, the energy required by the heating element to bring the water to the desired shower temperature is reduced. According to the invention, the thermal energy still contained in the waste water is advantageously used to "preheat" the water coming from the cold water supply (fresh water), in that this "preheating" is realized with the help of the heat exchanger element arranged in a corresponding way.

There are now various possibilities for designing and developing the teaching of the invention, for which reference may be made on the one hand to the claims subordinate to claim 1, and on the other hand to the explanation of preferred embodiments of the invention with reference to the drawing.

The drawing shows

Fig. 1 shows a first embodiment of the shower system according to the invention in a schematic representation, and

Fig. 2 shows a second embodiment of the shower system according to the invention in a schematic representation.

Fig. 1 and 2 show a shower system 1 for heating the water used to clean the user. The shower system 1 has a shower area 2, a cold water inlet 3, a hot water inlet 4 leading into the shower area 2 and a water outlet 5 leading out of the shower area 2. A heating element 6 is also provided for heating the water to the shower temperature, the heating element

element 6 is connected to the cold water inlet 3 via a first line 7 and to the hot water inlet 4 via a second line 8.

Within the shower system 1, at least one heat exchanger element 9 is arranged in a flow-technical manner so that the water to be supplied to the heating element 6 can be heated by the waste water leaving the shower area 2 through the water outlet 5. This heat exchanger element 9 can be designed in various ways. In the illustration in Figs. 1 and 2, the heat exchanger element 9 is designed as a heat exchanger unit 10 with a dashed outline, the structure of which will be described in more detail below.

A structurally simple design of a heat exchanger element 9 is conceivable. The decisive factor is that the heat exchanger element 9 ensures the heat transfer from the still warm waste water to the cold fresh water, so that the energy required for the heating element 6 provided for this purpose to warm or heat the water to the desired shower temperature is reduced. This can save up to 80% of energy. For example, a pipe carrying the waste water could be in contact with a pipe supplying the fresh water in a certain - possibly relatively small - area, so that heat transfer is possible. This area would then form the heat exchanger element 9.

The shower area 2 of the shower system 1 has a shower tray 11, a shower head 12 and control fittings (not shown) for controlling the corresponding water inflow. The shower head 12 is connected to the hot water inflow 4 and the water outflow 5 is arranged in the shower tray 11. Since Figs. 1 and 2 only show schematic representations of the shower system 1, control fittings or a shower cubicle, for example, are not shown.

The heating element 6 is designed here as an electronic instantaneous water heater.

It is also conceivable to arrange other continuous flow heaters or heating elements, especially heating elements designed as solar collectors. However, the use of an electronic continuous flow heater has proven to be particularly advantageous because it allows the desired shower temperature to be optimally set or optimally achieved during the showering process (normal operation).

Since the heat exchanger element 9 used here is designed as a heat exchanger unit 10, the heat exchanger unit 10 has a fresh water inlet 13, a fresh water outlet 14, a waste water inlet 15 and a waste water outlet 16.

The fresh water inlet 13 is connected to the cold water inlet 3 via a connecting line 17 and the fresh water outlet 14 is connected to the heating element 6 via the first line 7. The waste water inlet 15 is connected to the water outlet 5 of the shower area 2 via a third line 18 and the waste water outlet 16 is connected to a waste water line 19.

In both heat exchanger units 10 shown in Fig. 1 and 2, the fresh water inlet 13 is connected to the fresh water outlet 14 via a first pipe coil 20. Furthermore, the waste water inlet 15 is connected to the waste water outlet 16 via a second pipe coil 21. The first pipe coil 20 is designed differently in each heat exchanger unit 10 shown in Fig. 1 and 2.

In the heat exchanger unit 10 shown in Fig. 1, the first pipe coil 20 is designed as a hollow pipe in certain partial areas and the second pipe coil 21 is arranged partially within the first pipe coil 20. This enables a corresponding heat transfer.

In the heat exchanger unit 10 shown in Fig. 2, the first pipe coil 20 has a plurality of turns 22 and the second pipe coil 21 is partially arranged within the turns 22, which in turn enables the corresponding heat transfer.

There are different ways of designing the heat exchanger unit 10, in particular, the heat exchanger unit can be designed as a "swirl condenser". The decisive factor is that - in the end - a good heat transfer from the waste water to the fresh water is guaranteed.

A further advantageous embodiment of the invention is shown in Fig. 1. In the shower system 1 shown here, a flushing line 23 is provided, whereby the cold water inlet 3 is fluidly connected to the waste water inlet 15 of the heat exchanger unit 10 via the flushing line 23. This is achieved here by connecting the flushing line 23 to the third line 18. With the help of the flushing line 23, it is possible to flush the heat exchanger unit 10 so that impurities generated by the user during the showering process can be easily removed.

A first shut-off valve 24 is arranged in the flushing line 23 and a second shut-off valve 25 is arranged in the third line 18. In normal operation, i.e. shower operation, the first shut-off valve 24 is closed and the second shut-off valve 25 is open. The first and second shut-off valves 24 and 25 can be controlled in such a way that the heat

exchanger unit 10, the first shut-off valve 24 is opened and the second shut-off valve 25 is closed.

Furthermore, a third shut-off valve 26 is arranged in the waste water line 19. The connecting line 17 and the waste water line 19 are connected via a fourth line 27, with a fourth shut-off valve 28 arranged in the fourth line 27. In normal operation, the third shut-off valve 26 is open and the fourth shut-off valve 28 is closed.

The shut-off valves 24, 25, 26 and 28 can now be controlled in such a way that on the one hand a long-term flushing of the heat exchanger unit 10 in a certain flow direction is possible, but on the other hand a short-term flushing of the heat exchanger unit 10 with an opposite flow direction is also possible. The heat exchanger unit 10 can thus be flushed over a longer period of time if the first and third shut-off valves 24 and 26 are open and the second and fourth shut-off valves 25 and 28 are closed. If the heat exchanger unit 10 is to be flushed briefly in the opposite direction, the shut-off valves 24, 25, 26 and 28 can be controlled accordingly. The flushing of the heat exchanger unit 10 can be carried out in particular with the help of a foam ball in order to better remove the contaminants.

In the embodiments shown here, a pump unit 29 is arranged in the third line 18 for pumping the waste water.

The heat exchanger element 9 or the heat exchanger unit 10 can also be arranged inside the shower tray 11, for example in the free space remaining below the standing surface of the shower tray. This means that the space requirement for the shower system 1 according to the invention is extremely low.

Normal operation - shower operation - is briefly described below. The fresh water flows into the shower system 1 from the cold water inlet 3 with a water temperature of preferably 7-13 ⁰ C and reaches the fresh water inlet 13 of the heat exchanger unit 10 via the connecting line 17. Here it enters the first pipe coil 20 of the heat exchanger unit 10. When the shower operation continues, so that warm waste water is already being discharged through the second pipe coil 21, a heat transfer takes place within the heat exchanger unit 10, so that the fresh water is heated, i.e. "preheated", before it reaches the heating element 6, which is designed as an electronic continuous flow heater, via the first line 7. Here the fresh water is heated or warmed to the required shower temperature (final temperature) of preferably 30-50 ⁰ C. Because the water is already preheated, the

the energy required for the heating element 6 is reduced accordingly. The water heated to the shower temperature then passes through the second pipe 8, the hot water inlet 4 and the shower head 12 into the shower area 2, where it cleans the user. The water outlet 5 arranged in the shower tray 11

s the waste water is then pumped by the pump unit 29 via the third pipe 18 to the

Heat exchanger unit 10, where it enters the second pipe coil 21 through the waste water inlet 15 and gives off its heat to the fresh water flowing in the first pipe coil 20. Finally, the waste water is discharged through the waste water outlet 16 and the waste water line 19, whereby the waste water preferably has a water temperature of 12-18°C.

A possible flushing operation of the heat exchanger unit 10 will now be briefly described using Fig. 1. While the first and fourth shut-off valves 24 and 28 are closed and the second and third shut-off valves 25 and 26 are open in shower operation, the shut-off valves 24, 25, 26 and 28 can be controlled differently in flushing operation. For longer-term flushing operation, the shut-off valves 25 and 28 can be closed and the shut-off valves 24 and 26 can be opened. However, it is also conceivable that the heat exchanger unit 10 is briefly flushed in the other flow direction, namely when the third shut-off valve 26 is closed and the fourth shut-off valve 28 is open. This could be done briefly until, for example, a backflow forms or in particular when the second shut-off valve 25 is open. Such a change in flow direction - even if it is short-term - can remove contaminants better.

Claims (25)

G 12 012 Gb *.,::..: '»* &Lgr;4- S*p\e«nb*er 1996 Rainer' SchneLLs, Schmerbach 4, D-42799 LeichLingen Protection claims: 1. Shower system (1) for heating the water used to clean the user, with a shower area (2), at least one cold water inlet (3), at least one hot water inlet (4) leading into the shower area (2) and at least one water outlet (5) leading out of the shower area (2) and with at least one heating element (6) heating the water to the shower temperature, the heating element (6) being connected to the cold water inlet (3) via a first line (T) and to the hot water inlet (4) via a second line (8), characterized in that at least one heat exchanger element (9) is arranged in such a way that the water supplied to the heating element (6) water to be supplied can be heated by the waste water leaving the shower area (2) through the water drain (5). 2. Shower system according to the preceding claim, characterized in that the shower area (2) has a shower tray (11), a shower head (12) and control fittings for controlling the water inflow. 3. Shower system according to the preceding claim, characterized in that the shower head (12) is connected to the hot water inlet (4) and the water outlet (5) is arranged in the shower tray (11). 4. Shower system according to one of the preceding claims, characterized in that the heating element (6) is designed as a continuous flow heater. 5. Shower system according to one of the preceding claims, characterized in that the heating element (6) is designed as an electronic continuous flow heater. 6. Shower system according to one of the preceding claims, characterized in that the heating element (6) is designed as a solar collector. 7. Shower system according to one of the preceding claims, characterized in that the heat exchanger element (9) is designed as a heat exchanger unit (10) and the heat exchanger unit (10) has a fresh water inlet (13), a fresh water outlet (14), a waste water inlet (15) and a waste water outlet (16). 8. Shower system according to one of the preceding claims, characterized in that the fresh water inlet (13) is connected to the cold water inlet (3) via a connection line (17) and the fresh water outlet (14) is connected to the heating element (6) via the first line (7). 9. Shower system according to one of the preceding claims, characterized in that the waste water inlet (15) is connected to the water outlet (5) of the shower area (2) via a third line (18) and the waste water outlet (16) is connected to a waste water line (19). 10 10. Shower system according to one of the preceding claims, characterized in that the fresh water inlet (13) is connected to the fresh water outlet (14) via a first pipe coil (20). 11. Shower system according to one of the preceding claims, characterized net that the waste water inlet (15) is connected to the waste water outlet (16) via a second pipe coil (21). 12. Shower system according to one of the preceding claims, characterized in that the first pipe coil (20) is designed as a hollow pipe in certain partial areas and the second pipe coil (21) is arranged partially within the first pipe coil (20). 13. Shower system according to one of the preceding claims, characterized in that the first pipe coil (20) has a plurality of turns (22) and the second pipe coil (21) is arranged partially within the turns (22). 14. Shower system according to one of the preceding claims, characterized in that the heat exchanger unit (10) is designed as a "swirl condenser". 15. Shower system according to one of the preceding claims, characterized in that a flushing line (23) is provided and the cold water inlet (3) is fluidically connected to the waste water inlet (15) of the heat exchanger unit (10) via the flushing line (23), in particular the flushing line (23) with the third line (18). 16. Shower system according to one of the preceding claims, characterized in that a first shut-off valve (24) is arranged in the flushing line (23) and a second shut-off valve (25) is arranged in the third line (18). „„hull Mt·,- 17. Shower system according to one of the preceding claims, characterized in that in normal operation - shower operation - the first shut-off valve (24) is closed and the second shut-off valve (25) is open. 18. Shower system according to one of the preceding claims, characterized in that the first and second shut-off valves (24, 25) can be controlled in such a way that the first shut-off valve (24) is opened and the second shut-off valve (25) is closed in order to flush the heat exchanger unit (10). 19. Shower system according to one of the preceding claims, characterized in that a third shut-off valve (26) is arranged in the waste water line (19). 20. Shower system according to one of the preceding claims, characterized in that the connecting line (17) and the waste water line (19) are connected via a fourth line (27) and a fourth shut-off valve (28) is arranged in the fourth line (27). 21. Shower system according to one of the preceding claims, characterized in that in normal operation the third shut-off valve (26) is opened and the fourth shut-off valve (28) is closed. 22. Shower system according to one of the preceding claims, characterized in that the shut-off valves (24, 25, 26, 28) can be controlled in such a way that a longer-term flushing of the heat exchanger unit (10) in one flow direction and a short-term flushing of the heat exchanger unit (10) with the opposite flow direction is possible. 23. Shower system according to one of the preceding claims, characterized in that a pump unit (29) is arranged in the third line (18) for conveying the waste water. 24. Shower system according to one of the preceding claims, characterized in that the flushing of the heat exchanger unit (10) can be carried out with the aid of a foam ball. 25. Shower system according to one of the preceding claims, characterized in that the heat exchanger element (9) or the heat exchanger unit (10) is arranged within the shower tray (11), in particular in the free space remaining below the standing surface of the shower tray.