The invention relates to a device for supplying a treated fluid, in particular drinking water, comprising a treatment device with at least one treatment container for treating the fluid and a temperature control device for controlling the temperature of the fluid in the at least one treatment container, preferably for cooling the fluid.
The invention also relates to a sanitary valve system for dispensing temperature-controlled and/or treated fluid, in particular drinking water, comprising a device for supplying treated fluid and at least one outlet for dispensing the temperature-controlled and/or treated fluid, wherein the at least one outlet is connected to the device.
Although this invention is generally applicable to any treatment device, this invention will be described in relation to treatment devices in the form of carbonators for drinking water.
Treatment devices for enriching beverages with carbon dioxide are available in many different forms in the prior art. These treatment devices include, for example, integrated carbonator containers with a volume of approx. 1-2 litres for beverage cooling and, if necessary, pre-cooling pipes for storing chilled still water and sparkling water for the beverage dispensing taps. An uncooled and non-insulated water filter, such as an activated carbon filter or ion exchanger, may be installed upstream of these cooling units. When water is drawn from the tap, it first flows from this filter into the carbonator's cooling area. During longer periods of non-use, the water in the filter warms up to ambient temperature. This may rise to over 40° C., particularly if the treatment device is installed in a kitchen base unit. This water is rapidly mixed with the already cooled water in the standard cooling devices with a carbonator and/or cooling pipe, so that a significantly higher dispensing temperature is reached after only a few 100 ml of the beverage is dispensed. This also leads to less CO2 being bound in the drink. Another disadvantage is that higher temperatures also increase the hygienic risk, especially in the filter, during extended downtime.
DE 199 33 118 A1 describes a water treatment system for drinking water with a dispensing device, in which both still water and carbonated water can be supplied from two containers connected in series. There is also a cooling device for the water containers with greater cooling of the second container. The drinking water can be cooled through cooling coils of a refrigeration unit surrounding the containers, with additional lengths of the cooling coils being used for the second container as required.
The drawback is that the water treatment system is inflexible and inefficient, as the water containers must be supplied with refrigerant separately. In addition, the cooled water warms up again in the pipes before it is fed to the carbonators. As a result, there is still a hygiene risk if no carbonated water is drawn for a longer period of time.
Therefore, one objective of this invention is to create a device for supplying treated fluid and a sanitary dispensing system which provides more effective temperature control and reduces the risk to hygiene while providing sufficient quantities of treated fluid.
Another objective of the present invention is to provide an alternative device for providing treated fluid and an alternative sanitary dispensing system.
In one embodiment, this invention may solve the above-mentioned objectives by a device for supplying a treated fluid, in particular beverages, comprising a treatment device with at least one treatment container for treating the fluid and a temperature control device for controlling the temperature of the fluid in the at least one treatment container, preferably for cooling it, in that at least one pre-temperature control device is provided with at least one container for controlling the temperature of the untreated fluid, the container having an inlet for non-temperature-controlled, untreated fluid and an outlet from which temperature-controlled, untreated fluid can be provided, and in that the temperature control device is designed such that
In an embodiment, this invention also may solve the aforementioned objectives with a sanitary tap for dispensing temperature-controlled and/or treated fluid, in particular drinking water, which comprises a device according to one of claims 1-16 and at least one outlet for dispensing the temperature-controlled and/or treated fluid, which is connected to the device.
One of the advantages of this is that efficient temperature control can be provided while efficiently treating the water simultaneously. Another advantage is that a sufficient supply of treated, and temperature-controlled fluid can be provided while at the same time reducing the hygiene risk.
The term “sanitary” is to be understood in the broadest sense and refers, in particular in the description, preferably in the claims, among others, to any objects, arrangements, devices, equipment and the like in connection with bathrooms, kitchens, heating systems and the like.
Further features, advantages and embodiments of the invention are described below or are disclosed therein.
A preferred embodiment of the invention is that the at least one pre-temperature control device and the temperature control device are integrated in a common temperature control circuit, in particular with the at least one pre-temperature control device positioned downstream of the temperature control device in the temperature control circuit. One potential advantage of this is that both temperature control devices can be supplied with temperature control medium easily and efficiently.
A further preferred embodiment of the invention is that the temperature control device and the at least one pre-temperature control device are arranged in series or parallel to each other in the temperature control circuit. The advantage of arranging it in series is that it allows for particularly efficient temperature control, whereas a parallel arrangement allows the temperature control devices to be controlled easily and flexibly, if necessary separately.
A further preferred embodiment of the invention is a switching device for feeding untreated, temperature-controlled fluid to an outlet and/or for feeding it to the treatment process, specifically by means of a three-way valve. The advantage of this is that it provides flexible control of the flow of the untreated, temperature-controlled fluid.
A further preferred embodiment of the invention is that a fluid transport device, in particular a pump, is arranged in the fluid transport path, preferably in the fluid transport path between the at least one pre-temperature control device and the temperature control device. This is a simple and efficient way of transporting fluid.
A further preferred embodiment of the invention is that a number of pre-temperature control device devices are arranged in parallel or in series with one another with reference to the fluid transport path. The advantage of this is that lower temperatures can be reached more quickly if temperature control in the form of cooling is used.
A further preferred embodiment of the invention is that fluid treated using a switching arrangement, fluid temperature-controlled using several temperature control devices or a mixture of these can be fed to an output, specifically using at least two valves. This facilitates the flexible dispensing of different types of fluid.
A further preferred embodiment of the invention is that the at least one pre-temperature control device comprises a second treatment device, in particular a filtration device with at least one filter, which can be temperature-controlled by the pre-temperature control device. The advantage of this is the increased flexibility in the provision of different treated fluids.
A further preferred embodiment of the invention is that the at least one pre-temperature control device and/or the temperature control device has pipes for the temperature control circuit which are arranged in the area of the wall of the container and/or the treatment container, in particular where these are located in an insulating material and/or in an air-filled volume, preferably on the radial outer side of the container and/or treatment container. The advantage of this is efficient temperature control of the respective container contents.
A further preferred embodiment of the invention is that the supply pipe to the treatment device is positioned at least in part inside a wall of the treatment container, in particular in an insulating material. The advantage of this is further pre-temperature control of the fluid to be treated by the temperature control device of the treatment device, which allows for particularly reliable temperature control.
A further preferred embodiment of the invention is that the treatment container is positioned at least partially in the container of the at least one pre-temperature control device. The advantage of this is efficient utilisation of the available space.
A further preferred embodiment of the invention is that the treatment container and the container of the pre-temperature control device are located in a shared housing. This facilitates efficient insulation overall and short cable lengths, for example.
A further preferred embodiment of the invention is that a recirculation circuit is configured so that temperature-controlled, untreated fluid is returned to the pre-temperature control device via the temperature control device for the temperature control of untreated, non-temperature-controlled fluid. In this way, the pre-temperature control device can also be temperature-controlled without being directly connected to a temperature control circuit.
A further preferred embodiment of the invention is that the recirculation circuit can be activated using a recirculation switching device. The advantage of this is that the agitation circuit can be efficiently activated as required.
A further preferred embodiment of the invention is that the at least one pre-temperature control device and/or the temperature control device include a phase change reservoir and/or a salt water low temperature reservoir with at least one heat exchanger. The advantage of this is the increased flexibility to add an appropriate reservoir depending on the installation space, availability and desired temperature control.
A further preferred embodiment of the invention is that the treatment device is designed as a carbonator for carbonating drinking water, including in particular a refillable CO2 reservoir. This allows for the efficient supply of CO2-enriched fluid.
Other important features and advantages of the invention result from the dependent claims, from the drawings and the corresponding description of the figures using the drawings.
It is understood that the above-mentioned features, and features yet to be explained below, may be used not only in the respectively indicated combination, but rather also in other combinations or alone, without departing from the scope of the present invention.
Preferred designs and embodiments of this invention are shown in the accompanying drawings and are explained in more detail in the following description, wherein identical reference numbers refer to identical or similar or functionally identical components or elements.
In the form of a diagram,
In
Cooling circuit 9 comprises condenser 8, which is connected to pipes 10a, 10b of an unspecified condensing cooling circuit. Starting from condenser 8, an expansion device is arranged downstream either in the form of a capillary or—as in this case—expansion valve 8a, which is then connected to the aforementioned pipe 9a in wall 2b of container 2. On the side opposite container 2 vertically—at the top in
The following describes dispensing beverages in the form of drinking water but is not limited to this. Starting from drinking water supply device 20, drinking water is fed into container 3 of pre-cooling device 300 via controllable valve 21a and pipe 12a. The drinking water is pre-cooled using pipe 9c of cooling circuit 9, which is located in wall 3b. After cooling in pre-cooling device 300, the pre-cooled drinking water is transported by means of pipe 12b and pump 5 into pipe 12c, which also passes through wall 2b of container 2 along with the helically arranged pipe 9a of cooling circuit 9, notably in an alternating pattern.
This allows the pre-cooled drinking water to be cooled again by cooling circuit 9 before being fed into container 2. Pipe 12c is then connected to three-way valve 6, which allows for fluid connection to container 2 via pipe 12d as well as output 22 of the cooled drinking water via pipe 12f and a switchable valve 21b.
As described above, pipe 12d flows into container 2. In addition, CO2provided by CO2 reservoir 4 can be fed into container 2 via pipe 4b and switchable valve 4a to facilitate enrichment of the pre-cooled drinking water with CO2. The drinking water enriched with CO2 can be dispensed via pipe 12e and switchable valve 21c at outlet 23, for example an outlet of a sanitary valve or similar.
In addition, downstream of pump 5, drinking water pipe 12c-2 of container 3-2 and drinking water pipe 12c-1 of container 2 can be supplied in parallel with pre-cooled drinking water from container 3.
Similarly to three-way valve 6-1, which is connected to pipe 12c-1 and which enables a fluid connection to container 3 via pipe 12d-1 as well as outlet 22 of the cooled drinking water via pipe 12f and switchable valve 21b, pipe 12c-2 also opens into pipe 12f and drinking water can be fed from pipe 12c-2 into container 3-2 via additional three-way valve 6-2 and pipe 12d-2. Water from containers 3, 3-2 can be selectively connected to water outlet 23 either individually or fluidically mixed via corresponding extraction pipes with switchable valves 21c-1, 21c-2.
Cooling circuit 9 as shown in
In
In contrast to the “container-in-container” embodiment of
Water supply 20 for container 3 can be provided via supply pipe 27, which passes through container 2 into container 3. The same also applies to the corresponding extraction pipe 25 for still water 102 from container 3. This extraction pipe 25 can also supply cooled water from container 3 to container 2 for CO2 enrichment via pipe 27a. As in the embodiments shown in
Instead of pipe 9c, there is now a drinking water pipe 12g in insulation 3a, which can be used to cool container 3. Pipe 12g is connected via pipe 12b1 to a circulation pump 5a for this purpose, which in turn is connected to pipe 12b and pipe 12c for container 2. In addition, a fluidic connection with pipe 12g is positioned in pipe 12f between the three-way valve 6 and valve 21b. If circulation pump 5a is activated and a fluidic connection is established between pipe 12c and pipe 12f using three-way valve 6 and valve 21b is closed, container 3 can be cooled using the water that is additionally cooled by cooling circuit 9 prior to CO2 enrichment. This forms recirculation circuit 40.
Overall, in all embodiments of
The temperature can be controlled using a control device, not shown here, which regulates the temperature as required or on a time schedule by controlling the corresponding valves, pumps in the water supply and the cooling circuit according to sensor information such as the temperature in the containers, the quantity and type of fluid to be dispensed or similar.
In summary, at least one of the embodiments of the invention may provide one of the following features and/or provide at least one of the following advantages:
Although the present invention was described using preferred embodiments, it is not limited to these, but rather may be modified in various ways.
Number | Date | Country | Kind |
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10 2023 201 390.8 | Feb 2023 | DE | national |