The present invention relates in general to a cooking device with a cooking chamber and pertains more particularly to a cooking device having a cooking chamber with an outlet for a fluid for cleaning purposes.
Cooking devices are used for the preparation of foods. The foods located therein are heated. During this process, vapors or steam or also other fluids are formed, which must be removed. For this reason, a cooking chamber outlet, through which these fluids then pass to a cooking device outlet or waste water connection and are disposed of, is generally located in the base of the cooking chamber of the cooking device.
Such a cooking device with a cooking chamber outlet for a fluid, a device outlet, a water reservoir, a connection pipe from the water reservoir into the cooking chamber, a transport means associated with the connection pipe for the controllable supply of fluid from the water reservoir into the cooking chamber, and a distribution means for the fluid in the cooking chamber is known from the patent document DE 20 2004 000 106 U1, for example.
Moreover, it is necessary that the cooking chamber of cooking devices is regularly cleaned. There have already been a series of proposals to automate this cleaning process as far as possible. The patent documents DE 197 30 610 C1, EP 0 892 220 B1, DE 100 17 966 A1, DE 101 09 247 A1, the subsequently published EP 1 364 166 B1 and DE 20 2004 000 106 U1 describe respective cooking devices, which perform such an automatic cleaning of the cooking chamber and its fittings, i.e. using a circulation-type principle. What the configurations all have in common is that the device outlet is closed by means of a valve or another assembly. A container is thus formed. This container can be the cooking chamber itself, or an additional container can also be arranged in the waste water pipe. If the cooking chamber is to be cleaned in this case, the cooking chamber or the container is filled with a cleaning liquid and the liquid is then distributed in the cooking chamber by means of a circulation pump.
The closed device outlet is then opened again to pass the now used liquid out of the cooking device again.
This process is controlled by means of an electronic device control system for the automatic cleaning.
While this automatic cleaning is indeed quite effective, certain aspects still cause problems therein. This applies in particular to the closing process of the device outlet. For example, if the locking device provided for this should not function as a result of a malfunction or if it is also only partially impaired, then this also compromises the main purpose of the entire cooking device, since the contaminated liquid can no longer exit from the cooking chamber, for example. Then, the entire cooking device can no longer be used, although only an ancillary unit with a subsidiary purpose is affected.
However, at least cleaning is already rendered impossible as a result.
Moreover, the cross-sections of the relevant pipe sections for a closure are relatively large for technical reasons. The diameters generally lie between 30 mm and 70 mm. As a result of this, the appropriate devices for closing these pipes are also quite expensive.
In contrast, it is an object of the present invention to permit an automatic cleaning for such cooking devices with a design that is as simple as possible, but also substantially technically reliable.
This object is achieved by a cooking device with a cooking chamber, a cooking chamber outlet for a fluid, a device outlet, a water reservoir, a connection pipe from the water reservoir into the cooking chamber, a transport means associated with the connection pipe for the controllable supply of fluid from the water reservoir into the cooking chamber, and a distribution means for the fluid in the cooking chamber, which is distinguished in that an air trap is arranged downstream of the cooking chamber outlet, the device outlet is arranged downstream of the air trap, that the water reservoir lies in the air trap, the connection pipe leads from the water reservoir in the air trap into the cooking chamber, and the transport means for the controllable supply of fluid from the water reservoir into the cooking chamber are arranged so that they convey fluid from the water reservoir in the air trap into the cooking chamber.
The present invention makes use of an element, which is in fact already present in many cooking devices, but serves a quite different purpose here, while not posing any detriment to these other purposes.
Cooking devices with steam generating systems generally have a waste water assembly to connect these to a local waste water network. The condensates and liquids formed during cooking are discharged via this waste water assembly during cooking, as already mentioned above.
In this case, an air trap is occasionally provided in the waste water assembly so that no odors or vapors can exit through this waste water assembly and/or pass into the cooking chamber. Corresponding proposals have already been made in patent document DE 32 15 812 C2 or again in DE 196 51 283 C2. DE 101 09 247 A1 works without such an air trap, for example, thus requiring another type of odor screen. In this case, only a quenching box is connected to the cooking chamber outlet.
An air trap has a water reservoir, which prevents odors or vapors from being able to pass through the assembly.
This existing water reservoir in the air trap is now used according to the present invention as the basic liquid for cleaning. This leads to the surprising result that an additional closure of the cooking chamber outlet or cooking device outlet for instance is no longer necessary. Such a closure can be omitted completely. If one considers that closures used hitherto in practice with their accessories cost some hundreds of dollars and moreover must be painstakingly maintained, the advantage resulting from the invention is clearly evident.
An additional connection pipe is provided, with which the liquid can be brought from the water reservoir into the cooking chamber by means of a transport means. Thus, the above-mentioned disadvantages from the prior art are overcome.
It is particularly preferred that a vapor quenching means for the supply of fresh fluid to the air trap is provided.
Such a system can have a magnetic valve, for example, and a connection to the local water pipe network and can act as a condensation cooling system. The air trap is filled by it when fluid is removed from the water reservoir. However, during the cooking process in the cooking chamber of the cooking device, i.e. during the usual function, such a vapor quenching means restricts the temperature of the water reservoir and thus also of the condensate passing above to a maximum value. For this, a temperature sensor can be positioned in the water reservoir, which restricts this maximum temperature in association with a controller.
Since the temperature of the water reservoir is limited by this vapor quenching means in the cooking operation, the transport means at the same time protects against any damage as a result of too high a vapor temperature.
It is advantageous if heating elements provided in the cooking chamber are also directly used to heat the cleaning fluid. This can be achieved by a skilful arrangement and utilisation of the distribution means.
Moreover, it is preferred to provide a transport means associated with the air trap, which conveys fluid from the water reservoir in the air trap to the waste water connection.
With such a transport means, e.g. a circulation pump and/or lifting pump, the content of the air trap can be conveyed to the cooking device outlet and thus additionally the water exchange can be assisted in the water reservoir.
In a preferred embodiment, the transport means associated with the air trap and with the connection pipe are identical. Therefore, the very same pump can be used for both purposes.
It is additionally preferred that the transport means are pumps. Such pumps are particularly suitable as transport for the desired purpose.
In addition, it is preferred that a controllable junction is provided in the connection pipe, from which a branch pipe leads to the device outlet. So-called evacuation pumps, centrifugal pumps and also other types of pumps can be used. It is favourable if larger particles can also be transported in order to transport the content of the air trap into the device outlet. Sieves can also be appropriate in specific cases.
If the pump fails, then the cooking chamber can still be rinsed with fresh water and then dried, and then used for its main purpose, namely cooking food materials. Therefore, it is readily possible to continue to cater for a festive occasion or a dinner in a restaurant with the cooking device and wait for the alerted repair service to come the next day, which can be very important economically.
In this case, for the practical application case, a switchover 2/3-way valve can be used, for example, which is positioned behind the transport means in the connection pipe, and thus effects a selective transport of the fluid from the air trap either into the cooking chamber or into the cooking device outlet.
Moreover, it is preferred if a supply means for fresh water into the cooking chamber is provided.
It is particularly preferred in this case if the supply means has a nozzle in the cooking chamber for distribution of the fresh water.
It is provided in an embodiment that the distribution means for the fluid in the cooking chamber has a nozzle at the end of the connection pipe in the cooking chamber, which undertakes distribution of the fluid conveyed from the air trap in the cooking chamber. Moreover, the fan wheel frequently located in the cooking chamber can also be added to assist the distribution means, and thus can achieve a good distribution of the cleaning fluid in the entire cooking chamber.
Moreover, the cleaning function is properly fulfilled particularly when supply means are provided for cleaning and/or clear rinsing agents into the cooking chamber or to the supply means for the fresh water into the cooking chamber or into the connection pipe from the air trap into the cooking chamber or into the air trap.
Finally it is preferred if a separating element is arranged in the air trap, which separates a region of the air trap, in which coarse particles are deposited, from an extraction region of the air trap for the transport means. This prevents coarse contaminating particles such as crumbs from being entrained with the conveyed fluid into the cooking chamber again. Instead, they lie ready to be easily conveyed to the waste water connection.
Some embodiments of the invention are described in more detail below on the basis of the drawing:
A first embodiment of a complete assembly according to the invention is shown schematically in
In this embodiment, a circulation system 14 for the cooking chamber 10 is located on one side wall 13 of the cooking chamber 10. The circulation system 14 has a motor and a fan wheel 15 located inside the cooking chamber 10.
A water reservoir 34 is located in the air trap. The surface or water level of this water reservoir 34 in the air trap 33 is also referred to as the water line 35.
Finally, a pipe leads from the air trap 33 to the cooking device outlet 36 and also forms the waste water connection to the local waste water network.
The water level or water line 35 reaches as far as the outlet level in the air trap 33 into the pipe to the cooking device outlet 36.
In the paragraph depicted in
A vapor quenching means 51 leads into the air trap 33. The vapor quenching means 51 also serves as a condensation cooling system and has a connection to the local water pipe network, so that cool fresh water can be supplied and as a result the temperature of the water reservoir 34 in the air trap 33 can be restricted to a legally permissible maximum value. This also restricts the temperature of the waste water in the cooking device outlet 36.
A temperature sensor 34A is arranged in the water reservoir 34 of the air trap 33 for this purpose, which in conjunction with a controller 34B effects this temperature restriction.
A connection pipe 40 now leads into the cooking chamber 10 from the air trap 33 or, more particularly out of its lower area in the water reservoir 34. The connection pipe 40 terminates in the vicinity of the fan wheel 15 of the circulating air system 14 in the shown and also preferred embodiment.
A transport means 41 is provided, which conducts a fluid, i.e. the liquid present in the water reservoir 34 in particular, out of the air trap 33 into the cooking chamber 10 and, as mentioned, into the vicinity of the fan wheel 15. This transport means 41 is preferably a circulation pump. Since the temperature of the water reservoir 34 is also restricted to a maximum value during the cooking operation of the cooking device, the pump or the transport means 41 is protected from too high a vapor temperature.
If during the cleaning process a part of the liquid is removed from the water reservoir 34 in the air trap 33 by the transport means 41, the water line 35 would actually drop accordingly. The automatic cleaning control system can be provided for this, so that the filling means associated with the vapor quenching means 51 now also operate after the transport means 41 has been switched on and feed fresh water into the air trap 33 here during the cleaning process. This simultaneously ensures that the odor lock out function of the air trap 33 can also remain assured without change as the water level 35 is maintained above the bottom end of wall 35. At the same time, it can thus also be ensured that any overflow integrated into the air trap is further blocked with the water reservoir 34 and prevents steam and possibly also any foam formed during cleaning to exit there.
During the normal cooking operation of the arrangement from
If a cleaning operation is performed now after the cooking operation has ended, then firstly water is fed into the entire system by means of the vapor quenching means 51 or through further means still to be described in association with the following figures, and thus exchanges the liquid in the air trap 33. Solid constituents or also fats and oils are frequently deposited and held here during the cooking operation. These are discharged in this way.
At this point in time or also with a slight time shift, the transport means 41, e.g. the circulation pump, can also be switched on to achieve a better mix of the liquid in the air trap 33 and thus promote the exchange of the liquid. After a certain time, the liquid in the water reservoir 34 in the air trap 33 is sufficiently pure. If the transport means 41 is not yet in operation, it is now switched on, while fresh water is preferably further supplied by means of the vapor quenching means 51 or other structural elements to counteract the drop in the water line 35 of the water reservoir 34 in the air trap 33.
The transport means 41 conveys the liquid through the connection pipe 40 into the cooking chamber 10 and, in the embodiment shown in
In this case, a cleaning agent can also be introduced into the transported liquid. There are several possibilities for this, which are not illustrated here in detail. Thus, liquid cleaning agents, for example, can be fed into the connection pipe 40 by means of pumps or valves, which are actuated accordingly by the device control system 34B. A further possibility lies in the use of cleaning tabs or other additional devices and containers such as are known, for example, from EP 1 209 419 A2 or EP 1 103 599 A1.
The rotating fan wheel 15 now directs the liquid discharging from the connection pipe 40, in particular together with the cleaning fluid contained therein or simultaneously supplied thereto, into the cooking chamber 10. As a result of this, the inside wall and the installation parts in the cooking chamber 10 are cleaned by the action of the cleaner and the impinging liquid.
The liquid ultimately collects on the base 11 of the cooking chamber 10 and runs via the cooking chamber outlet 31 in the base 11 through the pipe 32 again to the air trap 33.
This process is preferably performed at a cooking chamber temperature of between 40° C. and 100° C., since this elevated temperature improves the cleaning action.
There is also the possibility during the cleaning process to replace part of the cleaning liquid by means of the vapor quenching means 51 or by other means, and possibly introduce a new cleaner into the circulation, which is produced by the transport means 41 and is formed via the connection pipe 40, the cooking chamber 10, the cooking chamber outlet 31, the pipe 32 and the air trap 33.
The additional introduction of a new cleaner is of particular advantage in the case of heavily soiled cooking chambers 10.
After a certain time the cleaning process is ended. There is now the possibility of also performing a clear rinsing process. This is not essential for the cleaning process, but is often preferred in order to neutralise the alkalinity of the cleaning agent by means of the acid of the clear rinsing agent, so that a lime-free and optically particularly pleasing cooking chamber 10 result.
For this process the contents of the air trap 33 are rinsed out again by means of the vapor quenching means 51 and/or the transport means 41 to now remove the cleaner or dilute the contents of the air trap 33 accordingly. By supplying water, the cleaning fluid runs together with the deposits removed from the cooking chamber 10 to the cooking device outlet 36 and on into the local waste water network.
If after a certain time the liquid in the air trap 33 is replaced by fresh water, then a further circulation process can start, in which either the mentioned clear rinsing process is initiated or, if necessary, a further cleaning process can additionally occur.
In the clear rinsing process, the procedure is substantially the same as the cleaning process, but a clear rinsing agent is supplied instead of the cleaning agent.
At the end of the clear rinsing step, the liquid in the air trap 33 is exchanged again to free the cooking chamber 10 as far as possible of any clear rinsing agent now contained therein. However, during this process the temperature is lowered sufficiently to ensure that the temperature of the circulated liquid does not exceed 50° C., where possible, to avoid lime deposits in the water, which could optically obscure the cooking chamber 10.
At the end of all the cleaning processes, a vaporising step can also be provided in the automatic cleaning, for example, to also remove any remaining residues of clear rinsing agent or also detergent residues. This is very effective in particular in cooking devices with a steam generation system in the cooking chamber, since possibilities are readily provided there to feed water in liquid form into the cooking chamber and vaporise it.
Finally, a drying process can also be provided in the cooking chamber 10.
In this case, the nozzle 42 can be caused to rotate either by the pressure of the transport means 41, i.e. through the pump pressure, or also by outlet nozzles suitably arranged with respect to flow, and/or can also be motor-driven. The cleaning performance can be further increased by such flushing nozzles.
It is then possible to also use such an embodiment in cooking devices, which do not have a circulating air system 14 and a fan wheel 15, however these can also be additionally present.
In
Various cooking devices already have systems for feeding water into the cooking chamber 10 in order to generate steam there by means of the prevailing cooking chamber temperature. In such cooking devices, these systems for feeding water can also be used as supply means 20 to supply water for cleaning purposes.
The supply means 20 can be used alternatively or in addition to the vapor quenching means 51 to feed water into the system, which via the connection pipe 40 consists of the cooking chamber 10, the cooking chamber outlet 31, the pipe 32 and the air trap 33, for the cleaning process. This water can contribute to the exchange of the water in the air trap 33 and hold the water line 35 at the desired level. This applies to both the actual cleaning processes and the rinsing processes.
However, the separating element 52 does not divide the air trap 33 completely, but leaves some passages free so that the air trap can be emptied completely. The height of the separating element 52 is lower than the usual water level 35 in the air trap 33. The arrangement and operation of the different pumps enable the respectively undesirable contaminants to be pumped out of the air trap 33 into the device outlet 36, so that fluid is constantly available in the water reservoir in the air trap, which is also suitable for the cleaning process and which can also be supplemented after the currently proceeding segment of the cleaning process with appropriately acid or base added elements.
The individual process steps can all be performed by an automatic system such as the controller 34B shown only in
Number | Date | Country | Kind |
---|---|---|---|
05009414 | Apr 2005 | EP | regional |
Number | Name | Date | Kind |
---|---|---|---|
3889099 | Nuss | Jun 1975 | A |
4110916 | Bemrose | Sep 1978 | A |
4503760 | Pryputsch et al. | Mar 1985 | A |
4823766 | Violi | Apr 1989 | A |
5029519 | Boyen | Jul 1991 | A |
5272963 | Del Fabbro | Dec 1993 | A |
5423248 | Smith et al. | Jun 1995 | A |
5481962 | Tedesco | Jan 1996 | A |
5499577 | Tommasini | Mar 1996 | A |
5503061 | Hopkins | Apr 1996 | A |
5615603 | Polin | Apr 1997 | A |
5690020 | Kitani et al. | Nov 1997 | A |
5694835 | Mangina | Dec 1997 | A |
7325481 | Helm | Feb 2008 | B2 |
Number | Date | Country |
---|---|---|
32 15 812 | Nov 1983 | DE |
32 15 812 | Nov 1983 | DE |
197 30 610 | Oct 1998 | DE |
196 51 283 | Jan 2001 | DE |
100 17 966 | Oct 2001 | DE |
101 09 247 | Oct 2002 | DE |
101 62 953 | Jul 2003 | DE |
20 2004 000 106 | Jun 2004 | DE |
10 2004 006 973 | Oct 2004 | DE |
10 2004 001 220 | Mar 2005 | DE |
10 2004 001 224 | May 2005 | DE |
0 892 220 | Jan 1999 | EP |
1 103 599 | May 2001 | EP |
1 209 419 | May 2002 | EP |
1 364 166 | Nov 2003 | EP |
2 849 166 | Mar 2003 | FR |
Number | Date | Country | |
---|---|---|---|
20060260476 A1 | Nov 2006 | US |