The invention relates to a conveyor dishwasher and an operating method for same.
Conveyor dishwashers (such as a belt conveyor dishwashing machine or flight-type dishwasher) are used in the commercial area. An exemplary conveyor dishwasher is known from European Patent 0 838 190 B1. In contrast with household dishwashers in which the wash ware to be cleaned remains stationary in the machine during the cleaning process with conveyor type dishwashers the wash ware is conveyed through various zones of the conveyor dishwasher. Each zone is provided with a tank which holds the liquid sprayed in the respective zone. The conveyor dishwasher includes in particular at least one zone designed as a wash zone in which the wash ware is cleaned to remove impurities, e.g., food residues.
With known conveyor dishwashers, two factors often contribute to the total water consumption: first, the initial filling of the conveyor dishwasher in which fresh water is added to the tank of the at least one wash zone and, secondly, the final rinse during operation of the conveyor dishwasher. The final rinse liquid supplied for the final rinse runs according to the cascade principle through the entire machine. The water is kept fresh in the tanks, i.e., the concentration of impurities is kept low by constant dilution. Another effect of this supply of liquid into the tanks is that exactly as much liquid is displaced out of the tanks, i.e., enters the drain, as is supplied to the tanks.
In an aspect, a conveyor dishwasher for cleaning wash wares includes a conveyor device for conveying the wash wares in a direction of conveyance through at least two zones of the conveyor dishwasher, at least one zone of which is a wash zone having spray nozzles. A tank and a pumping device are provided for recirculating wash liquid from the tank to the spray nozzles and spraying the wash liquid through the spray nozzles onto the wash wares. At least one zone is a final rinse zone including spray nozzles for spraying final rinse liquid onto the wash wares. A storage tank gathers sprayed final rinse liquid and a liquid transfer device is used for transferring liquid from the storage tank to the wash zone, which thereby forms a target zone. A control unit is configured for automatic operation of the liquid transfer device depending on the liquid demand in the wash zone.
In another aspect, a method for operating a conveyor dishwasher is provided. The method includes providing the conveyor dishwasher with a final rinse zone for spraying final rinse liquid onto the wash ware and a wash zone for spraying wash liquid onto the wash ware. Wash liquid is sprayed onto the wash ware in the wash zone. Final rinse liquid is sprayed onto the wash ware. The final rinse liquid is collected in a storage tank. The final rinse liquid is supplied to the wash zone as a function of demand for liquid.
Advantageously, a supply of final rinse liquid may be available in the storage tank, the tank may be filled with the final rinse liquid from the storage tank when liquid is entrained. This can reduce fresh water consumption.
The initial filling of the conveyor dishwasher may be performed using final rinse liquid from the storage tank. This can reduce the demand for fresh water.
This invention is explained in greater detail below with reference to the drawings on the basis of preferred embodiments as examples. The definitions and explanations given above also apply to the following description of the drawings and vice-versa.
The conveyor dishwasher 2 shown in
The term “wash ware 4” includes, as examples, dishes, glasses, cutlery, pots, containers, boxes, trays, etc. The term “cleaning” includes, as examples, pre-wash, wash, post-wash, final rinse, etc. The term “washing” refers to cleaning the wash ware 4 with the wash liquid to remove impurities from the wash ware 4. The term “final rinse” refers to the treatment of the wash ware 4 with final rinse liquid to remove wash liquid in particular from the wash ware 4. Final rinse liquid may be, for example, pure water or water to which a rinse aid has been added.
The conveyor dishwasher 2 illustrated in
The final rinse zone 16 has spray nozzles 36 for spraying final rinse liquid onto the wash ware 4. The final rinse liquid may be conveyed by a pump mechanism 38 to the spray nozzles 36, as depicted here, for example, or it may be conveyed through corresponding line pressure in the final rinse liquid line. A heat exchanger 40 and a heating device 42, preferably a water heater, are provided for heating the final rinse liquid.
The final rinse liquid discharged from the final rinse nozzles 36 may be fresh water, for example or fresh water mixed with rinse aid.
The conveyor dishwasher 2 has a bottom part 44 where the sprayed final rinse liquid collects. In the embodiment illustrated here, the bottom area 44 includes an area of the final rinse zone 16 and the post-wash zone 14. A tank opening 45 may be formed in the bottom area 44 opening into the tank 22 of the post-wash zone 14, as illustrated in
According to this invention the conveyor dishwasher has a storage tank 46 to hold sprayed final rinse liquid. “Sprayed final rinse liquid” as used herein may be final rinse liquid sprayed by the spray nozzles 36 of the final rinse zone 16 or post-wash liquid sprayed by the spray nozzles 28 of the post-wash zone 14. Post-wash liquid is final rinse liquid that has already been used. In any case, “sprayed final rinse liquid” refers to a liquid to which no detergent has been added in order to maintain a predetermined detergent concentration in the final rinse liquid, as is the case with the wash liquid in wash tanks 18, 20. Of course, the final rinse liquid sprayed onto the wash ware 4 and running off of the wash ware 4 contains a nonspecific detergent concentration, but it is lower than the detergent concentration in the wash tanks.
In general, at least one zone in which final rinse liquid is sprayed is connected by fluid flow to the storage tank 46. For example, the final rinse zone 16 may be connected to the storage tank 46 by flow in such a way that sprayed final rinse liquid enters the storage tank 46. Furthermore, the post-wash zone 14 may be connected by flow to the storage tank 46 in any desired manner so that sprayed final rinse liquid enters the storage tank 46.
In the embodiment depicted here, the bottom part 44 has a storage tank opening 47 in the area of the post-wash zone 14, said opening being connected by flow to the storage tank 46, namely by a line 48 here. As an alternative to the embodiment depicted here, the line 48 may be connected to the bottom part 44 in the area of the final rinse zone. Furthermore, the line 48 may be connected to the tank 22 of the post-wash zone 14.
In the depicted embodiment, zone walls 50 are provided, bordering the bottom part 44 at the side and permitting a liquid level 52 above the tank opening 45 and above the storage tank opening 47 so that liquid can flow out of the tank 22 and into the storage tank opening 44 and then can flow out through the line 48 into the storage tank 46. This configuration permits adequate filling of the tank 22 with final rinse liquid on the one hand, while on the other hand also allowing final rinse liquid to automatically flow over into the storage tank 46 when the liquid level 52 is higher than the storage tank opening 47.
A controllable liquid transfer device 54 is provided having a pump mechanism 56 and a liquid line 58 for transferring liquid from the storage tank 46 to the rear wash zone 12, which thus forms a target zone. The liquid transfer device 54 may be formed by any other device which allows controlled transfer of liquid from the storage tank 46 into the at least one target zone.
The mouth 60 of the liquid transfer device 54 is preferably arranged with a distance in height above than tank 20 of the wash zone 12, as illustrated in
To determine a liquid demand in at least one of the wash zones 10, 12, a sensor device may be provided.
The front wash zone 10 includes a sensor device in the form of a turbidity sensor 64 for detecting a degree of soiling of the liquid in the tank 18 of the front wash zone 10. Furthermore, the rear wash zone 12 includes a sensor device in the form of a turbidity sensor 66 for detecting a degree of soiling of the liquid in the tank 20 of the rear wash zone 12. The control unit 62 is designed for operating the liquid transfer device 54 when the degree of soiling in the tank 20 of the rear wash zone 12 is above a predetermined degree of soiling. By operating the liquid transfer device 54, liquid from the storage tank 64 is supplied to the tank 20 of the rear wash zone 12 and thus the degree of soiling, i.e., the concentration of impurities in the tank 20 of the rear wash zone 12 is reduced.
The control unit 62 is also designed for operating the liquid transfer device 54 when the degree of soiling in the tank 18 of the front wash zone 10 exceeds a predetermined degree of soiling. The predetermined degree of soiling of the liquid in the tank 20 of the rear wash zone 12 may be equal to the predetermined degree of soiling of the liquid in the tank 18 of the front wash zone 12. Furthermore, the predetermined degree of soiling of the liquid in the tank 18 of the front wash zone 10 may be higher than the predetermined degree of soiling of the liquid in the tank 20 of the rear wash zone 12. In the case of a liquid demand in the tank 18 of the front wash zone 10 and operation of the liquid transfer device 54 on this basis, the liquid is supplied in the embodiment depicted here from the storage tank 46 to the tank 20 of the rear wash zone 12 from which liquid can flow via liquid overflow device 68, namely an overflow channel here, into the tank 18 of the front wash zone 10 to thereby reduce the concentration of impurities in the liquid in the tank 18. The liquid from the tank 20 of the rear wash zone 12 flows over the overflow channel 68 into the tank 18 of the front wash zone 10 when the liquid level in the tank 20 of the rear wash zone 12 is above the outflow level 77.
The tank 18 of the front wash zone 10 is equipped with an overflow 70 (drain) through which liquid can flow out of the tank 18. When the liquid in the tank 18 of the front wash zone is above an outflow level 79, liquid flows out of the tank 18 through the overflow 70.
At least one of the sensor devices may also be designed in the form of a liquid level sensor for detecting a predetermined level of liquid in the tank of the respective at least one wash zone. In the embodiment depicted here, the rear wash zone 12 is provided with a level sensor 72 for detecting a predetermined lower level 73 of liquid in the tank 20 of the rear wash zone 12. Furthermore, the front wash zone 10 is provided with a liquid level sensor 74 for detecting a predetermined lower level 75 of the liquid in the tank 18 of the front wash zone 10. The predetermined lower level 73 of the rear wash zone 12 may be at the same height as the predetermined lower level 75 of the front wash zone 10. Furthermore, the predetermined lower level 73 of the rear wash zone 12 may be higher or alternatively lower than the predetermined lower level 75 of the front wash zone 10. The predetermined lower levels 73, 75 are preferably below the respective outflow level 77, 79 of the respective tank 20, 18. In the embodiment depicted here, the liquid level sensors 72, 74 are designed as level switches, where the predetermined lower level 73, 75 corresponds to the lower switch point of the respective liquid level switch 72, 74.
Liquid may be supplied out of the storage tank 46 into the respective target zone over a predetermined period of time, for example. Furthermore, liquid may be supplied from the storage tank 46 into the respective target zone until a predetermined upper level has been reached or exceeded in the target zone. The predetermined upper level may be for example the upper switch level of the liquid level switch 72, 74 in the respective wash zone 10, 12. The predetermined upper level of the respective wash tank may be at the same height as the outflow level 77, 79 of the respective wash tank, for example.
In particular, entrainment of liquid by large dishes from the rear zone 12 into the front zone 10 can be detected by means of the liquid level sensor 72 in the tank 20 of the rear zone 12 and the tank may be filled accordingly with liquid out of the storage tank 46. Such an entrainment of liquid in conveyor dishwashers occurs in particular with large wash ware whereby liquid entrainment occurs in the opposite direction from the direction of conveyance of the wash ware and consists of the fact that liquid which is sprayed onto the wash ware 4 in a downstream zone in the direction 8 of conveyance, flows into the preceding zone 10 on this wash ware 4.
There may also be a demand for liquid in the wash zones 10, 12 in the initial filling of the conveyor dishwasher 2. Accordingly, the control unit 62 is preferably designed for operating the liquid transfer device 54 in the initial filling of the conveyor dishwasher 2 to supply liquid from the storage tank 46 to at least one of the wash zones 10, 12, preferably both wash zones 10, 12. In this way, the fresh water demand of the conveyor dishwasher 2 can be reduced because no supply of fresh water is necessary for the initial filling of the wash tanks 18, 20 but instead the final rinse liquid generated in a previous cleaning operation of the conveyer dishwasher is reused for the initial filling of the wash tanks 10, 12.
To this end, the volume of the storage tank 46 maybe of such a dimension that it is at least equal to the sum of the individual tank volumes of the wash tanks 18, 20 of the wash zones 10, 12. Furthermore, depending on the available space, the volume of the storage tank 46 may be smaller than the sum of the individual tank volumes of the wash tanks 18, 20.
As
A sensor device for determining a fresh water demand in the storage tank 46 may be, for example a liquid level sensor 78 for detecting a predetermined lower level 80 of the liquid in the storage tank 46. The control unit 62 is in this case designed to operate the fresh water supply device 76 in predetermined operating states, e.g., in the initial filling of the wash tanks and thereby supply fresh water to the storage tank 46 when the liquid level in the storage tank is equal to the predetermined lower level 80 or below the predetermined lower level 80. The predetermined lower level 80 in the embodiment depicted here corresponds to the lower switch point of the liquid level sensor 78 which is designed as a level sensor. It is possible to provide for a predetermined amount of fresh water to be supplied in operation of the fresh water supply device 76. Furthermore, it is possible to provide for fresh water to be supplied until reaching a predetermined upper level 81 which is detected by a suitable liquid level sensor. In the embodiment depicted here, the predetermined upper level 81 corresponds to an upper switch point of the level sensor 78 and is thus also detected by the level sensor 78.
A sensor device for determining a fresh water demand in the storage tank 46 may be, for example, in the form of a turbidity sensor 82 for detecting a degree of soiling of the liquid in the storage tank 46. The control unit 62 is in this case designed for operating the fresh water supply device 76 and thereby supplying fresh water to the storage tank 46 when the degree of soiling of the liquid in the storage tank 46 is equal to or greater than a predetermined soiling limit.
The storage tank 46 preferably has an overflow 84 over which liquid flows out when the liquid level in the storage tank is above a predetermined outflow liquid level 86, as illustrated in
In the embodiment illustrated here, the liquid transfer device 54 is the only liquid transfer device for transferring final rinse liquid out of the post-wash zone 14 or out of the final rinse zone 16 into one of the wash zones 10, 12. The baffle 87 shown in
Due to the flow connection of the two wash tanks 18, 20 through the liquid overflow device 68, it is sufficient to provide a liquid transfer device 54 only in the rear wash zone 12. As an alternative, it is possible for a liquid transfer device from the storage tank 46 into the rear wash zone 12 to be provided as well as a liquid transfer from the storage tank 46 into the front wash zone 10 to be provided (not shown), preferably controlled by the control unit 62 independently of one another. In this case, the flow connection 68 between the rear wash zone 12 and the front wash zone 10 may be omitted.
In the above-described conveyor dishwasher 2, sprayed final rinse liquid is advantageously collected in a storage tank, and liquid from the storage tank 46 is supplied to at least one wash zone as a function of a liquid demand. In this way, replenishing of the liquid in the wash tank, i.e., dilution of the liquid in the wash tanks, is performed only when necessary. Any addition of final rinse liquid or fresh water to the wash tanks requires a corresponding addition of detergent to maintain the desired detergent concentration in the wash tanks. Liquid is supplied to the wash tanks only when needed, and the demand for detergent for operation of the conveyor dishwasher 2 is reduced. When a great deal of water is entrained by large dishes, liquid can be supplied to the rear wash tank 20 through the storage tank 46. In this way, a fresh water supply to the rear wash tank, as is customary with known dishwashers, becomes superfluous. This reduces the fresh water consumption by the conveyor dishwasher 2. The final rinse liquid in the storage tank 46 may be used for an initial filling of the wash tanks 18, 20. The fresh water demand by the conveyor dishwasher 2 is reduced in this way.
Depending on the level distance desired between the predetermined upper level and the predetermined lower level in the respective tank 10, 12 or in the storage tank 46, a float switch having a suitable hysteresis range (distance between the upper and lower switch points) may be used for the respective liquid level switches 72, 74, 78. Alternatively, a different number of liquid level sensors having a different function principle may also be used.
The connecting lines have not been shown in the drawings for reasons of simplicity. However, it is self-evident that all the parts of the conveyor dishwasher 2 (e.g., the control unit 62 with the liquid transfer device 54) that cooperate functionally are connected to one another functionally accordingly.
It is to be clearly understood that the above description is intended by way of illustration and example only and is not intended to be taken by way of limitation, and that changes and modifications are possible. Accordingly, other embodiments are within the scope of the following claims
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