Patent Application
20250194892
This application relates generally to warewashers such as those used in commercial applications such as cafeterias and restaurants and, more particularly, to a warewasher deliming system.
Commercial kitchens often utilize warewash machines that require regular cleaning, including occasional deliming in which the water flow paths along the rinse line, including the hot water booster, energy recovery unit, plate heat exchanger unit and/or the rinse piping needs, to be cleaned of scales or lime. Some machines include an integrated and automated delime system. Some machines automatically drain the machine of delime solution at the completion of circulation of the delime solution, using an automated drain valve or a drain pump. However, some machines include a standpipe in the machine tank(s) that needs to be manually raised by an operator in order to drain the tank(s) at the completion of circulation of the delime solution. Other machines include a manual drain valve.
It would be desirable to provide a warewasher and associated deliming system that accounts for possible failure of an operator to timely and properly drain the delime solution.
In one aspect, a warewash machine includes a chamber for receiving wares, the chamber having at least one spray zone in which a liquid is recirculatable from a tank to a spray assembly for spraying the liquid on wares. A delime system is configured for delivering a delime solution to the tank. A controller is configured for operation in at least one ware cleaning mode and at least one delime operation mode. The controller is configured such that, in the delime operation mode, the delime system is controlled to carry out a delime operation in which the controller (i) controls the delime system to deliver delime solution into the tank and (ii) carries out an acidity reduction process to reduce acidity of the delime solution by at least one of (i) causing delivery of fresh water into the tank or (ii) causing delivery of detergent into to the tank.
In the case of delivery of fresh water into the tank, the acidity is reduced by diluting the liquid/solution in the tank. In the case of delivery of detergent into the tank, the acidity is reduced by a neutralization effect of the detergent.
In another aspect, a warewash machine for washing wares includes a chamber for receiving wares, the chamber having at least one spray zone in which a liquid is recirculatable from a tank to a spray assembly for spraying the liquid on wares, the tank including a drain component that must be manually moved in order to drain the tank; a delime system configured for delivering a delime solution to the tank; and a controller configured for operation in at least one ware cleaning mode and at least one delime operation mode. In the delime operation mode, the delime system is controlled to carry out a delime cycle in which the controller: controls the delime system to deliver delime solution into the tank and then circulates the delime solution; and monitors whether drainage of the tank occurs after completion of circulation of the delime solution and initiates and maintains a lockout of the ware cleaning mode until drainage of the tank occurs.
In another aspect, a warewash machine includes a chamber for receiving wares, the chamber having at least one spray zone in which a liquid is recirculatable from a tank to a spray assembly for spraying the liquid on wares. A delime system is configured for delivering a delime solution to the tank. A controller is configured for operation in at least one ware cleaning mode and at least one delime operation mode. In the delime operation mode, the delime system is controlled to carry out a delime operation in which the controller: (i) controls the delime system to deliver delime solution into the tank and monitors the warewash machine to determine whether a tank drain step took place to drain delime solution from the tank, and, if not, the controller automatically carries out an operation to reduce acidity of the delime solution by at least one of (i) causing delivery of fresh water into the tank to dilute the delime solution in the tank or (ii) causing delivery of detergent into to the tank to effect some neutralization of the delime solution in the tank.
The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features, objects, and advantages will be apparent from the description and drawings, and from the claims.
Referring to
A delime system is also provided, and includes a source of delime chemical 42 and a delime pump 44 for selectively feeding delime chemical into the booster heater 34, such that delime solution (water mixed with the delime chemical) can be delivered to the spray zone 18 and tank 20 by operation of the pump 36.
An overflow standpipe 46 is provided in the tank and is engaged with the drain opening 26, such that liquid in the tank rising above an overflow level can travel to the drain path 28 through the standpipe. To fully drain the tank 20, the overflow standpipe 46 is raised upward from the drain opening 26 (e.g., by manually grasping the overflow standpipe), such that liquid flows directly from the tank into the drain opening 26 and along the path 28.
A tank maintenance fill path 50 may also be provided for delivering water from a machine hot water input connection 52 into the tank 20 via operation of a valve 54.
The machine includes a controller 100 configured for carrying out various operations of the machine via operation of the machine components. As used herein, the term controller is intended to broadly encompass any circuit (e.g., solid state, application specific integrated circuit (ASIC), an electronic circuit, a combinational logic circuit, a field programmable gate array (FPGA)), processor(s) (e.g., shared, dedicated, or group-including hardware or software that executes code), software, firmware and/or other components, or a combination of some or all of the above, that carries out the control functions of the machine or the control functions of any component thereof.
The controller 100 may be configured with one or more ware cleaning modes (e.g., spraying wash liquid and rinse liquid on wares moving through the chamber 12a). The controller 100 is also configured with at least one delime operation mode. In the delime operation mode, the delime system is controlled to carry out a delime operation in which the controller delivers delime solution into the tank and spray zone 18 for descaling/deliming of surfaces in the spray zone.
By way of example, delime solution may be made in the booster 34 in a batchwise process or manner, by delivering delime chemical into the booster 34 via pump 44, heating the delime solution in the booster to a set temperature (e.g., to 140 F), and then pumping the delime solution, via the rinse pump 36, to spray through the spray pipes 32a and fill the machine tank(s) 20. The delime solution fills the tank 20 and may be recirculated by the pump 24 for deliming the tank, internal wall surfaces, the tank heater 20a, etc. During a delime circulation process over a set time period, this recirculation may take place continuously, or intermittently with dwell times included. In embodiments, delime chemical could alternatively be delivered directly into the tank 20 without heating in the booster 34.
After the delime solution circulation process is completed, the delime solution should be drained from the tank 20, as it is undesirable to allow the acidic delime solution to sit in the tank for an excessive time period. For this purpose, the machine may include a user interface 102 (e.g., HMI with a display screen) and the controller may effect display of a drain machine alert on the user interface informing the operator that the tank 20 must be drained (e.g., by lifting the overflow pipe 46, or by manual control of a drain valve (not shown)). Before the drain machine alert, any delime solution in the booster 34 may be cleared via operation of the pump 36 to empty the booster 34 (without adding further delime chemical to the booster).
The controller 100 is configured to monitor the machine to determine whether a tank drain step takes place to drain delime solution from the tank 20. In embodiments, if the tank drain does not take place, the controller automatically carries out an operation to reduce acidity (increase pH) of the delime solution by at least one of (i) causing delivery of fresh water into the tank to dilute the solution in the tank (e.g., through the booster 34, and/or directly to the tank via line 50) or (ii) causing addition of detergent to the tank to effect some neutralization of the liquid in the tank (e.g., by a detergent feed line 56 that feeds from a detergent source 57 via a detergent pump 59). The amount of fresh water and/or detergent delivered can be controlled based upon known or expected acidity of the delime solution and the volume in the tank 20, or in tank sensors (e.g., pH meter 61) could also be used to monitor the changing acidity level. The pump 24 can also be selectively operated as part of this operation to reduce acidity.
In embodiments, the controller 100 is configured such that, during the delime operation, a circulation process is carried out in which the delime solution is recirculated, continuously or intermittently, from the tank through the spray assembly 22, and the controller 100 determines whether a tank drain operation took place after conclusion of the circulation process. The controller may be configured such that, if a tank drain operation does not take place within a set time period (e.g., 10 minutes, 20 minutes, 30 minutes or 40 minutes) after conclusion of the circulation process, the controller automatically carries out the operation to reduce acidity. Thus, the timeout of the set time period acts as a triggering event for the acidity reduction process in such embodiments. Moreover, the controller may be configured such that, after the operation to reduce acidity takes place, a lockout is initiated such that operation in the ware cleaning mode is prevented unless and until a tank drain operation is carried out (e.g., even if the machine is powered off and then powered on again). The controller may cause continued display of the machine drain alert to advise operator(s) to drain the tank during the lockout of the ware cleaning mode.
In embodiments, the controller 100 is configured to automatically carry out the operation to reduce acidity before initiating the machine drain alert. In such embodiments, the completion of a delime circulation/wash cycle timer acts as the triggering event for the acidity reduction process. However, in some implementations the acidity reduction process could overlap, in whole or in part, with an end portion of the delime circulation, in which case the triggering event for the acidity reduction process would be reaching some intermediate time point of the delime circulation/wash timer (e.g., 90% of the delime circulation/wash timer completed). In either case, after the acidity reduction operation is completed and the delime circulation/wash timer is completed, the controller initiates the machine drain alert and the ware cleaning mode lockout. The controller may be configured such that, if a tank drain operation does not take place within a set time period (e.g., 10 minutes, 20 minutes, 30 minutes or 40 minutes) after initiation of the machine drain alert, the controller powers down the machine. In such embodiments, the controller is configured such that, on a next power up of the machine, the controller remains in the delime operation mode and reinitiates the machine drain alert and reinitiates or maintains the ware cleaning mode lockout such that operation in the ware cleaning mode is prevented unless and until a tank drain operation is carried out.
In embodiments, the determination of whether a tank a drain operation took place is based upon at least one of (i) monitoring of a level of liquid in the tank (e.g., via a sensor 60), (ii) monitoring a flow of liquid along the drain path 28 from the tank (e.g., via a sensor 62) or (iii) monitoring a condition of a component associated with a drain path from the tank (e.g., via a sensor 64 that detects position of the overflow standpipe 46).
In one embodiment, the controller 100 is configured to such that in the delime operation mode an associated delime operation or cycle is carried out as follows.
An operator accesses the delime operation mode by pressing a displayed “DELIME” button on the user interface 102 with the machine powered on or off. Alternatively, the delime operation mode can also be accessed by entering a “manager” menu via the user interface 102 and scrolling to the delime operation cycle.
The operator is then prompted via the user interface 102 to confirm the start of the delime operation or cycle. To initiate, the operator selects a “yes” button and presses a displayed Enter button.
Next, the operator is notified by a user interface message to clean the strainers and baskets associated with the machine tank(s). Interlocks associated with one or more doors (e.g., 10a, 10b 10c) on the housing will be open to allow the doors to be opened for internal access to the machine. Once baskets and strainers are cleaned, the operator places them back into the machine. The operator then selects “yes” and presses the displayed Enter button to confirm completion of strainer and basket cleaning.
The operator is then notified via a user interface 102 message to drain the machine. The operator will then pull the standpipe(s) 46, 146, 246 as needed to drain all machine tank(s). The user interface shows that the machine is draining and may display progress of draining (e.g., by using tank water level sensors to track the draining). Once the machine has been fully drained, the user interface displays a message instructing the operator close the tank drains (e.g., replace standpipes) and the machine access doors 300. The door interlocks are then closed.
The booster fill valve 40 is then opened and the delime pump 44 energized to add delime chemical into the booster 34, creating the delime solution.
Once the booster water level has reached a set point (e.g., detected by sensor(s) or based upon a known filling time), the rinse pump 36 is energized to deliver the delime solution to the tank(s) (e.g., via the spray arm 32a). During booster filling, the delime pump 44 is operated so that the delime solution is added to the booster 34 periodically to avoid having too strong of a concentration in the booster tank. Rinse pump operation is delayed/stopped until the booster is full and the rinse pump 36 then operates and empties the booster. While emptying the booster, the delime pump 44 remains off so that no delime solution is added. Once the booster 34 is empty, the pump 36 is turned off and the fill of the booster takes place again by opening the valve 40 and periodically operating the delime pump 44 to add delime chemical. This process will repeat until all tank(s) are considered full (e.g., as detected by water level sensor(s)).
Once the controller identifies that all tanks are full, a delime wash cycle is initiated and “Delime Ongoing” is displayed on the user interface 102. The wash pumps 24, 124, 224 are operated (continuously or intermittently/periodically (regular or irregular dwell time periods between pump operation) so that the pumps associated with all tanks present in the machine operate to circulate the delime solution for the purpose of deliming.
The length of the delime wash cycle is controlled by a delime circulation/wash cycle timer. Once the delime circulation/wash cycle timer is reached or times out, the wash pump(s) 24, 124, 224 are stopped and a delime dilution operation begins, during which the user interface displays a rinse cycle in process message. In the delime dilution operation, fresh water is added to dilute the delime solution in the tanks, and thus operates as an acidity reduction process that is triggered by completion of the delime circulation/wash cycle timer. Here, the tank fill valve 54 is opened to provide a direct flow of fresh water (with no delime chemical) into the tank(s). The rinse pump 36 is also operated to empty the booster and the booster fill valve 40 is opened to deliver fresh water into the booster, but the delime pump 44 remains off so that no further delime chemical is added. This assures clearing of delime chemical from the booster. In some cases, the booster 34 may be purged before the tank fill valve 54 is opened. The acidity reduction process is carried out for a specified time according to a delime dilution timer. The specified time is preset according to a known volume of the machine tank(s) and a known concentration of delime chemical that was added.
After completion of the delime dilution timer, a countdown timer is displayed on the user interface along with an operator instruction to drain the machine. If machine is not drained at the completion of the countdown timer, the machine automatically powers down.
At the next machine startup, an operator notification is displayed instructing the operator to drain the machine. Detection of actual draining of all machine tanks is necessary to complete the delime operation or cycle. This effectively locks out the ware cleaning mode(s) of the machine until the tank(s) have been drained as the last step of the delime operation or cycle.
As discussed previously, in an alternative implementation, at the completion of the delime circulation/wash timer, the drain tank message could first be implemented and, if draining does not occur within a specified drain timer, the timeout of the specified drain timer could act as the trigger for the acidity reduction process.
It is to be clearly understood that the above description is intended by way of illustration and example only, is not intended to be taken by way of limitation, and that other changes and modifications are possible.
| Number | Date | Country | |
|---|---|---|---|
| 63609563 | Dec 2023 | US |
