AU641930B2 - Food service system and method of rethermalizing food - Google Patents
Food service system and method of rethermalizing food Download PDFInfo
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- AU641930B2 AU641930B2 AU61489/90A AU6148990A AU641930B2 AU 641930 B2 AU641930 B2 AU 641930B2 AU 61489/90 A AU61489/90 A AU 61489/90A AU 6148990 A AU6148990 A AU 6148990A AU 641930 B2 AU641930 B2 AU 641930B2
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- heater
- heating
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D23/00—Control of temperature
- G05D23/19—Control of temperature characterised by the use of electric means
- G05D23/1906—Control of temperature characterised by the use of electric means using an analogue comparing device
- G05D23/1912—Control of temperature characterised by the use of electric means using an analogue comparing device whose output amplitude can take more than two discrete values
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- A—HUMAN NECESSITIES
- A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
- A23B—PRESERVATION OF FOODS, FOODSTUFFS OR NON-ALCOHOLIC BEVERAGES; CHEMICAL RIPENING OF FRUIT OR VEGETABLES
- A23B2/00—Preservation of foods or foodstuffs, in general
- A23B2/80—Freezing; Subsequent thawing; Cooling
- A23B2/82—Thawing subsequent to freezing
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- A—HUMAN NECESSITIES
- A47—FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
- A47J—KITCHEN EQUIPMENT; COFFEE MILLS; SPICE MILLS; APPARATUS FOR MAKING BEVERAGES
- A47J39/00—Heat-insulated warming chambers; Cupboards with heating arrangements for warming kitchen utensils
- A47J39/006—Heat-insulated warming chambers; Cupboards with heating arrangements for warming kitchen utensils for either storing and preparing or for preparing food on serving trays, e.g. heating, thawing, preserving
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65D—CONTAINERS FOR STORAGE OR TRANSPORT OF ARTICLES OR MATERIALS, e.g. BAGS, BARRELS, BOTTLES, BOXES, CANS, CARTONS, CRATES, DRUMS, JARS, TANKS, HOPPERS, FORWARDING CONTAINERS; ACCESSORIES, CLOSURES, OR FITTINGS THEREFOR; PACKAGING ELEMENTS; PACKAGES
- B65D81/00—Containers, packaging elements, or packages, for contents presenting particular transport or storage problems, or adapted to be used for non-packaging purposes after removal of contents
- B65D81/38—Containers, packaging elements, or packages, for contents presenting particular transport or storage problems, or adapted to be used for non-packaging purposes after removal of contents with thermal insulation
- B65D81/3825—Containers, packaging elements, or packages, for contents presenting particular transport or storage problems, or adapted to be used for non-packaging purposes after removal of contents with thermal insulation rigid container being in the form of a box, tray or like container with one or more containers located inside the external container
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B3/00—Ohmic-resistance heating
- H05B3/68—Heating arrangements specially adapted for cooking plates or analogous hot-plates
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B3/00—Ohmic-resistance heating
- H05B3/68—Heating arrangements specially adapted for cooking plates or analogous hot-plates
- H05B3/74—Non-metallic plates, e.g. vitroceramic, ceramic or glassceramic hobs, also including power or control circuits
- H05B3/746—Protection, e.g. overheat cutoff, hot plate indicator
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- A—HUMAN NECESSITIES
- A47—FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
- A47B—TABLES; DESKS; OFFICE FURNITURE; CABINETS; DRAWERS; GENERAL DETAILS OF FURNITURE
- A47B31/00—Service or tea tables, trolleys, or wagons
- A47B2031/002—Catering trolleys
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B2213/00—Aspects relating both to resistive heating and to induction heating, covered by H05B3/00 and H05B6/00
- H05B2213/04—Heating plates with overheat protection means
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B2213/00—Aspects relating both to resistive heating and to induction heating, covered by H05B3/00 and H05B6/00
- H05B2213/07—Heating plates with temperature control means
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S165/00—Heat exchange
- Y10S165/918—Heated and cooled food cabinets and/or trays
- Y10S165/919—Wheeled
Landscapes
- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- General Physics & Mathematics (AREA)
- Automation & Control Theory (AREA)
- Physics & Mathematics (AREA)
- Food Science & Technology (AREA)
- Mechanical Engineering (AREA)
- Ceramic Engineering (AREA)
- Wood Science & Technology (AREA)
- Zoology (AREA)
- Polymers & Plastics (AREA)
- Devices For Warming Or Keeping Food Or Tableware Hot (AREA)
- Handcart (AREA)
- General Preparation And Processing Of Foods (AREA)
Description
WO 91/02481 PCT/US90/04315 -1- FOOD SIr eASYSTEM 0'TD AsytaDM TECHNICAL FIELD The present invention relates to food service systems wherein individual portions of precooked food are supported on trays within moveable carts. The carts are placed in a chilled environment to store the food in a chilled state. Selected foods on the trays are rethermalized in the cart, heated to a hot serving temperature, while other portions of food on the trays remain in the chilled state.
The rethermalization method of the present invention is directed to conductively applying heat to the selected food portions through a heating plate which is heated by a thermostatically controlled electrical heater.
BACKGROUND OF THE INVENTION Various types of food service systems and conductive heating rethermalization methods are known in the prior art. A most basic food jervice system is one hi which food is served immediately, or only a short time period, after the food is cooked or prepared. Typically in better restaurants, food is served immediately after it is cooked or prepared. Such immediate service of the food generally results in the best quality of food. In other environments such as fast food restaurants and cafeterias, food is not served immediately after preparation, but rather kept warm and served in the warm state. In fast food restaurants, food such as hamburgers is kept hot in disposable plastic containers. In cafeterias, food can be kept warm in the bulk state and served to individuals on a request basis, or food can be prepared in bulk and, thereafter, divided into individual portions and kept warm in a pellet system. A pellet system can also be used in non-cafeteria environments, such as hospitals wherein the food is c?/us 0 20. Aug. 1991 Aladdin Syne;-'etics, B 12940PCT -2placed on serving dishes and covered with insulated domes to keep the food warm until service.
A significant drawback of systems which keep Xood warm for a short period of time before service is that the time period during which the food can be kept safe and warm is relatively limited, and the quality of the food deteriorates over time.
A rethermalization system is another prior art type of food service system. In a rethermalization system, food is cooked or pre- ,.4A4 0 C. .4 pared and then chilled in bulk to 4- or less. Eventually the food is divided into individual portions and stored in a chilled state until it is reheated. The United States Food and Drug Administration (FDA) guidelines specify that the chilled and stored temperature must be 4'44C.
less. A short time before the food is to be served, the food which is to be served hot is brought to a safe serving temperature, i.e.
it is rethermalized. FDA guidelines specify that a safe serving temperature is(165OF)or greater. The present invention is directed to certain improvements in structural and functional aspects of a rethermalization system which uses conductive hdating.
One manner of classifying prior art conductive heating rethermalization systems is by the location of the heating elements within the system. That is, prior art rethermalization systems have located the heating element in either a food serving dish, a dish supporting tray, or a shelf attached within a service cart.
U.S. Patent No. 3,908,749 to Williams discloses a food service system wherein precooked foods are held on trays within a chilled environment cart. Food to be rethermalized is held within a dish which has an electrical resistance heating element embeodded in its base. Contact buttons to connect the heating element to an electrical power source extend from the bottom of the base of the dish. The dish extends through a hole in a food service tray, and when the tray is supported in the service cart, the contact buttons rest on expoed leaf contacts which extend from a rear wall of the service cart.
Embedding the electrical heating element within the dish significantly increases the cost and complexity of the dish. A dish within a food service system undergoes severe handling since it must WO 91/02481 PCT/US90/04315 -3carry food, is subjected to heat for rethermalizing the food, and thereafter is subjected to heat, chemicals and handling impact in washing and drying processes. Thus, the dish is the component of this system which must be replaced most frequently. A system which incorporates the heating element into the dish thus has a relatively high long-term operating expense. Another disadvantage of this type of food service system is that relatively large electrical contacts must remain exposed in the cart to provide the electrical connection to the contacts of the dish. Such exposed contacts are thus subject to corrosion and water damage during operation and cleaning.
Food service rethernalization systems which incorporate heating elements into the service tray have disadvantages similar to dish heating element systems. That is, the cost of the trays is relatively high and the trays are subject to breakage because of frequent handling during food service and cleaning. Exposed contacts are also required to provide electrical connection to the heating elements embedded in the trays. Another disadvantage of tray heating element systems is that the trays become warped after a period of time due to the frequent heating and cooling cycles to which the trays are subjected and their relatively large planar configuration. Once the trays become warped, good surface contact between the heating element portion of the tray and the dishes to be heated is lost. As a consequence, accurate, and possibly adequate, heat is not applied to the food during rethermalization. Examples of food service rethermalization systems which utilize trays incorporating heating elements are found in U.S. Patent Nos. 4,068,115 to Mack et al.; 4,167,983 to Seider et al. and 4,235,282 to deFilippis et al.
Food service rethermalization systems which incorporate the heating elements into shelves supported in the service cart alleviate the problem of the high cost of the more replaceable portions of the system, i.e. expensive dishes and trays. Furthermore, since the heating elements are formed as a portion of the cart, i.e. a shelf within the cart, the connection of the electrical heating elements to a power source is incorporated within enclosed portions of the shelf and cart, alleviating the problem of exposed contacts. However, VO 91/02481 PCT/US90/04315 -4rethermalization carts with shelf located heating elements do have certain limitations or disadvantages. Such systems generally incorporate a plurality of heating elements in a fixed manner into a single shelf. Thus, when one of the heating elements on a shelf becomes inoperative, the entire shelf must be replaced, rather than replacing the single inoperative heating element. Examples of food service rethermalization systems wherein the heating elements are incorporated into shelves within the service cart are found in U.S. Patent No.
4,346,756 to Dodd et al.; 4,323,110 to Rubbright et al. and 4,285,391 to Bourner.
Prior art rethermalization food service carts have one or more columns of vertically spaced storage shelves on which trays carrying dishes of food are held. Dependent upon whether the tray at a given shelf location is carrying food to be heated, the heating elements at the respective shelf locations have to be activated at an appropriate time. Power to (al of the heating elements is generally turned on manually or via an automatic timer program. However, separate activation of the individual heating elements at the shelf locations is dependent on whether or not food to be heated is present at the shelf location. One technique is to have the food service personnel activate a manual switch as the food tray is leaded on the shelf, if the tray contains food to be heated. However, such a technique is labor intensive and requires that the food service operator inspect the food on the tray or otherwise have an indication of whether food to be heated is present ot a tray being placed onto the shelf.
Rubbright et al. '110 discloses a programmable system for activating heating elements at various shelf locations. In this system, a transport modular pack is programmed to have each heater element follow a particular and independent time/temperature curve dependent upon the food to be heated at the particular shelf location. This technique is very complicated and labor intensive, and requires special care and attentiveness by a skilled operator, since a specific time/temperature curve must be programmed by the operator into the rr ritilar nrnk fnr enre% Incdririi' rr an WO 91/02481 PCT/US90/04315 Another prior art technique for activating the individual heating elements at the shelf locations relies upon tray positioning. In Seider et al. '983, electrical heater contacts on the dishes mate with projecting electrical power contacts at the shelf locations when the tray is positioned in one direction, but do not make electrical contact when the tray is positioned in the 1800 opposite direction. In Bourner '391, a mechanical switch is placed at each shelf location and is activated by a tray cover when the tray is positioned in one direction, but is not activated when the tray is positioned in the 1800 opposite direction, because of a cut out formed in the cover. Again, care must be taken by the food service operator in positioning the trays within the shelves. Frequently the loading of the shelves with the trays occurs at a separate location, or is attended to by a different person, from the loading of the food onto the tray. Thus, miscommunication or misunderstanding as to the food located on the tray can result in incorrect positioning of the tray.
Electrical conductive heaters in prior art rethermalization systems and rethermalization methods using such heaters have exhibited certain limitations or drawbacks in the manner in which the food is rethermalized. Most typically, a rethermalization system utilizes a resistance heater, which operates intermittently at a single power level during rethermalization, i.e. during the time when the food is initially brought from the chilled state to a serving temperature. The resistance heater is controlled by an on-off thermostat which operates between upper and lower temperature of limits. Typically, the resistance heater applies heat over a predetermined time period.
While such a heating method has worked satisfactory, it is subject to certain limitations. For examp'e, the system must be designed to work within a practical time period. While it would be desirable from a labor/cost standpoint to rethermalize chilled food as quickly as possible, it is difficult to achieve high quality food when rethermalization occurs too quickly. For example, certain portions of food may become scorched while others remain cold, or the food may become dehydrated or discolored when rethermalization occurs too rapidly.
WO 91/02481 PCT/US90/04315 -6- One commercial rethermalization system accomplishes rethermalization of food in approximately one quarter of an hour.
However, the range or variety of food which can be rethermalized is limited and special plating techniques are required for many of the lighter or more fragile foods. The term "plating techniques" refers to the special way or manner in which certain foods, which are to be rethermalized, are placed on dishware to assure that the foods retain their quality after rethermalization. Plating techniques are most frequently used with light and fragile foods. Examples of plating techniques include supporting food on a dish within a dish or on toast, adding gravy or water to the food, or spraying the dishes with a nonstick coating. Thus, while the time during which rethermalization takes place is less, any operating expense savings is very likely lost by the added expense is required in the special plating techniques.
Conversely, when the time for rethermalization is significantly increased, for example, to one hour as suggested in Williams '749 for an entree of a meat and one or two vegetables, the need for special plating techniques is reduced and a wider variety of food can be rethermalized. However, a one hour rethermalization time period can be too long when three meals per day must be prepared in typical institutional environments such as hospitals, prisons or nursing homes since scheduling options for handling and recycling the carts for the next meal are limited.
The system disclosed in Bourner '391 rethermalizes chilled food in approximately a one-half hour time period. Such a rethermalization time period has proven to be a satisfactory compromise, That is, a relatively wide variety of food ca>" be rethermalized without the requirement of using special plating techniques. Furthermore, the one-half hour time period has not proven to be too restrictive on service personnel, allowing sufficient time for preparation and service of three meals per day in an institutional environment.
Nevertheless, even the system disclosed in Bourner '391 has certain limitations. For example, an unrestricted range of foods cannot be rethermalized without special plating or quality degradation.
It is difficult to rethermalize small portions of low density, fragile WO 91/02481 PCT/US90/04315 -7foods, while retaining high quality of the foods and at the same time rethermalize large portions of high density, difficult to heat foods within the same time period. It is believed that on of the causes of this limitation is that the thermostat which controls the heater must operate at a relatively high temperature range in order to sufficiently heat the more difficult to rethermalize food, and that at such higher temperature ranges, the easier to heat foods become overcooked.
A system which utilizes a resistance heater at a single power rating also has proven unforgiving when certain set parameters are varied. For example, if portion sizes are varied too much from specified portions, quality of the reheated food deteriorates. This is particularly true if too much of a dense ftod is placed in combination with too little of a fragile, low density food. Such a system is also very voltage dependent. Thus, if the voltage supplied to the heating elements drops significantly below the norm, for example more than insufficient power may be supplied by the heating elements to heat the higher density, more difficult to heat foods. Similarly, if the voltage supplied to the heating elements increases excessively, for example 10%, excessive heat may be supplied to the more fragile foods causing deterioration in the quality of these foods.
The system in Dodd et al. '756 uses a separate low power holding circuit for keeping food warm after it has been rethermalized. A higher power primary heating circuit is thermostatically controlled and used to rethermalize the food over a predetermined time period.
Thus, while this system uses separate heaters having different power ratings, only the higher power heater is used for rethermalization, while the lower power heater is used primarily to keep the already rethermalized food warm. A switch is used to select between the two heating optionl.
The system in Mack et al. '115 uses PTC power heaters as the preferred type of heater embedded in the dish. The use of a resistance heater controlled by a thermostat is mentioned as an alternative to the PTC heater. The PTC heaters operate basically as multimodal resistance heaters so that below their critical temperature they have a low electrica resistance, while above it the resistance is very WO 91/02481 PCT/US90/04315 -8high. Near the critical temperature, the resistance varies between the extremes. Therefore, depending upon temperature a PTC heater will Odetver different wattages. During the development of the present system, it was found that PTC heaters had both structural and functional disadvantages. The heaters initially draw very high current, requiring more expensive high power capability electrical service. Also, if the initial input temperature of the food varied from preset standards, the heaters would not adequately heat the food to proper serving temperature.
The Rubbright et al, '110 system programs an individual time/temperature curve for each heater element. A predetermined time period is not used for all of the types of foods to be rethermalized. Rather, a particular time/temperature curve is used to control heater temperature and time independently for each heating element depending upon the type of food being rethermalized. A certain number of programs are available for use and are coordinated with various types or combinations of foods. The food service operator thus must coordinate the particular food or combination of foods with the appropriate program. The food service handling process is thus complicated, rnquiriog extra care and attention during meal preparation and specil training for the operators of the system.
The food service system and method of rethermalization of the present invention was developed too -the structural and functional limitations of the prior art systems and methods discussed above.
$UMMARY OF THE INVENTION The present invention is directed to a heating system for use in a food service cart for storing and heating foods. The system includes a plurality of vertically spaced tray supports attached to the cart for supporting food service trays at a plurality of vertically spaced shelf locations, and a plurality of heaters attached to the cart at a plurality of vertically spaced locations in alignment with the shelf locations for heating foods carried on service trays and supported by the tray supports. A mechanism initiates the supply of power to the heaters and a timer turns the power off to the heaters after a predetermined time WO 91/02481 PCT/US90/04315 -9period has elapsed. A thermostatic control controls the power supplied by each respective heater during the predetermined time period.
The control includes a sensing device for sensing temperature and a power adjusting device for adjusting the power supplied by the heater.
The sensing device senses temperature over a predetermined range having upper and lower temperature limits, and the power adjusting device reduces the power at i.hioh the heater operates to a lower power level when the sensing device senses the upper temperature limit and increases the power at which the heater operates to a higher power level above the lower power level when the sensing device senses temperature at or below the lower temperature limit.
The present invention is also directed to a heater module per se which incorporates the heater and thermostatic control.
In a preferred embodiment, each heater includes an electrical heating element, and the power adjusting device includes a switch which shorts a portion of the heating element out of the operative heater circuit to operate the heater at the increased power level, and which places the portion of the heating element into the operative heater circuit to operate the heater at the reduced power level.
Another aspect of the present invention is directed to a method of heating precooked food stored at a plurality of locations within a food service cart. According to the method, a preselected amount of food to be heated is supported adjacent an individual heater, and heat is supplied to ti~s food from the heater over a predetermined time period in a thermostatically controlled manner as follows: Heat is initially supplied at a high power level from the beginning of the predetermined time period; and thereafter reduced to a low power level lower than the high power level when an upper temperature of a temperature range of the thermostatic control is reached. The heater operates at the low power level until a lower temperature of the temperature range is reached and then increases to a higher power level above the low power level. The heat is again reduced to a low power level lower than the higher power level when the upper temperature of the temperature range is reached; and the steps of reducing and increasing the power are continuously WO 91/02481 PCT/US90/04315 performed over the predetermined time period to continuously supply heat from the heater to the food during the predetermined time period.
Another aspect of the present method relates to selecting a range of foods with various heat energy requirements to be rethermnalized; and to selecting of an appropriate rethermalization time period and low and high power levels which will satisfactorily rethermalize the range of foods.
The terms two-stage heater and two-stage method of rethermalization will be used herein as shorthand terminology for the heater and thermostatic control which supplies power continuously during the rethermalization time either at a high power level or at a low power level, and to the method of rethermalization 1sing the application of heat at the high and low power levels. The two-stage heater and method of rethermalization overcomes, to a degree, certain food processing limitations of a single-stage rethermalization heater (the on-off operation of a single-power heater). For example, foods with a broader range of heat energy requirements can be rethermalized with the two-stage heater without degrading food qualicy. As a corollary, less special plating techniques are required for the lower density, fragile foods. Also, a mixture of high energy requirement and low energy requirement foods can be more readily rethermalized simultaneously using the two-stage heatr. Such mixed rethermalization with the two-stage heater works particularly well with round dishes which both are aesthetically pleasing and allow freedom to vary portion sizes of one, two, or three foods.
The two-stage heater system and method is also more forgiving in various respects over a single-stage rethermalization heater system and method. That is, accurate portion sizes are not as critical when the two-stage heater and method is used. Similarly, variations in the voltage applied to the heaters does not as readily affect the quality of the rethermalized food.
Another advantage of the two-stage heater and method is that a lower and narrower thermostat range can be used within the predetermined rethermalization time period. When a lower and more WO 91/02481 PCT/US90/04315 11accurate thermostat range is used, there is less chance that the food will become scorched, or that the more fragile foods will have their quality degraded. Also, excess power is not used when meals consisting primarily of light, fragile foods reach the desired serving temperature.
Another aspect of the present invention is directed to a system for selectively activating individual heaters in a food service cart.
An individual switch mechanism is connected to each of the heaters for turning power on and off separately to each one of the heaters. A switch activator mechanism activates the switch mechanism, and is associated with covers for hot food to be carried on the service trays whereby one of the switch mechanisms turns power on to a respective one of the heaters when one of the covers is carried by a tray and supported in the cart above the last-mentioned switch mechanism. In one embodiment, the switch mechanism includes a pivotable housing, a magnet supported at one end of the housing and a mercury switch activated and carried by the pivotable housing. A preferred form of switch activator mechanism is a ring of magnetic material supported in the base of the food cover.
The system which uses an individual switch mechanism connected to each heater in combination with a switch activator mechanism carried in the covers for hot food simplifies the process of activating the individual heaters, as well as reduces the likelihood of error in activating the heaters. As food is placed on dishware, it is common practice to place a cover over food which is intended to be hot. The present system accomplishes individual heater activation by this simple one-step process. The step of manually, and individually, activating a switch for each shelf location, programming a control module for each meal, or properly orientating trays within a service cart is thereby eliminated.
A further aspect of the present invention is directed to a heater module for use in a food service cart wherein a heating element housing is removably attached to the cart at a shelf location. A heater plate sized to contact one food carrying member, and at least one electrical heating element are carried in the heating element WO 91/02481 PCT/US90/04315 12housing with the heating element in thermal contact with the heater plate. The heating element housing includes a mechanism for removably attaching the housing to the cart whereby the heating element for a respective heater plate is individually removable from the cart by removing the heating element housing. The heating element housing preferably has a pair of openings for receiving a pair of support pins extending from a support beam in the cart. Repair, replacement and cleaning of heating elements and heaters is simplified by the present heater module since each individual heater can be removed separately. In prior art shelf-mounted heaters, a plurality of heaters was fixedly attached to each shelf location so that individual replacement and repair of the heaters could not be accomplished.
Various advantages and features of novelty which characterize the invention are pointed out with particularity in the claims annexed hereto and forming a part hereof. However, for a better understanding of the invention, its advantages, and objects obtained by its use, reference should be made to the drawings which form a further part hereof and to the accompanying descriptive matter, in which there is illustrated and described preferred embodiments of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view of a food service system including a mobile food service cart and a refrigeration cabinet; Figure 2 is a partial rear view of the food service cart; Figure 3 is a horizontal sectional view of the food service cart, illustrating one food tray supported at a shelf location and another food tray in the process of being inserted into a shelf; Figure 4 is a partial front elevational view illustrating trays, dishware, and covers supported at shell' locations with one overall cover partially broken away; Figure 5 is a partial sectional view illustrating dishware supported on a heater; Figure 6 is a partial side elevational view with the side wall of the service cart removed and illustrating food trays and covers supported at horizontally spaced shelf locations; WO 91/02481 PCI/US90/04315 13 Figure 7 is a top plan view of a heater module with selected internal details shown in dash line; Figure 8 is a cross sectional view taken generally along line 8-8 of Figure 7 with a portion of a tray and cover illustrated above the heater module; Figure 9 is a top plan view of a generally T-shaped heater element support bar; Figure 10 is a front view of the support bar; Figure 11 is a cross-sectional view taken generally along line 11-11 of Figure 9; Figure 12 is a plan view of a cover plate for the support bar; Figure 13 is a front elevational view of a heater module; Figure 14 is a rear elevational view of the heater module; Figure 15 is a cross-sectional view taken along line 15-15 of Figure 7; Figure 16 is a partial exploded perspective view of a heater module, tray and cover, illustrating a pivoting switch; Figure 17 is a plan view of a smaller heater module; Figure 18 is a plan view of an attachment plate of the module of Figure 17; Figure 19 is a partial exploded perspective view of a heater module, illustrating an alternate switch mechanism; Figure 20 is a diagrammatic view of the resistance pattern of one embodiment of a heater element; Figure 21 is a diagrammatic view of the resistance pattern of another heater element; Figure 22 is circuit diagram of one embodiment of a two-stage heater and heater control; Figure 23 is a circuit diagram of another embodiment of a two-stage heater andr heater control; Figure 24 is a circuit diagram of a further embodiment of a two-stage heatsr and heater control; and Figure 25 is a graph illustrating a theoretical comparison between a two-stage heater in accordance with the present invention and a single-stage heater.
?CT/USO/04315 Aladdin Synergetics, Inc. B I?9OPCT 14- DETAILED DESCRIPTION Food Service System Referring to the drawings, wherein like numerals indicate like elements, there is illustrated a food service system indicated generally as 10. Food service system 10 includes a mobile food service cart 12' which functions as a rethermalization and service cart, and a refrigeration cabinet 14. lool-o or Cart 12 is formed generally of sheet metal and includes aLsupport base 16. A first pair of wheels 18 depend from one of tne sides of base 16 and a second pair of steerable and lockable wheels depend from its other side. A first side wall 22 extends upwardly from a first side of base 16 and a second side wall 24 extends upwardly from a second side of base 16. A top wall 26 is connected to and extends between the upper ends of first and second side walls 22 and 24. Tubular members 25 (one of which is shown along the front edge of cart 12 in Figure 1) are attached to the front and back edges of each side wall 22 and 24; and generally U-shaped tubular members 27 are attached to and connected between top wall 26 and side walls 22 and 24, and base 16 and side walls 22 and 24, along the front and back edges of cart 12. Tubular members 25, 27 provide additional rigidity to cart 12. A handle 28 is attached to the exterior of side wall 24, and is used to move and steer cart 12. The front and back of cart 12 are open to allow free access for the insertion and removal of food service trays 30. Male electrical connector contacts 32, which connect cart 12 to an electrical power source, extend from base 16 immediately below side wall 22.
In use cart 12 is loaded with trays 30, which in turn support precooked or otherwise prepared food. Thereafter, cart 12 is wheeled into refrigeration cabinet 14 where it will be stored in a chilled state until rethermalization. Refrigeration cabinet 14 includes a front access door 34 to allow entry and removal of cart 12, and which seals the refrigeration cabinet. A female electrical receptacle 36 Is attached to the interior back wall of cabinet 14. When cart 12 is backed completely into cabinet 14, contacts 32 engage receptacle 36 to thereby connect cart 12 to a main electrical power supply in a WO 91/02481 PCT/US90/04315 conventional manner. Electrical power to receptacle 36, and, hence, cart 12 can be initiated manually through switch 31, or switch 31 can be programmed to turn power on at a preselected time. A conventional timer 33 is also provided to control the amount of time that power is supplied to the cart.
If cart 12 is to be used in a centralized rethermalization system, cabinet 14 can be replaced by a refrigerator room wherein a plurality of spaces and electrical receptacles are provided for a plurality of carts 12, and the entire room is refrigerated.
Food Service Tray and Dishware As seen in Figure R, a pair of support bars 38 are attached to the inside surfaces of sire walls 22 and 24 at both the front and back of cart 12. At a given horizontal location, support bars 38 define a front and a back shelf location to support a pair of trays Support bars 38 are preferably formed of a rigid plastic. As seen in Figure 4, support bars 38 have a generally T-shaped cross-section with pins 40 formed integral with the top section of the T. Pins 40 extend through apertures in side walls 22 and 24 to thereby secure support bars 38 to side walls 22 and 24. An alignment and locking )rojectilon 39 extends from the top surface of support bars 38.
Projection 39 mates with a slot 41 along the bottom edge of tray 30 to hold tray 30 in position.
Tray 30 has a generally rectangular configuration with an upstanding peripheral rim 42, which extends upward from a support surface 44. A divider 46 also extends upward from the support surface 44 and divides surface 44 into a food holding area and a utensil/napkin holding area. In the food holding area a round large entree opening 48, and a round small soup opening 50, are formed. A rim 49 extends upward from surface 44 and around the periphery of opening 48. A rim 51 extends upward from surface 44 and around opening 50. As seen ,n Figure 4, an entree dish 52 fits within entree openirr 48 and a soup bowl 54 fits within soup opening 50. Entree dish andl soup bowl 54 both have a conventional round shape. As see ,n Figure 6, the diameter of dish 52 increases slightly from its smallest diameter along its bottom surface, and is correlated to the PCT/UJS00/i4315 Aladdin Synergetics, Inc. i9Y40PCf 16" diameter of opening 48 such that the bottom surface of dish 52 extends down slightly below the lower surface of tray 30, and the side and upper rim of dish 52 are out of contact with rim 49 of tray The diameter of soup bowl 54 is likewise correlated to the diameter of opening Entree dish 52 and soup bowl 54 are designed to be capable of selrv'l- a P -ooA., Ca1r<^'; es io r holding hot foodsL An isulated entree cover 56 is therefore provided to cover dish 52 and food held on the dish; and an insulated soup cover 58 is provided to extend over and cover soup bowl 54. A disposable lid is also placed directly on top of soup bowl 54. The diameter of cover 56 is greater than the diameter of dish 52 and slightly greater than the outside diameter of rim 48. In this manner, cover 48 is aligned over dish 52 and opening 48 so that the base of cover 56 rests on support surface 44. In a similar manner, the diameter of soup cover 48 is greater than the diameter of soup bowl 54 and rim 51.
An overall food cover 60 is provided to cover the entire food carrying area of support surface 44. Cover 60 provides protection for foods, other than hot food covered by covers 56 and 58 which are supported in the food service area 44 of tray 30. The utensil/napkin support area remains open so that utensils, napkins, menu and patient identification can be placed on the tray after all the food has been placed on tray 30 and covered. Covers 56 and 58 are insulated covers preferably formed of an outer hard plistic shell filled with an insulation material as seen in Figures 8 and 16. Cover 60 is preferably formed of a rigid injection molded plastic.
Heating System pad As seen in Figure 3, a pair of large entree heater assemblies or O'eta.Ver) pakS I r odules.
64 and a pair of small soup heater assembliesLor modules 66 are located at each horizontal shelf location.,, Figures 9, 10, 11 and 12 illustrate the support structure for supporting heater modules 64 and 66 at the horizontal shelf locations. As seen therein, a generally 2su pe bagr orJ 1oea.v, T-shapedbar 68 extends between opposite side walls 22 and 24. T-bar 68 is preferably formed of a high strength aluminum material and includes a central rib 70, a cross member 72 which extends perpendicularly from opposite sides of rib 70, and a pair of wall members 74.
PCT/US90/04315 Aladdin Synergetics, IrAl ,i 12940PCT -17- Wall members 74 extend perpendicularly away from opposite distal ends of cross member 72 so that a hollow open-ended rectangular area is defined between cross member 72 and wall members 74. A base cover 76 fits within the hollow area and covers the open end between walls 74. Wiring, shown diagrammatically as 73, extends through the hollow area to connect the heater modules to a main power source through contacts 32. A plurality of notches 80 are formed in the interior of wail member 74, and projections or clips 82 extend from an upper surface of cover 76 and fit within notches 80 to secure base cover 76 in place.
A plastic end piece 84 is located at each end of bar 68 and disposed between a respective end of bar 68 and one of the walls 22, 24.
Each end piece 84 has a small cross section portion 86 which frictionally fits into the hollow interior of bar 68, and an exterior portion 88 which fits between the interior surface of the wall members 22 and 24 and the distal ends of bar 68. Exterior portion 88 has a curved exterior surface.
Bar 68, base cover 76 and end pieces 84 "re secured to walls 22 and 24, preferably by screws, one of which 81 is shown in dash-line in Figure 9, extending through the walls and into end pieces 84. Four support pins 9L oxtend from each longitudinal edge of bars 68. Each pin 90 is attached to bar 68 in a conventional manner, preferably by screw threads. Pins 90 have a large diameter base portion 92 and a small diameter distal portion 94. A friction member, such as an 0-ring 96, is secured to the distal end of base portion 92. Pins function to support heater modules 64 and 66 in a cantilever manner or oe^i-.4 from bar 68. As seen in Figure 7, a cylindrical bore 98 is formed through the hoising of heater module 64 adjacent each of its sides.
Similar bores Lre fortfied in heater module 66. Pairs of pins 90 fit within bores 8 to support the heater nodules. In this manner, heater modules 64 and 66 are supported at a plurality of vertically spaced shelf locations The pin 90 and bore 98 connection and suppo't technique allows each ind:vidual heater module, which is sized to heat a single dish or bowl, to be individually removed for service or replacement.
4io p 0 A .L a LOa o, oreO'. f cl 8 C O0^ IU' r I oaL(e a I- I@cL. PCT/US9IO/O435 Aladdin Synergetics, Inc. 12940PCT 18 Details of heater module 64 are best seen in Figures 7, 8 and 13-15. Heater module 66, except where noted otherwise particJlarly with reference to Figures 17 and 18, is constructed similar to heater module 64. The exterior of heater module 64 is defined by a plastic housing 100, a metal heater plate 102, a plastic switch attachment plate 104 and a rubber or plastic gasket 106. The components which are held within the interior of heater module 64 include a resistive electrical heating element 108, an insulation plate 110, a thermostat A a C 0 WN i 3a 112, a fuse 114, a pivot switch mechanism 116, and ndicator Light 118.
Housing 100 is formed of a relatively rigid, high temperature resistant, injection molded thermoplastic. Housing 100 includes a bottom or base 120 and a peripheral wall 122 extending upward from bottom 120 about the periphery of housing 100. Peripheral wall 122 has a tapered or slanted top and bottom exterior surface along the front and sides of housing 100. The slanted top surface, along the front of housing 100, assists in guiding a dish into position on top of the heater. A round opening 124 is formed in peripheral wall 122 and includes a support ledge 126.
Heater plate 102 is preferably formed of a nickel plated aluminum plate having a thickness of approximately Plate 102 is generally round and has a circular perimeter generally mating with the configuration of round opening 124. A plurality of support legs 128 extend downward at a plurality of locations about the perimeter of heater plate 102. A resistive heating element 108, such as shown in Figure 20, is secured to the bottom of heater plate 102.
Element 108 is preferably formed of a resistance foil in the pattern illustrated in Figure 20. The foil is encased in a silicon rubber and is attached to plate 102 during vulcanization of the rubber by the applicatkia of heat and pressure. Plate 110, formed of an insulative material, such as a ceramic fiber or the like, is thereafter secured in position below heating element 108 by resting on top of ledge 126.
Thermostat 112 is secured with an adhesive directly to the bottom of heater plate 102 within a centrally located opening in heating element 108. Heater plate 102 and the components secured to it are 4315 Aladdin Synergetics, Inc. s 2940PCT -19attached to housing 100 by securing legs 128 within holes t-i-formed within housing 100 adjacent peripheral wall 122. The border between 1o2.
heater plate l and opening 124 is sealed with a room temperature vulcanized silicon rubber to prevent entry of liquid into the hterior of the housing.
Switch attachment plate 104 has a generally triangular configuration as seen in Figure 7. A mating support ledge, which follows the peripheral contour of plate 104, is formed in the bottom of housing 100 and, as seen partially in Figure 14, plate 104 fits on the support ledge. Plate 14 is permanently secured to the support ledge by either an adhesive or welding, preferably by sonic welding. The interior of housing 100 is thus hermetically sealed, allowing heater 64 to ce cleaned in a pressure washing process. Plate 104 supports pivot switch mechanism.116, which functions to individually activate heating element 108 in each respective heater assembly. Pivot switch mechanism 116 includes an L-shaped housing 130 with a magnet 132 Carried in one open erd of housing 130, and a mercury switch received within an opening in the other end of housing 130. A pair of support flanges 136 extend upward from the interior of plate 104 to pivotally support housing 130 via a support pin 138 passing through holes in flanges 136 and housing 130.
In the deactivated state of switch 116, the end of housing 130 which carries magnet 132 is pivoted downward and the opposite end carrying mercury switch 134 is pivoted upward. In this position mercury switch 134 is in its open state and power Is not supplied to heating element 108. Switch 116 is activated by placing an insulated cover 56 over a dish of food to be rethermalized. As seen in Figures 8 of sv% eL ar-;varo, es and 16, an annular ring,140 of a magnetic metallic material is held within the perimeter of cover 56 adjacent its base. As seen in Figure 8, with tray 30 and cover 56 in position, magnet 132 is drawn upward toward metallic ringA140 and mercury switch 134 pivots downward to be placed in its closed state. Activation of an appropriate heater module is thus readily assured, since whenever an insulated cover is placed over food to be heated, the heater module is automatically activated. A cylindrical projection 142 is formed integral with the L'TL,,v, a av- V 140 aL .e-c r. J 1 PCT/US90/04315 Aladdin Synegrstics, InIc. P 12940PCT upper surface of housing 100 to receive magnet 132 and allow sufficient upward pivoting to activate mercury switch 134. A pair of electrical connector pins 144 are supported by a pair of spaced flanges 148 formed on plate 140 in a hermetically sealed manner. Pins 144 connect to a main power supply bypassing through holes 150 in the side T-bar 68 and connecting to electrical wiring 74 supported within the hollow interior of T-bar 68.
Figures 17 and 18 illustrate details of small heater module 66.
As seen therein, attachment plate 108' differs in configuration from attachment plate 108 used in module 64. Attachment plate 108' extends across the entire back of module 66 and has the configuration of two triangles connected by a central strip. Switch 116 is supported on flanges 136' on one of the triangles, and connector pins 144 extend from flanges 148' the other triangle. Otherwise, module 66 is constructed similar to module 64.
Figure 19 illustrates an 'alternate embodiment of a switch mechanism 116A in which pivotable housing 130, magnet 132 and mercury switch 134 is replaced by a reed switch 134A. Magnetic ring 140 in cover 56 is replaced by a magnet 140A located in a small area along the base of cover 56. In order to properly align magnet 140A with reed switch 134A, a projection 49A is formed adjacent rim 49 on tray 30 and cooperates with a mating recess 57 formed in the interior surface of cover 56. This embodiment of switch mechanism and activating mechanrnm is a secondary embodiment and should be used only in environments where persons or patients with heart pacemakers are not present, since magnet 140A within cover 56 could interfere with the operation of the pacemakers.
Figure 20 illustrates the resistance pattern of heating element 198 of heater assembly 64, and Figure 22 is a circuit diagram illustrating the manner in which power is supplied through heating element 108 to accomplish two-stage heating. Two-stage heating refers to the fact that in one stage the heater operates at a high power level and in another stage operates at a lowerpower.level. The resistance pattern shown in Figure 20 has a generally circular perimeter and is sized and PCT/US9C/04315 Aladdi.- Synergetics, Inc. -21-!SCC" arranged to cover substantially all of the bottom surface of heater plate 102.
As seen in Figure 22, power is supplied to resistive elements A, B and C of heating element 108 when mercury switch 116 is closed.
(ac' f' a cc. 'naS) When thermostat :112 is open, current passes through all 3 resistive elements A, B and C and provides heat at a first power lvel. However, when thermostat 112 is closed, current is shunted past resistive element A and only.passes through resistive elements B and C, C being a low voltage,indicator light circuit. In this state, heat is supplied at a higher power level since the current passes through a lower resistance (B Thus, during a rethermalization time period (the time period during which timer 33 supplies electrical power),'power is always supplied to the food being rethermalized.
Details of the rethermalization will be discussed in greater detail in the discussion of the rethermalization method. However briefly, when food to be rethermalized is in its cold state and power is initially supplied to heater element 108, thermostat 112 is In its closed state so that heat is initially supplied at high power through resistive elements B and C. When the thermostat reaches its upper limit, it opens, so that current flows through all three resistive elements A, B and C at lower power. Thereafter, when the thermostat reaches its lower temperature limit it again closes to short current from resistive element A, and again supply heat at the high power level. Thus, throughout the rethermalization period heat is actively supplied to the food being rethermalized, but at varying power levels.
As seen; rn Figure 20, the higher resistance of resistive element A is accomplished by a plurality of parallel resistance elements connected..at connection points 1 and 2, which are also shown in Figure 22. In Figure 21, which illustrates an alternate heating element 108 for use in the smaller soup heater module 66, the higher resistance of resistive element A is accomplished by using a smaller resistance element connected at connection points I and 2.
Figure 23 illustrates an alternate embodiment of heater element and control circuit arrangement which also accomplishes twostage heating. In this embodiment, a first resistive heating element 4< ;Z-2.4 llu-,l- r .el Co4t,. c- -v ffl;, *%I I S:rereics c. a A' is connected in parallel to a second resistive heating element B'.
Thermostat 112' controls the passage of current through elements A' and B' so that current passes through both elements in the high power mode of operation and through only element A' in the low power mode of operation. The resistance of element B' is preferably higher than the resistance of element A' so that in the low power mode of operation, the power is proportiohal relatively low, e.g. 25% of the total power when current passes through both elements A' and Element C' can also tJ included for an indicator light.
Figure 24 illustrates another embodiment of heater element and control circuit arrangement which also accomplishes t'o-stage heating. In this embodiment, a first resistive heating element A" is also connected in parallel to a second resistive heating element B".
However, thermostat 112" alternately supplies curren.t to elements A" and The resistance of elements A" and B" is selected so that wheii current passes through element A" the heater operates at a high power level, and when current passes through element E" the heater operates at a lower power level. Element C" can also be included for an indicator light.
Rethermalization Method FoCid service system 10, and in partiular the two stage heating elements 108, 108' are particularly useful in a method of rethermalizing chilled, precooked food. The food is stored at the plurality of shelf locations within food service cart 12. Within cart 12, a preselected amount of food to be heated is supported adjacent each indivdtual heater 64, 66. Generally, t;le total food portion for an entree can vary from(3-14 ounces) with the entree including one, two or three different foods. Similarly, the food to be heated by the soup ro soup, cereal, hot des- '-A heater element can vary from(3 to 6 ounces) o soup, cereal, hot desserts, rolls or other liquids. The use of the two-stage heater in accordance with the present invention is particularly advantageous for re thermalizing entrees, and more particularly entrees which vary in tLeir range of heat requirements. Entree foods generally include meat, fish, poultry, casseroles, starches and vegetables.
PCT/US90/04315 Aladdin Synergetics, Inc. B. 12940PCT 23 The two-stage heater applies heat to the food over a predetermined time period as set by timer^33. For example, the predetermined time period can range from 30-45 minutes, with 36 minutes being the preferred time. The heat is supplied by tle heater in a thermostatically controlled manner as follows: 1) Heat is initially supplied from the heater at a high power level from the beginning of the predetermined time period; 2) The heat from the heater is reduced to a lower power level, lower than the higher power level when an upper temperature of a temperature range of the thermostatic control is reached; 3) The heater operates at the low power level until a lower temperature of the temperature range is reached, and then increased to a higher power level above a low power level; 4) The heat from the heater is reduced to a low power level, lower than the higher power level, when the upper tempe,'ature of the temperature range is reached; and steps 3 and 4 are cyclically' performed over the precetermined time period to continuously supply heat from the heater to the food during the predetermined time period.
Turning to Figure 25, the two-stage application of heat in a r:chermalization method in accordance with the present invention is compared to the application of heat in a prior art one-stage rethermalization method. In this prior art method heat is supplied by a single power heater which is cyclically turned on and off over the predetermined rethermalization time period. The graph is a theoretical graph and assumes that: the total power of th~a prior art heater is the same as the high power level of the heater used in the present..method; all heaters operate between the same thermostat limits; and the same food portion, an average entree portion, is being heated. The graph illustrates the temperature sensed by a thermostat coupled to the bottom of the heater plate.
As seen in the graph, both systems initially supply heat to the system at the same rate. After the upper temperature of the thermo- Static temperature range is reached, the prior art system completely shuts off its single power heater, while the present system continues PeT/W(300/ .43 Aladdin Synergetics, thc, 1?940P.GT -24 to apply heat through a low power heater. Thus, as seen in the graph, the temperature sensed by the thermostat decreases more rapidly in the. prior art system than the temperature sensed in the present system. As a result, over a typical rethermalization time period, the prior art system must cycle its heater on more frequently than the high power heater of the present system is cycled on. The chances of scorching of food being rethermalized occurs during the temperature peaks, so that there are more opportunities to scorch the food in the prior art system. This scorching danger is actually greater in typical prior art systems which operate at higher temperature ranges than illustrated in the theoretical graph shown in Figure 25. For example, as will be discussed hereinafter, the method of the present invention operates the heaters within a thermostatic temperature 104'C aA. I°C 0 -a C.
range between(220 F and 235 0 F 5 F) whereas a typical prior art heater operating over the same predetermined time period would IIs8". Al 1'3 C operate between.245 0 F and 270aF). Prior art systems, which rethermalize in even shorter time periods, operate at even higher 17-10C L e04eC. t thermostatic ranges, e.g(350°F to 4000F).
The present heating method also is directed to the manner of refining or adapting the two-stage heating method to a broad range of food types to be rethermalized. In order to accomplish this objective, the qualities of the foods, which determine the degree of heating the foods require, had to be classified or organized. The following chart A, lists the various food qualities or parameters which render the foods difficult or easy to heat, i.e. foods having either a high heat energy requirement or a low heat energy requirement.
As seen in Chart A, the food qualities which would determine whether a particulsr food is difficult or easy to heat include food density, portion size, configuration, moisture content, specific heat, and fragility. The variance of the Supply voltage also affects the ability of the heater tc heat the food, Food density refers to mass per unit volume of the food, with the higher density food being more difficult to heat than the lower density foods. Larger portions of food, for exampe (six ounces or more, are more difficult to heat than smaller portions of food, for PCT/U$90/I315 Aladdin Syner'getics, Inc. 1?940PCI example to 3 ounces). The configuration of tr:e fod, in particular, the amount of surface area of the food which contacts the heating plate determines the ease with which a food can be heated. Flat food with relatively large surface area in contact with the heating plate is much easier to heat than unflat food which has very low surface contact with the heating plate. Moisture content also affects the ease with which the food can be heated, with the higher moisture content food, e.g. 70-75 percent liquid being easier to heat due to steaming than the foods with less moisture content, e.g. 38-75 percent liquid content. Specific heat also is a contributing factor to whether the food is difficult or easy to heat with foods of high specific heat, e.g. 0.85 to 0.95, being generally more difficult to heat than foods with low specific heat, e.g. 0.65 to 0.80. Fragility of food refers to whether a particular food can sustain its integrity and quality, e.g. not dry out or lose its color or texture, when it undergoes heating. Foods such as meatloaf, casseroles, lasagna and salisbury 'steaks are relatively sturdy and thus can undergo high energy heating, while such foods as poached eggs, omelets, rice, baked fish, pancakes and rare steaks are fragile and cannot undergo high intensity heating.
To arrive.at the powver settings and thermostat operating range to be used in the two-stage heating rethermalization method, extremes of foods with high energy heating requirements and foods with low energy heating requirements were first tested. Test examples are shown in the last columa of Chart A. A preferred technique for arriving at the low power and high power settings was first to determine an amount of low power which could rethermalize low energy., equirement foods, e.g.(2 ouncesof peas or 2 stacked pancakes 444 0O 60 C by raising their temperature from below 40F)to approximately(O400F) The low heat energy requirement food was not brought to the typical 75 Fc t 0 Oo t rethermalization temperature range of 475F to 210°F)wvith only the lower power heater, since the final heater wo'!d utilize the two-stage heater and, therefore, would result in an additional boosting of power over and above the use of only the low power heater.
113 10o A 10 Ik Foods with high energy heat requirement for example,'a(4 to 6 ouncesalisLtury steak wit(4 ounces)of mashed potatoes an(4 ounces PCT/US90/04315 Aladdin Synergetics, inc. 12940PCT 26 of broccoli spears were thereafter tested in the following manner: The selected low power heater was run continuously and additional power was supplied by a secondary heater at progressively higher power until the high energy heat reguirement food was adequately rethermalized from below 40 F)to above165F), The intermittent application of the additional power was controlled between predetermined thermostatic settings. Once a high power or additional power setting was determined, the combinations of low power and high power settings was tested on low heat energy requirement food to determine if the food could be adequately heated or if its quality was destroyed. Adjustments were made up and down the power scale on both the low power heater and high power heater with the power to the high power heater being decreased when the power to the low power heater was increased. Through this process, it was eventually determined that optimum power settings for the high and low power heaters was a low power setting slightly lower than the initial setting of the low power heater for low energy requirement foods and a slightly increased power setting for the high power heater over the iniial power supplied to the high heat energy requirement foods.
This test procedure was used at progressively lower thermostat range settings. That initial testing occurred at a typical higher Utf*C I. 08 UC prior art thermostatic range, e.g. between(245 F to 280 However, it was eventually determined that a thermostatic temperature range between(h215F and 240 F preferablybetween 220 F and 235 F),and power supplied at 41 watts at the low power setting and 156 watts at the high power setting accomplished the objectives of satisfactory rethermalizing entree food of both high and low energy requirements, as well as fethermalizing mixtures of low and high energy requirement of food such as shown in Chart A. Suitable power ranges for the .El y" entree heater should be approximately 35 to 45(watts)for low power and 150 to 160wvatts)for high power.
It order to establish the thermostat and oower settings for small heater module 66, a similar procedure was followed. As a RI'C ac .L \3"cresult, it was determined that a thermostat range between(240 and -24 F) -9S^ worked satisfactorily with power supplied at 10(watts)at the low N -,T/U5O0/ 04315 Aladdin Syrnergeices, 'inc. 3 12940PCT -27power setting and 46 Awatts)at the high power setting. With these power and thermostat settings, it was found that a variety of difficult to heat liquids, as wfc, as delicate, light weight rolls could be heated.
When rolls are to be heated, they can be supported on small dishes or a disposable plate or lid rather than on bowls.
In order to establish the above parameters of this method of rethermalizaton,, i.e. the range of foods to be rethermalized and the thermostat and power settings, other system constants had to be set.
For example, the thickness and size of the heater plate had to be held constant throughout the testing. It was determined that the system worked well with a nickel plated aluminum heating plate having a thickness of 1/8 of ar nch)and a diameter of approximately( inches).
The size, shape and configuration of the dish also had to be held constant. It was found that a highly conductive ceramic dish with an alumina additive to increase its convectiveness. was suitable for the rethermalization process. The preferred dish has a diameter of approximately 7 3/4")and a thickness of approximately( of an inch), In order to ensure proper heat conduction from the aluminum heater plat, to the dish, the dish should be extremely flat with very little concavity and no convex points.
The size, shape'and configuration of the bowl for the small heater also was held constant during testing. A round four inch bowl, 2"7 y lo- MI with an eight fluid ounce)capacity, and made of a high heat resistant injection molded plastic was found to be suitable. A bowl with a bOttom thickness of approximately a forty-thousandths of an inch) had the appropriate thermal conductivity. The bottom of the bowl also was kept very flat and a thin high heat resistant plastic lid was placed on top of the bowls.
SNumerous characteristics and advantages of the invention have been described in detail in the foregoing description with reference to the accompanying drailngs. However, the disclosure is illustrative only and the invention is not limited to the precise illustrated embodiments. Various changes and modifirations may be affected therein by persons skilled in the art without departing from the scope or spirit of the invention.
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PCT/US901 04315 Aladdin Synergetics, Inc.
B 12940PCT 28 In Chart A: 1 ounce 6.02835 kg Chart A Heat Requirement High Heat Requirement Size of Food Den-sity- Portion (nigh)Large (6 oz meat loaf or more) lasagna total plate potatoes weight mac cheese 10-12 oz.
chicken bone-in chkn.
oatmeal lasagna (thick) Small (1.5-3 oz.) (Low) total plate rice weight omelette 3-4 oz.
pancakes bread, rolls peas corn Configuration Unflat/low Surface Area broccoli brussel spts bk. potato mac. chs.
Flat/Large Surface Area sliced meats casseroles steaks mash. pot.
Moisture Content Low (38-75%) ham bk. chkn.
High (75-95%) spinach casseroles gravies beef broth Specif ic Heat High (.85-.95) apples potatoes Low ham chicken sausage beef Tested Fragility Voltage Ex3lnples Sturdy meatloaf casseroles lasagna sals. stk.
Fragile poached eggs omelette rice rst. beet baked fish pancakes stk (rare) 108 125 o 4-6 oz salisbury steaks, 4 oz mashed potato, 4 oz. broc sprs.
ochicken thigh, 4 oz (bone-in), 3 oz brussel sprouts, 4-5 oz" baked potato 7 oz sal. stk. 6 oz mashed pot.
2 oz carrots 0 4-6 oz oatmeal 0 4-6 oz broth 0 pched egg, t~aszt one chs. omite 2 oz, Deas or corn or rice 2 pancakes o(stacked) (stacked) Srolls Heat Requirement Mixed
C;
17 -'1 *1 Cf)
IT'
8 oz. '-&sagna (tall) 1.5 oz.
green peas whole baked pot.
2 oz. sliced roast k~et 6 oz. ment loaf, 2 oz. rice 4 oz. rice, 6 oz glazed chicken (Oriental) 8 oz. mac L. ch.
2.5 oz. broc.
6 oz. stugf ad baked flounder* 2 oz. green peas
Claims (18)
1. A food heating system comprising: a food service cart for storing and heating foods; a plurality of vertically spaced tray supports attached to said cart for supporting food service trays at a plurality of verticallv spaced shelf locations; a plurality of heaters attached to said :rt at a plurality of vertically spaced locations in alignment with the shelf locations for heating foods carried on food service trays supported by said tray supports; initiating means for initiating the supply of power to said heaters; and timer means for turning power off to said heaters after a predetermined time period has elapsed; wherein the improvement comprises: thermostatic control means for controlling the power supplied by each respective 4 1 said heater during the predetermined time period, said control means including sensing means S for sensing the temperature of said heater and power adjusting means for adjusting the power supplied by said heater in response to the temperatre sensed by said sensing means, said sensing means sensing temperature over a predetermined temperature range having upper and lower temperature limits, and said power adjusting means reduces the power at which said heater operates to a predetermined positive lower power level when said sensing means senses a temperature at or above the upper temperature limit and increases the power at which said heater operates to a predetermined higher power level above the lower power level when said sensing means senses temperature at below the lower temperature limit.
2. A heating system in accordance with claim 1 wherein said power adjusting means operates each respective said heater to supply its full power when said initiating means initiates the supply of power to said heaters at the beginning of the predetermined time period.
31. 3. A heating system in accordance with claim 2 wherein said power adjusting means adjusts thet pow %r supplied by each respective said heater to 'Its full ;power when it increases the power above the lower power level. 4. A heating systemn in acccordance with claim 1, 2 or 3 wherein the predetermined temperature range is substantially no greater than 20 degrees Fahrlenheit. S. A heating system in accordance with claim 1, 2 or 3 wherein each said heater includes an operative heater circuit and an electrical heating element imposed in said operative heater circuit, and said power adjusting means includes switching ip~eans for shorting a portion of maid h~eating element out of said operative heater circuit to operate said heater at thte higher power level and for placing said portion of said heating element into said operative heater c;ircuit to operate said heater at the lower power level. 6. A heating system in accordance with claim 5 wherein each said heater includes a heating, plate, said electrical heating element is a resistive heating element and is arranged to cover substantially all of the surface area of said heating plate, and said heating plate forms 1 the contact surface of said heater for contact with a food carrying member associated with the food service tray. 7. A heating system in accordance with claim 6 wherein said heating plate is *generally circular. 8. A heating system in vcordance wih claim 5 further comprising 'In indicator connected to said electrical heating element and which indicates which of the higher and lower power levels is operating. 9. A heating system in accordance with claim 5 wherein said sensing means is located to directly sense the temperature of said heating plate. A heating system in accordance with claim 1 wherein each said heater includes a heating element housing, a heater plate sized to contact cne food carrying member and said electrical heating element, and attaching means for removably attaching said heating element housing to said cart. 11. A heating systemn in accordance with claim 1, 2 or 3 wherein each said heater includes first and second electrical heating elements, and said power adjusting means includes switching means for supplying power to both said heating elements in the higher power level of operation and for supplying power to only one (of said heating elements in the lower power level 4 4 1 of operation. 144: 12. A heating system in accordance with claim 11 wherein said heater includes a heating plate which forms the heater contact surface for contact with a food carrying member, and said first and second heating elements are aricanged to both cover substantially all of the urface area of said heating plat, 13. A heating system in accordance with clairn 12 -wherein said heating plate is generally cirular. 14. A heating system in accordance with claim 1, 2 or 3 wherein each said heater includes sepain' t e- high and low power electrical heating elements, and said power adjusting means incluades switching means for supplying pows- to said high power heating element in the higher power level of operation and to said lower F.:wer heating element in the lower power level of operation. A heating system in accordance with claim 1 further comprising individual activating means connected to each said heater for allowing said heater to supply power when individually activated. 16. A heating system in accordance with claim 1 wherein said sensing means directly senses the temperature of said heater by being in direct thermal contact with said heater. 17. A heating system in accordance with claim 1 wherein each said heater includes a heating plate forming the contact surface of said heater for thermal contact with a food carrying member associated with a food service tray supported by said tray supports, and a resistive heating element covering at least substantially all of a surface area of said heating plate. 18. A ieating system in accordance with claim 17 wherein said sensing means directly senses the temperature of said heating plate. 19. A heating system in accordance with claim 17 wherein said sensing means I 1 1 includes a thermostat. A heating system in accordance with claim 19 wherein said thermostat is secured S directly to a bottom of said heating plate. 21. A heating system in accordance with claim 19 wherein said thermostat is positioned within a centrally located opening in said heating element. S22. A heating system in accordance with claim 1 wherein the predetermined time period is thirty-six minutes. 23. A heating system in accordance with claim 1 wherein the lower temperature limit is between 215 degrees and 225 degrees and the upper temperature limit is between 230 degrees and 240 degrees Fahrenheit.
34. 24. A heating system in accordance with claim 1 wherein said power adjusting means includes a first resistive element assembly and a second resistive.element assembly, wherein electrical current passes through both ,aid first and second resistive element assemblies when said heater is operated at the lower power level and the current passes through said first resistive element assembly and is shunted past said second resistive element assembly when said heater is operated at the higher power level. A heating system in accordance with claim 1 wherein during the predetermined time period electrical current is being supplied continuously to each of said heaters. 26. A heating system in accordance with claim 1 wherein said tray supports allow for the positioning of the food service trays relative to said heaters with said heaters secured in and S to said cart. i i 27. A heating system in accordance with claim 1 wherein said heaters are positioned in said cart relative to said tray supports such that, when food service trays having through- openings are inserted into said cart and then in position on said tray supports, the through- i 'openings are aligned with respective said heaters such that food-containing dishes in the through- openings are in direct thermal contact with respective said heaters for rethermalizing the foods in the dishes. 4R° 28. A heating system in accordance with claim 1 wherein said heaters are secured to said cart such that the food service trays are removable from support on said tray supports and away from said cart with said heaters secured to said cart. 29. A heating system in accordance with claim 1 wherein said power adjusting means includes for each said heater first and second resistive heating elements, and wherein electrical current passes through said first resistive heating element when said heater is operating at the higher power level and through said second resistive heating element when said, heater- iZ operating at the lower pcFwer level. A heating system it~ accordance with claim 1 wherein the lower power level is approximately 25 percent of the highex piower level. 31. A heating system in accordk\nce with claim 1 wherein the lower temperature limit is between 215 degrees and 225 degreerj Fahrenheit. 32. A heating system in accordance with claim 1 wherein said power adjusting means reduces and increases the power continuously over the predetermined time period to continuously supply heat from said heater to the food during the predetermined time period. 33. A heating system in accordance with claim 1 wherein said power adjusting means continuously and constantly supplies electrical current to said heaters during the entire predetermined time period. 34. A heating system in accordance with claim 1 wherein the higher power level inlue a osatcniuu lcrclcretpssn bog adhae n h oe oe le includes a -onstnt continuous electrical currentsn through said heateradte1~e oe A heating system in accordance with claim 1 further comprising refrigeration means for receiving said cart therein and refrigerating foods carried on the food service trays supported in said cart.
36. A heating system in accordance with claim 35 wherein saidi initiating means initiates the supply of power to said heaters when said cart is positioned in said refrigeration means.
37. A heating system in accordance with claim 1 wherein said power adjusting means includes alternate first and second heater circuits and switching means for switching the supplied power back-ard-forth between said fiust nd second heater circuits in response to the temperature sensed by said sensing means such that power is supplied constantly aid continuously to alternately said first and second heater circuits over the entire predetermined time period.
38. A food heating system comprising: a food service cart for storing and heating foods; a plurality of verticUy spaced 'ay supports attached to said cart for supporting removable food service tryws at a plurality of vertically spaced shelf locations; a plurality of conductive heaters securably attached to said cart at a plurality of vertically spaced locations in alignment with the shelf locations for heating foods carried on removable food service trays supported by said tray supports, each said heater including a heating surface, each said heater t being positioned i. said cart relative to said tray supports such that, when removable food S service trays having through-openings are inserted into said cart in positica on said tray supports, said through-openings are aligned with respective said heaters such that food-containing dishes in said through-openings are in direct thermal contact with respective said heating surfaces t for rethermalizing foods in the dishes; initiating means for initiating a supply of current to said heaters; and timer means for turning current off to said heaters after a predetermined time period has elapsed; wherein the improvement comprises: ench said heater including first and second electrical heating elements; each said heater including a thermostatic control which controls said electrical heating elements during' the predetermined time period; said thermostatic control including sensing means, in direct contact with said heating surface, for sensing the temperature of said heater and current adjusting means for ad justing the current through said heater in response to the temperature sensed by said sensing means; said sensing means sensing temperature over a predetermined temperature range ha ing upper and lower temperature Emits; and said current adjusting m,'ans reducing the current through said heater to a predetermined lower constant current level when said sensing means senses a temperature at or above the upper temperature limit and increases the current through said heater to a predetermined higher conutant current level above the lower constant current level when said sensing means senses temperature at or bolow the lower temperature limit, with current being continuously drawn through said heater over the entire predetermined time period.
39. A heating system in accordance with claim 38 further comprising a refrigerator for receiving the cart with foods therein and for refrigerating the foods. A heating system in accordance with claim 38 wherein the predetermined lower and upper contant current levels are selected to correspond to particular lower and upper temperature heating requirements of a range of foods which are to be rethermalized in said cart. S.41. A heating system in accordance with claim 38 wherein said current adjusting means includes switching me-ns for supplying current to both said first and second electrical heating elements in the higher constant current level of operation and for supplying current to only one of said electrical heating elements in the lower constant current level of operation. 38.
42. A heating system in accordance with claim 38 wherein said -curent 2d'4in mans includes switching means for selectively supplying current only to said first electrical heating element in the higher constant current level, of operation and for selectively supplying current only to said second electrical heating element in the lower constant current level of operation.
43. A heating system in accordance with claim 41 or 42 wherein said first and second electrical heating elements each comprise, re.aistance foil which is secured to said heating surface.
44. A heating system in accordance with claim 43 wherein said resistance foil is encased in silicon rubber and laminated to the bottom of said heating surface. A heating system in accordance wvith claim 43 wherein said heating surraee comprises an aluminum plate having a thickness of approximately 1/8 inch. 4,4'46. A heating system in accordance with claim 44 wherein said first and second electrical heater elements are formed in a pattern which substantially covers aUl of said heating surface. *47. A heating system in accordance with claim 38 wherein the lower temperature limit is approximately 220 degrees Fahrenheit.
48. A heating system in accordance with claim 47 wherein the upper temperature limit is approximately 235 degrees Fahrenheit.
49. A heating system in accordance with claim 38 wherein the lower temperature limit is approximately 240 degrees Fabrenheit. A heating system in, c~ordance with claim 49 wherein the upper temperatue limit is approximately 275 degrees Fahrenheit. 39.
51. A heating system in accordance with claim 38 wherein-Ahe pedernie temperature range is substantially no greater than 20 degrees Fahrenheit.
52. A heating system in accordance with claim 38 wherein said plurality of heaters comprises first and second heater types having different first and second heating range,, respectively.
53. A heating system in accordance with claim 52 wherein said first heater type comprises an entree heatr which draw, approximately 35 to 45 watts of powver in the lower constant current level of operation.
54. A heating system in accordance with claim 53 wherein said entree heater draws approximately 150 to 160 watts of power in the higher constant current level of operation. A heating system in accordance with claim 52 wherein said second heater type compr-ises ~a bowl heater which draws approximately 10 watts of power in the lower constant current level of operation.
56. A heating system in accordance with claim 55 wherein said bowl heater draws approximately 46 watts of po~wer in the higher constant current level of operation.
Applications Claiming Priority (6)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US39420489A | 1989-08-15 | 1989-08-15 | |
| US394204 | 1989-08-15 | ||
| US47148390A | 1990-01-29 | 1990-01-29 | |
| US471483 | 1990-01-29 | ||
| US48901790A | 1990-03-06 | 1990-03-06 | |
| US489017 | 1995-06-08 |
Related Child Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| AU44329/93A Division AU660830B2 (en) | 1989-08-15 | 1993-07-30 | Food rethermalizing method |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| AU6148990A AU6148990A (en) | 1991-04-03 |
| AU641930B2 true AU641930B2 (en) | 1993-10-07 |
Family
ID=27410109
Family Applications (5)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| AU61533/90A Abandoned AU6153390A (en) | 1989-08-15 | 1990-08-06 | Food service dish |
| AU61519/90A Ceased AU644092B2 (en) | 1989-08-15 | 1990-08-06 | Food service cart with cantilevered heater pads |
| AU61747/90A Ceased AU641932B2 (en) | 1989-08-15 | 1990-08-06 | Food service cart with individually removable heaters |
| AU61489/90A Ceased AU641930B2 (en) | 1989-08-15 | 1990-08-06 | Food service system and method of rethermalizing food |
| AU27227/92A Expired - Fee Related AU662174B2 (en) | 1989-08-15 | 1992-10-21 | A food storing and rethermalizing system |
Family Applications Before (3)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| AU61533/90A Abandoned AU6153390A (en) | 1989-08-15 | 1990-08-06 | Food service dish |
| AU61519/90A Ceased AU644092B2 (en) | 1989-08-15 | 1990-08-06 | Food service cart with cantilevered heater pads |
| AU61747/90A Ceased AU641932B2 (en) | 1989-08-15 | 1990-08-06 | Food service cart with individually removable heaters |
Family Applications After (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| AU27227/92A Expired - Fee Related AU662174B2 (en) | 1989-08-15 | 1992-10-21 | A food storing and rethermalizing system |
Country Status (4)
| Country | Link |
|---|---|
| EP (3) | EP0487569A1 (en) |
| AU (5) | AU6153390A (en) |
| NZ (2) | NZ234887A (en) |
| WO (4) | WO1991002479A1 (en) |
Families Citing this family (10)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5868195A (en) * | 1992-11-23 | 1999-02-09 | Standex International Corporation | Rethermalization system |
| US5797445A (en) * | 1992-11-23 | 1998-08-25 | Standex International Corporation | Refrigerated rethermalization cart |
| GB2284905B (en) * | 1993-12-15 | 1998-04-01 | Burlodge Ltd | Food regeneration |
| FR2737638B1 (en) * | 1995-08-03 | 1997-10-03 | Bourgeois Prod Coop | INDUCTION TRAY HEATING DEVICE |
| EP0776145B1 (en) * | 1995-11-22 | 2004-03-03 | Schmalz, E., Nachfolger Schmalz, Beat | Apparatus for heating of meals by induction |
| FR2741780B1 (en) * | 1995-12-04 | 1998-01-09 | Pan Eiffel Sarl | PROCESS OF DEFROST AND FERMENTATION OF BAKERY AND VIENNESE PRODUCTS AND STUDY FOR THE IMPLEMENTATION OF SAID PROCESS |
| ES2125816B1 (en) * | 1996-12-31 | 1999-11-16 | Garcia Garcia Isidro | THERMAL SHELF. |
| GB2339348B (en) * | 1998-07-09 | 2003-05-07 | Gen Domestic Appliances Ltd | Heating units for a cooking appliance |
| DE10347634A1 (en) * | 2003-10-09 | 2005-05-12 | Innovat Ges Fuer Sondermaschb | Arrangement for heating food |
| ES2975431T3 (en) * | 2019-07-11 | 2024-07-05 | Vorwerk Co Interholding | Food preparation appliance with PTC electrical thermistors connected in parallel |
Citations (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| GB2066594A (en) * | 1979-12-26 | 1981-07-08 | Sweetheart Plastics | Electrical food heating system |
| US4285391A (en) * | 1979-08-29 | 1981-08-25 | Aladdin Industries, Incorporated | Electrical system for food service devices |
| US4323110A (en) * | 1977-01-11 | 1982-04-06 | Anchor Hocking Corporation | Food preparation process |
Family Cites Families (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US3750083A (en) * | 1968-11-14 | 1973-07-31 | Minnesota Mining & Mfg | Magnetic electric connector |
| US3608770A (en) * | 1969-06-10 | 1971-09-28 | Continental Can Co | Apparatus and system for food preparation |
| FR2207676B1 (en) * | 1972-11-28 | 1976-09-17 | Grandi Rene | |
| US4005745A (en) * | 1974-09-30 | 1977-02-01 | Anchor Hocking Corporation | Apparatus for storing, refrigerating and heating food items |
| CA1164319A (en) * | 1979-08-29 | 1984-03-27 | Marcel Goggiola | Magnetic safety device, inter alia for a food processor |
| US4346756A (en) * | 1980-08-20 | 1982-08-31 | Uop Inc. | Apparatus for selectively heating an individual food item in a refrigerated environment |
| GB8827611D0 (en) * | 1988-11-25 | 1988-12-29 | Gerard Gamble Ltd | Food service system |
-
1990
- 1990-08-06 AU AU61533/90A patent/AU6153390A/en not_active Abandoned
- 1990-08-06 EP EP19900912124 patent/EP0487569A1/en not_active Withdrawn
- 1990-08-06 EP EP90911911A patent/EP0486548A1/en not_active Withdrawn
- 1990-08-06 EP EP90911579A patent/EP0487560A1/en not_active Withdrawn
- 1990-08-06 WO PCT/US1990/004313 patent/WO1991002479A1/en not_active Ceased
- 1990-08-06 AU AU61519/90A patent/AU644092B2/en not_active Ceased
- 1990-08-06 AU AU61747/90A patent/AU641932B2/en not_active Ceased
- 1990-08-06 WO PCT/US1990/004314 patent/WO1991002480A1/en not_active Ceased
- 1990-08-06 AU AU61489/90A patent/AU641930B2/en not_active Ceased
- 1990-08-06 WO PCT/US1990/004315 patent/WO1991002481A1/en not_active Ceased
- 1990-08-06 WO PCT/US1990/004312 patent/WO1991002478A1/en not_active Ceased
- 1990-08-13 NZ NZ234887A patent/NZ234887A/en unknown
- 1990-08-13 NZ NZ234889A patent/NZ234889A/en unknown
-
1992
- 1992-10-21 AU AU27227/92A patent/AU662174B2/en not_active Expired - Fee Related
Patent Citations (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US4323110A (en) * | 1977-01-11 | 1982-04-06 | Anchor Hocking Corporation | Food preparation process |
| US4285391A (en) * | 1979-08-29 | 1981-08-25 | Aladdin Industries, Incorporated | Electrical system for food service devices |
| GB2066594A (en) * | 1979-12-26 | 1981-07-08 | Sweetheart Plastics | Electrical food heating system |
Also Published As
| Publication number | Publication date |
|---|---|
| NZ234887A (en) | 1994-01-26 |
| AU6174790A (en) | 1991-04-03 |
| EP0486548A1 (en) | 1992-05-27 |
| AU6153390A (en) | 1991-04-03 |
| WO1991002479A1 (en) | 1991-03-07 |
| AU2722792A (en) | 1992-12-17 |
| AU6151990A (en) | 1991-04-03 |
| AU662174B2 (en) | 1995-08-24 |
| NZ234889A (en) | 1993-05-26 |
| AU6148990A (en) | 1991-04-03 |
| AU641932B2 (en) | 1993-10-07 |
| AU644092B2 (en) | 1993-12-02 |
| WO1991002481A1 (en) | 1991-03-07 |
| EP0487560A1 (en) | 1992-06-03 |
| WO1991002480A1 (en) | 1991-03-07 |
| EP0487569A1 (en) | 1992-06-03 |
| WO1991002478A1 (en) | 1991-03-07 |
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