1. Field of the Invention
This disclosure relates to deep fryers for the food service industry. More particularly, this disclosure relates to deep fryers that are capable of filtering used oil to conserve the oil and to the oil filtering process. Still more particularly, this disclosure relates to deep fryers that are capable of filtering used oil to conserve the oil and to the oil filtering process wherein the process uses thermal sensor feedback to monitor the location of oil in the fryer.
2. Description of Related Art
Deep fryers are a necessity of the food service industry and particularly for the fast food service industry. Deep fryers use a substantial amount of shortening or oil during the cooking process. During the cooking process much of the oil is absorbed by a food product, resulting in loss of oil volume. The remaining oil can become filled with debris due to constant use. Accordingly, there is a need to extend the usable life of the unabsorbed oil and to keep the unused oil clean during the cooking process.
Accordingly, there is a need for a deep fryer that automatically filters used oil in a continuous filtering loop using sensor feedback.
The present disclosure provides for a deep fryer that filters used cooking oil to extend the life of the cooking oil, using feedback from temperature sensors.
The present disclosure also provides for a deep fryer that has a closed loop oil filtering system for removing debris from the cooking oil.
The present disclosure provides for a deep fryer system that is capable of filtering oil using temperature sensor feedback to ensure correct location of the oil in the deep fryer.
The present disclosure further provides for a method of filtering cooking oil in a deep fryer that is based on feedback from temperature sensors in the deep fryer.
The present disclosure still further provides for a method of filtering cooking oil for a plurality of fryer pots using a manifold to collect cooking oil and a pump associated with each deep fryer.
The present disclosure further provides for a plurality of fryer pots that are controlled using a centralized system that uses sensory feedback to ensure filtering steps are performed in the correct timed sequence.
The present disclosure provides for a deep fryer that provides at least two sensors; one of the two sensors is a temperature sensor to ensure oil is in the deep fryer to commence the filtration cycle and the other of the two sensors ensures that the oil has reached the desired height in the pot during the filler operation.
The present disclosure still yet further provides for a deep fryer having slots at its lower edge proximate the oil return valve to disperse oil in a spray pattern, the spray pattern ensures that crumbs on the bottom surface of the deep fryer will be flushed.
Accordingly, there is a need for a centralized process that controls the automatic filtering operation of a deep fryer having a plurality of fryer pots, by using feedback from temperature sensors and timers that control the operation of the pumping and filling operations in each pot.
These and other further benefits and features are provided by an automatic filtration system for cooking oil in a deep fryer having a plurality of fryer pots disposed in the deep fryer. Each of the plurality of fryer pots having a first temperature sensor, a second temperature sensor, a drain valve and return valve. The system further has a controller that is capable of counting the number of cooking cycles of a particular fryer pot. After the first temperature sensor senses a first predetermined temperature, oil drains from the fryer pot through the drain valve and when the second temperature sensor senses a second predetermined temperature the oil has substantially returned to the fryer pot through the return valve.
An automatic filtration system for cooking oil in a deep fryer having a deep fryer and a plurality of fryer pots disposed in the deep fryer. Each of the plurality of fryer pots having a first temperature sensor, a drain valve, a second temperature sensor, a return valve associated therewith and at least one slot proximate the drain valve. The system further includes a controller. After the first temperature sensor senses a first predetermined temperature, oil drains from the fryer pot through the drain valve and when the second temperature sensor senses a second predetermined temperature the oil returns to the fryer pot through the return valve and the at least one slot.
Other and further benefits, advantages and features of the present invention will be understood by reference to the following specification in conjunction with the accompanying drawings, in which like reference characters denote like elements of structure and:
Referring to
Deep fryer 10 has a control panel 35 that is associated with each fryer pot 15. Control panel 35 is operatively connected to a controller 40 that monitors the operation of sensors and timers associated with each fryer pot 15. Controller 40 can accept various settings, such as, for example, temperature and timing settings. For example, controller is 40 is capable of counting the number of times cooking cycles processed in a fryer pot 15. After a predetermined temperature has been sensed, and a number of cooking cycles have been counted, the automatic filtration can be initiated. Alternatively, after a predetermined temperature has been sensed, the control panel 35 prompts the user with filter cycle indicator 42, such as a lamp or an audible indicator for manual operation of the initiation of the automatic filtration cycle with or without a counted number or basket cycles. Controller 35 permits user selection of either automatic or manual operation.
Referring to
Oil passes from drain manifold 55 to crumb basket 65, via downspout 60. Crumb basket 65 is a preliminary filter that removes large pieces of residual food product from oil. Referring to
Referring to
Once a substantial amount of oil has drained from fryer pot 15 into filter pan 70 from manifold 55, temperature sensor 25 in fryer pot 15 is exposed to an ambient air temperature. When temperature sensor 25 senses a 10° F. to 20° F. temperature drop below the set oil temperature, controller 40 energizes linear actuator 52 to open return valve 90 and pump and motor assembly 85 are switched on to return oil back to fryer pot 15. Sensor 25 senses a temperature of from approximately 250° F. to 280° F. The pumping action pulls the oil through filter pad 72 located in the bottom of filter pan 70 and forces clean filtered oil through return valve 90. The temperature drop sensed by sensor 25 informs controller that oil is no longer in fryer pot 15 and that pump and motor assembly 85 can be switched on to commence filling of fryer pot 15. Were filtration system only time based, the pump and motor assembly 85 may improperly commence operation and run in the absence of oil and cause premature component failure.
After filtered oil is pushed through opened return valve 90, it is forced through a narrow slot or several slots 100 at lower edge of fryer pot 15 and sprayed over fryer pot lower surface. These slots are from 2 to 5 inches long, 0.05 to 0.10 inches in height, and from 1 to 5 in number. The force with which oil is sprayed back over lower surface of fryer pot 15 is strong enough to push remaining heavy debris that did not initially flow through drain valve 45 at commencement of filtering cycle, but not so great as to force oil to splash out of the fryer pot 15. By having an oil flow rate of approximately 3 to 9 gallons/minute through a limited size pump and motor assembly 85, oil is prevented from splashing out of fryer pot 15. The sprayed oil and additional debris will then flow through drain valve 45. The amount of time for spraying the oil from return valve 90 back and though the drain valve 45 is predetermined and set in controller 40 for a duration of 15 to 30 seconds. During this time, cooking oil is repeatedly cycled through filtration system. After 15 to 30 seconds, linear actuator 50 is activated to close drain valve 45 while pump and motor assembly 85 return oil to fryer pot 15. The repeated or polishing cycles filters the oil to ensure that substantially all food particles have been removed from the cooking oil and the fryer pot 15. The polishing filtration cycles eliminate the need for the cooking oil to be replaced prematurely and therefore extends the useful life of the cooking oil. Further the centralized control of drain valve 45, return valve 90, and pump and motor assembly 85 provides sensory feedback to ensure that the filtering cycle is performed in the correct timed sequence.
Approximately 15 to 30 seconds after drain valve 45 is closed, heating elements 20 are automatically energized to warm cooking oil that has been returned to fryer pot 15. After 20 to 45 more seconds, the volume of cooking oil in fryer pot 15 is great enough so that temperature sensor 95 on fryer pot wall is able to sense an increase in temperature because it is immersed. When sensor 95 senses approximately 5 to 10 seconds of rising temperature the oil is considered to be returned substantially to the pot. Twenty to forty-five additional seconds of bubbling insure that the oil is completely returned to the fryer pot from filter pan 70. At this time, pump and motor assembly 85 are de-energized and linear actuator 52 is energized to close return valve 90.
While the instant disclosure has been described to incorporate linear actuators, either hydraulic or pneumatic pistons could also be used for opening and closing the drain and return valves of the instant disclosure.
The present invention having been thus described with particular reference to the preferred forms thereof, it will be obvious that various changes and modifications may be made therein without departing from the spirit and scope of the present invention as defined in the disclosure.
This application claims benefit of U.S. Provisional Patent Application Ser. No. 60/962,046 filed on Jul. 26, 2007, the contents of which are incorporated by reference herein.
Number | Date | Country | |
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60962046 | US |