초록 ▼

A system for controlling temperature in an enclosure operates in a low heat or a high heat mode with flame always present. The presently intended use is for providing a cooking grill with a controlled temperature cooking space. An electrically controlled valve having high flow rate and low flow rate

A system for controlling temperature in an enclosure operates in a low heat or a high heat mode with flame always present. The presently intended use is for providing a cooking grill with a controlled temperature cooking space. An electrically controlled valve having high flow rate and low flow rate settings is interposed in the fuel line for at least one of the burners in the grill. A temperature sensor signals cooking space temperature to a controller that may be a microprocessor. The system includes a keyboard allowing the user to communicate a selected set point to the microprocessor and the microprocessor communicates status to a display. The microprocessor selects the setting of the electrically controlled valve. In a preferred embodiment, the electrically controlled valve is placed in series fuel flow with one of the manually adjustable valves commonly found on cooking grills.

대표청구항 ▼

1. A control system for a fluid fuel burner supplying heat to an enclosure, said system including:a) a temperature sensor mounted within the enclosure for sensing the temperature within the enclosure and providing a temperature signal encoding the temperature within the enclosure; b) a first fuel va

1. A control system for a fluid fuel burner supplying heat to an enclosure, said system including:a) a temperature sensor mounted within the enclosure for sensing the temperature within the enclosure and providing a temperature signal encoding the temperature within the enclosure; b) a first fuel valve for controlling flow of fuel from an inlet port to the fuel burner, and having at least first and second preselected fuel flow rates responsive to first and second states of a fuel rate signal respectively, said second fuel flow rate higher than the first fuel flow rate, said first fuel valve including a regulator mechanism active while the first preselected fuel flow rate exists; c) a controller receiving the temperature sensor signal and a set point temperature signal encoding a set point temperature value, for providing to the first fuel valve the fuel rate signal having the at least first and second states thereof as a function of the temperature encoded in the temperature sensor signal and the set point temperature value; and d) a keypad functioning as a manually operable temperature entry device accepting human input specifying a set point temperature and providing a set point temperature signal encoding the specified set point temperature. 2. The control system of claim 1, wherein the keypad includes a temperature control key for specifying a temperature input from the keypad, and wherein the controller records the temperature input from the keypad as the set point temperature value responsive to operation of the temperature key.3. The control system of claim 1 wherein the temperature sensor comprises a meat probe.4. The control system of claim 1, wherein the first fuel valve has a first preselected fuel flow rate greater than zero flow.5. A control system for a fluid fuel burner supplying heat to an enclosure, said system including:a) a temperature sensor mounted within the enclosure for sensing the temperature within the enclosure and providing a temperature signal encoding the temperature within the enclosure; b) a first fuel valve for controlling flow of fuel from an inlet port to the fuel burner, and having at least first and second preselected fuel flow rates responsive to first and second states of a fuel rate signal respectively, said second fuel flow rate higher than the first fuel flow rate, said first fuel valve including a regulator mechanism active while the first preselected fuel flow rate exists; c) a controller receiving the temperature sensor signal and a set point temperature signal encoding a set point temperature value, for providing to the first fuel valve the fuel rate signal having the at least first and second states thereof as a function of the temperature encoded in the temperature sensor signal and the set point temperature value, wherein the controller comprises a proportional control function and an integral control function; and d) a manually operable temperature entry device accepting human input specifying a set point temperature and providing a set point temperature signal encoding the specified set point temperature. 6. The control system of claim 5, wherein the controller comprises a run control calculator determining for intervals a duty cycle value specifying a fraction of the interval, and including a run cycler providing one value of the fuel rate signal during the duty cycle fraction of the interval and the other fuel rate value during at least part of the remainder of the interval.7. The control system of claim 6, wherein the first fuel valve has a first preselected fuel flow rate greater that zero flow.8. In a gas grill of the type having a cooking enclosure, a fitting for connecting to a gas fuel source, a burner in the cooking enclosure, and a fuel line to conduct fuel from the fitting to the burner, the improvement comprising:a) a temperature sensor mounted within the cooking enclosure for sensing a temperature within the enclosure and providing a temperature signal encoding the temperature within the enclosure; b) an electrically controlled fuel valve interposed in the fuel line for controlling flow of fuel from the fitting to the fuel burner, and having at least first and second preselected fuel flow rates responsive respectively to first and second states of a fuel rate signal, said second fuel flow rate higher than the first fuel flow rate, said fuel valve including a pressure regulator mechanism active while the first preselected fuel flow rate exists; c) a controller receiving the temperature sensor signal and a set point temperature signal encoding a set point temperature value, for providing the fuel rate signal as a function of the temperature encoded in the temperature sensor signal and the set point temperature value, said controller including i) a timer providing a clock signal at the start of each of a series of consecutive time intervals of preselected length; and ii) an algorithm processor receiving the clock signal, the set point temperature and the temperature signal, and responsive to each clock signal providing the first value of the fuel rate signal for a fraction of the preselected time interval length as a function of the set point signal and the temperature signal, and the second value of the fuel rate signal for the remaining fraction of the preselected time interval length; and d) a manually operable data entry device accepting human input specifying a set point temperature and providing a set point temperature signal encoding the specified set point temperature. 9. The improvement of claim 8, including a battery supplying operating power to the fuel valve.10. The improvement of claim 8, wherein the entry device comprises a keypad.11. The improvement of claim 10, wherein the keypad includes a temperature key for specifying a temperature input from the keypad, and wherein the controller records the temperature input from the keypad as the set point temperature value responsive to operation of the temperature key.12. The improvement of claim 8 wherein the temperature sensor comprises a meat probe.13. The improvement of claim 8, including a thermopile mounted to receive heat from the burner and supplying power to the controller and the valve.14. The improvement of claim 13, including a pilot light receiving fuel from the fuel line, and mounted adjacent to the burner and the thermopile, and wherein the first fuel valve shuts off fuel flow when receiving the first state of the fuel rate signal.15. In a gas grill of the type having a cooking enclosure, a fitting for connecting to a gas fuel source, a burner in the cooking enclosure, and a fuel line to conduct fuel from the fitting to the burner, the improvement comprising:a) a temperature sensor mounted within the cooking enclosure for sensing a temperature within the enclosure and providing a temperature signal encoding the temperature within the enclosure; b) an electrically controlled fuel valve interposed in the fuel line for controlling flow of fuel from the fitting to the fuel burner, and having at least first and second preselected fuel flow rates responsive respectively to first and second states of a fuel rate signal, said second fuel flow rate higher than the first fuel flow rate; c) a controller receiving the temperature sensor signal and a set point temperature signal encoding a set point temperature value, for providing the fuel rate signal as a function of the temperature encoded in the temperature sensor signal and the set point temperature value; d) a manually operable data entry device accepting human input specifying a set point temperature and providing a set point temperature signal encoding the specified set point temperature; e) at least one manually operable second fuel valve in series with the first fuel valve, said second fuel valve for manually controlling fuel flow to the burner, said second fuel valve having a control knob for controlling the flow rate of fuel through the valve; and f) a switch having a mechanical linkage to the second fuel valve's control knob, said switch in controlling relation to the first fuel valve, said mechanical linkage placing the switch in a control position when the knob is in a predetermined position, said switch when in the control position allowing the first fuel valve to reach at least both of the first and second fuel flow rates, and allowing only the second fuel flow rate for the first fuel valve otherwise. 16. The improvement of claim 15, wherein the gas grill includes at least two burners and two manually operable second fuel valves, each second fuel valve in series with the first fuel valve and each controlling fuel flow to a preselected one of the burners, each said second fuel valve having a control knob for controlling the flow rate of fuel through the associated second fuel valve, wherein the improvement further comprises for each second fuel valve, a switch having a mechanical linkage to the second fuel valve's control knob and in controlling relation to the first fuel valve, said mechanical linkage placing the switch for each second fuel valve in a control position when the knob for each of the second fuel valves is in a predetermined position for that second fuel valve, said switch for each second fuel valve when in the control position allowing the first fuel valve to reach at least both of the first and second fuel flow rates, and allowing only the second fuel flow rate for the first fuel valve otherwise.