Control unit with automatic setback capability
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F24F-011/00
G05D-023/19
G05B-015/02
출원번호
US-0600469
(2015-01-20)
등록번호
US-9709290
(2017-07-18)
발명자
/ 주소
Matsuoka, Yoky
Astier, Frank E.
Sharan, Rangoli
Fadell, Anthony Michael
출원인 / 주소
Google Inc.
대리인 / 주소
Kilpatrick Townsend & Stockton LLP
인용정보
피인용 횟수 :
0인용 특허 :
59
초록▼
Methods for controlling temperature in a conditioned enclosure such as a dwelling are described that include an “auto-away” and/or “auto-arrival” feature for detecting unexpected absences which provide opportunities for significant energy savings through automatic adjustment of the setpoint temperat
Methods for controlling temperature in a conditioned enclosure such as a dwelling are described that include an “auto-away” and/or “auto-arrival” feature for detecting unexpected absences which provide opportunities for significant energy savings through automatic adjustment of the setpoint temperature. According to some preferred embodiments, when no occupancy has been detected for a minimum time interval, an “auto-away” feature triggers a changes of the state of the enclosure, and the actual operating setpoint temperature is changed to a predetermined energy-saving away-state temperature, regardless of the setpoint temperature indicated by the normal thermostat schedule. The purpose of the “auto away” feature is to avoid unnecessary heating or cooling when there are no occupants present to actually experience or enjoy the comfort settings of the schedule, thereby saving energy.
대표청구항▼
1. A method for controlling temperature in a conditioned enclosure comprising: controlling temperature within the conditioned enclosure according to a setpoint temperature, an initial value of the setpoint temperature being from a preexisting schedule and representing a temperature suitable for when
1. A method for controlling temperature in a conditioned enclosure comprising: controlling temperature within the conditioned enclosure according to a setpoint temperature, an initial value of the setpoint temperature being from a preexisting schedule and representing a temperature suitable for when one or more persons are occupying the conditioned enclosure;periodically determining occupancy based on data received from one or more occupancy sensors adapted to detect occupancy within the conditioned enclosure;periodically updating the setpoint temperature upon expiration of a predetermined time interval during which no occupancy has been detected, the updated setpoint temperature requiring substantially less energy to maintain than the initial value of the setpoint temperature; andperiodically modifying the predetermined time interval based at least in part on received manual settings that indicate occupancy following the updating the setpoint temperature. 2. A method according to claim 1 wherein the determining occupancy and periodically updating occur during daytime hours. 3. A method according to claim 1 wherein the conditioned enclosure is at least part of a dwelling or a light commercial building. 4. A method according to claim 1 wherein periodically updating the setpoint temperature comprises updating the setpoint temperature to a setpoint temperature from the preexisting schedule. 5. A method according to claim 4 wherein periodically updating the setpoint temperature comprises returning the setpoint temperature to the initial value. 6. A method for controlling temperature in a conditioned enclosure comprising: controlling temperature within the conditioned enclosure according to a setpoint temperature, an initial value of the setpoint temperature being from a preexisting schedule and representing a temperature suitable for when one or more persons are occupying the conditioned enclosure;periodically determining occupancy based on data received from one or more occupancy sensors adapted to detect occupancy within the conditioned enclosure;periodically updating the setpoint temperature upon expiration of a predetermined time interval during which no occupancy has been detected, the updated setpoint temperature requiring substantially less energy to maintain than the initial value of the setpoint temperature; andperiodically modifying the predetermined time interval based at least in part on prior received data and prior automatic changes of the setpoint temperature in the conditioned enclosure. 7. A method according to claim 6 wherein the determining occupancy and periodically modifying occur during daytime hours. 8. A system for controlling temperature in a conditioned enclosure comprising: a thermostat that controls a heating, ventilating and air conditioning (HVAC) system of the conditioned enclosure and that classifies the conditioned enclosure at least as being in an occupied state or an unoccupied state, the thermostat comprising: an occupancy sensor for detecting occupancy within the conditioned enclosure, anda memory that stores: occupancy history information from the occupancy sensor;a local flag having a value based on the occupancy history information being consistent with the conditioned enclosure being unoccupied; andone or more peer flags having values that correspond to local flags stored by one or more peer thermostats, each of the peer flags being updateable to reflect a value of a local flag of a respective one of the peer thermostats; andwherein the thermostat: updates the local flag at least according to information from the occupancy sensor;receives information of the values of the local flags of the one or more peer thermostats to update the peer flags;classifies the conditioned enclosure in the unoccupied state when the value of the local flag and values of all of the peer flags reflect that the occupancy history information of the thermostat and all of the peer thermostats is consistent with the conditioned enclosure being unoccupied; andcontrols the temperature in the conditioned enclosure according to a first schedule when the conditioned enclosure is classified in the occupied state, and according to a second schedule when the conditioned enclosure is classified in the unoccupied state. 9. The system of claim 8, wherein the thermostat is capable of disqualifying a peer thermostat of the one or more peer thermostats based on insufficient sensed occupant activity at the peer thermostat being disqualified, such that the value of the peer flag corresponding to the peer thermostat that is disqualified is not considered when the thermostat classifies the conditioned enclosure. 10. The system of claim 9, wherein the thermostat is capable of requalifying a disqualified peer thermostat, based on the disqualified peer thermostat sensing a predetermined level of occupant activity, such that the value of the peer flag corresponding to the peer thermostat that is requalified is again considered when the thermostat classifies the conditioned enclosure. 11. The system of claim 8, the thermostat further comprising a wireless transceiver, and wherein the thermostat receives the information of the status of the local flag of at least one of the one or more peer thermostats to update the peer flags, through peer to peer communication with the at least one of the one or more peer thermostats, using the wireless transceiver. 12. The system of claim 8, the thermostat further comprising a wireless transceiver, and wherein the thermostat receives the information of the status of the local flag of at least one of the one or more peer thermostats to update the peer flags, from a cloud-based management server through the wireless transceiver. 13. The system of claim 8, wherein the second schedule includes a temperature setpoint at an energy-saving temperature value, relative to a temperature setpoint at a corresponding time of day in the first schedule. 14. The system of claim 8, further comprising the one or more peer thermostats. 15. A method for controlling temperature in a conditioned enclosure comprising: controlling a heating, ventilating and air conditioning (HVAC) system for the conditioned enclosure with a thermostat that comprises: an occupancy sensor for detecting occupancy within the conditioned enclosure;a processing system; andmemory that stores: occupancy history information from the occupancy sensor;a local flag having a value based on the occupancy history information being consistent with the conditioned enclosure being unoccupied; andone or more peer flags having values that correspond to local flags stored by one or more peer thermostats, each of the peer flags being updateable to reflect a value of a local flag of a respective one of the peer thermostats;updating the local flag at least according to information from the occupancy sensor;updating the peer flags according to received information of the values of the local flags of the one or more peer thermostats;classifying the conditioned enclosure, by the processing system, in the unoccupied state when the value of the local flag and values of all of the peer flags reflect that the occupancy history information of the thermostat and all of the peer thermostats is consistent with the conditioned enclosure being unoccupied; andcontrolling the temperature in the conditioned enclosure, by the processing system, according to a first schedule when the conditioned enclosure is classified in the occupied state, and according to a second schedule when the conditioned enclosure is classified in the unoccupied state. 16. The method of claim 15, further comprising disqualifying, by the processing system, one of the one or more peer thermostats based on insufficient sensed occupant activity, such that the value of the peer flag corresponding to the disqualified peer thermostat is not considered when the thermostat classifies the conditioned enclosure. 17. The method of claim 16, further comprising requalifying, by the processing system, the disqualified peer thermostat, when the disqualified peer thermostat senses a predetermined level of occupant activity, such that the value of the peer flag corresponding to the requalified peer thermostat is again considered when the thermostat periodically determines classification of the conditioned enclosure. 18. The method of claim 15, further comprising receiving, by the thermostat, the information of the status of the local flag of at least one of the one or more peer thermostats to update the peer flags, through a wireless transceiver in peer to peer communication with the at least one of the one or more peer thermostats. 19. The method of claim 15, further comprising receiving, by the thermostat, the information of the status of the local flag of at least one of the one or more peer thermostats to update the peer flags, through a wireless transceiver from a cloud-based management server. 20. The method of claim 15, wherein the second schedule includes a temperature setpoint at an energy-saving temperature value, relative to a temperature setpoint at a corresponding time of day in the first schedule.
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