Preconditioning controls and methods for an environmental control system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G05B-013/00
G05B-011/01
G06F-001/00
출원번호
US-0632150
(2012-09-30)
등록번호
US-8630742
(2014-01-14)
발명자
/ 주소
Stefanski, Mark D.
Matsuoka, Yoky
출원인 / 주소
Nest Labs, Inc.
대리인 / 주소
Kilpatrick Townsend & Stockton LLP
인용정보
피인용 횟수 :
21인용 특허 :
31
초록▼
Embodiments of the invention describe thermostats that are configured to precondition an enclosure and methods for performing the same. According to one embodiment, a method of preconditioning an enclosure includes providing a thermostat and computing a set of preconditioning criteria information (P
Embodiments of the invention describe thermostats that are configured to precondition an enclosure and methods for performing the same. According to one embodiment, a method of preconditioning an enclosure includes providing a thermostat and computing a set of preconditioning criteria information (PCI) with said thermostat. The computed PCI is typically representative of time and ambient temperature conditions for which preconditioning should be performed. The PCI may be stored in memory and used to compare against a current time and current ambient temperature condition of the enclosure to determine whether to enter the thermostat into a preconditioning state. If a determination is made that the PCI criteria are satisfied, the thermostat may be entered into the preconditioning state to heat or cool the enclosure. One or more of these processes may be performed while a processor of the thermostat is in a relatively high power mode or relatively low power mode.
대표청구항▼
1. A thermostat, comprising: a housing;memory; anda processing system disposed within the housing, the processing system being in operative communication with one or more temperature sensors to determine an ambient temperature, and in operative communication with a heating, ventilation, and air cond
1. A thermostat, comprising: a housing;memory; anda processing system disposed within the housing, the processing system being in operative communication with one or more temperature sensors to determine an ambient temperature, and in operative communication with a heating, ventilation, and air conditioning (HVAC) system to control the ambient temperature according to an HVAC schedule stored in said memory, the HVAC schedule including a first setpoint characterized by a first setpoint temperature and a first setpoint time, the HVAC schedule including a second setpoint characterized by a second setpoint temperature and a second setpoint time, the first setpoint time and second setpoint time defining a first time interval therebetween, said processing system being configured to control the HVAC system to precondition the enclosure during at least a part of said first time interval such that the ambient temperature reaches substantially said second setpoint temperature by said second setpoint time, the processing system including a first processor characterized by at least a relatively high electrical power-consuming first mode of operation and a relatively low electrical power-consuming second mode of operation, wherein the processing system controls the HVAC system to preconditioning the enclosure by: during said first time interval, entering into said first mode of operation to process the second setpoint temperature in conjunction with first information derived from a historical record stored in said memory of previous heating and cooling cycles for said HVAC system as controlled by the thermostat to compute a set of preconditioning criteria information (PCI) representative of time and ambient temperature conditions for which the preconditioning should be performed;storing the set of PCI in said memory;subsequent to said storing the set of PCI in said memory, entering into said second mode of operation;while in said second mode of operation, comparing a current time and current ambient temperature against said PCI to determine whether to enter into a preconditioning state; andentering into said first mode of operation and into said preconditioning state upon a determination that the PCI criteria are satisfied. 2. The thermostat of claim 1, wherein the set of PCI is computed based on a time to temperature for the enclosure that defines a change in temperature response for the enclosure when subjected to a heating or cooling operation. 3. The thermostat of claim 2, wherein the time to temperature for the enclosure is adjusted for a subsequent preconditioning operation based on a response of the enclosure to said preconditioning, said response being stored in said memory and included in said historical record of said previous heating and cooling cycles. 4. The thermostat of claim 1, wherein the processing system further comprises a second processor characterized by a relatively low electrical power-consuming mode of operation, wherein said set of PCI is communicated to said second processor prior to said first processor entering into said second mode of operation. 5. The thermostat of claim 4, wherein said set of PCI is computed via said first processor each time said first processor enters into said first mode of operation, and wherein said set of PCI is communicated to said second processor prior to said first processor entering into said second mode of operation. 6. The thermostat of claim 4, wherein communicating said set of PCI to said second processor comprises communicating a partial set of said set of PCI, said partial set covering a time interval extending to either of: 1) an anticipated or requested time of said first processor entering into said first mode of operation, and 2) said second setpoint time. 7. The thermostat of claim 4, wherein comparing said current time and current ambient temperature against said PCI to determine whether to enter into said preconditioning state comprises: determining an amount of time relative to said first processor entering into said second mode of operation;determining an ambient temperature condition of said PCI associated with said amount of time, the ambient temperature condition representing a temperature for which preconditioning should be performed; andcomparing said current ambient temperature with said ambient temperature condition to determine whether said PCI criteria are satisfied. 8. The thermostat of claim 4, wherein processing said second setpoint temperature in conjunction with said first information to compute said set of PCI comprises: determining a first time duration defined by said second setpoint time and a first time within said first time interval;deriving from said historical record, a first ambient temperature condition associated with said first time duration that represents a temperature for which preconditioning should be performed;determining a second time duration defined by said first time and a second time within said first time interval;deriving from said historical record, a second ambient temperature condition associated with said second time duration that represents an additional temperature for which preconditioning should be performed; anddetermining at least one addition time duration within said first time interval; andderiving at least one additional ambient temperature condition representative of at least one additional temperature for which preconditioning should be performed. 9. The thermostat of claim 1, wherein said set of PCI comprises either or both an upper range representative of conditions for which preconditioning cooling should be performed and a lower range representative of conditions for which preconditioning heating should be performed. 10. The thermostat of claim 1, wherein said set of PCI comprise a step function, and wherein preconditioning is limited to a defined duration. 11. A method comprising: providing a thermostat, the thermostat comprising: a housing;memory; anda processing system disposed within the housing, the processing system being in operative communication with one or more temperature sensors to determine an ambient temperature, and in operative communication with a heating, ventilation, and air conditioning (HVAC) system to control the ambient temperature according to an HVAC schedule stored in said memory, the HVAC schedule including a first setpoint characterized by a first setpoint temperature and a first setpoint time, the HVAC schedule including a second setpoint characterized by a second setpoint temperature and a second setpoint time, the first setpoint time and second setpoint time defining a first time interval therebetween, said processing system being configured to control the HVAC system to precondition the enclosure during at least a part of said first time interval such that the ambient temperature reaches substantially said second setpoint temperature by said second setpoint time, the processing system including a first processor characterized by at least a relatively high electrical power-consuming first mode of operation and a relatively low electrical power-consuming second mode of operation;during said first time interval, entering said first processor into said first mode of operation to process the second setpoint temperature in conjunction with first information derived from a historical record stored in said memory of previous heating and cooling cycles for said HVAC system as controlled by said thermostat to compute a set of preconditioning criteria information (PCI) representative of time and ambient temperature conditions for which the preconditioning should be performed;storing said set of PCI in said memory;subsequent to said storing said set of PCI in said memory, entering said first processor into said second mode of operation;while in said second mode of operation, comparing a current time and current ambient temperature against said PCI to determine whether to enter said thermostat into a preconditioning state; andentering said first processor into said first mode of operation; andentering said thermostat into said preconditioning state upon a determination that the PCI criteria are satisfied. 12. The method of claim 11, wherein said set of PCI is computed based on a time to temperature for said enclosure. 13. The method of claim 12, wherein said time to temperature is adjusted for a subsequent preconditioning operation based on a response of said enclosure to said preconditioning. 14. The method of claim 11, wherein said processing system further comprises a second processor characterized by a relatively low electrical power-consuming mode of operation, wherein said set of PCI is communicated to said second processor prior to said first processor entering into said second mode of operation. 15. The method of claim 14, wherein comparing said current time and current ambient temperature against said set of PCI to determine whether to enter into said preconditioning state comprises: determining an amount of time relative to said first processor entering into said second mode of operation;determining an ambient temperature condition of said set of PCI associated with said amount of time, said ambient temperature condition representing a temperature for which preconditioning should be performed; andcomparing said current ambient temperature with said ambient temperature condition to determine whether said set of PCI criteria are satisfied. 16. The method of claim 14, wherein said set of PCI comprises a step function within said first interval of time. 17. The method of claim 16, wherein said set of PCI comprises either or both an upper step function representative of conditions for which preconditioning cooling should be performed and a lower step function representative of conditions for which preconditioning heating should be performed. 18. The method of claim 11, wherein preconditioning is limited to being performed up to one hour prior to the second setpoint time. 19. A thermostat, comprising: a housing;memory; anda processing system disposed within the housing, the processing system being in operative communication with one or more temperature sensors to determine an ambient temperature, and in operative communication with a heating, ventilation, and air conditioning (HVAC) system to control the ambient temperature according to an HVAC schedule stored in said memory, the HVAC schedule including a first setpoint characterized by a first setpoint temperature and a first setpoint time, the HVAC schedule including a second setpoint characterized by a second setpoint temperature and a second setpoint time, the first setpoint time and second setpoint time defining a first time interval therebetween, the processing system being configured to control the HVAC system to precondition the enclosure during at least a part of the first time interval such that the ambient temperature reaches substantially the second setpoint temperature by the second setpoint time, the processing system including a first processor characterized by at least a relatively high electrical power-consuming first mode of operation and a relatively low electrical power-consuming second mode of operation, and a second processor characterized by a relatively low electrical power-consuming mode of operation, wherein the processing system controls the HVAC system to preconditioning the enclosure by: during the first time interval, processing, via the first processor in said first mode of operation, the second setpoint temperature in conjunction with first information derived from a historical record stored in said memory of previous heating and cooling cycles for the HVAC system as controlled by the thermostat to compute a set of preconditioning criteria information (PCI) representative of time and ambient temperature conditions for which the preconditioning should be performed;communicating the set of PCI to the second processor;subsequent to communicating the set of PCI to the second processor, entering the first processor into the second mode of operation;comparing, via the second processor, a current time and current ambient temperature against the set of PCI to determine whether to enter into a preconditioning state;entering the first processor into the first mode of operation based on information transmitted by the second processor; andentering the thermostat into the preconditioning state upon a determination that the PCI criteria are satisfied. 20. The thermostat of claim 19, wherein the set of PCI is computed based on a time to temperature for the enclosure that defines a change in temperature in a defined amount of time for the enclosure when subjected to a heating or cooling operation. 21. The thermostat of claim 19, wherein the set of PCI is computed via the first processor each time the first processor enters into the first mode of operation, and wherein the set of PCI is communicated to the second processor prior to each time the first processor enters into the second mode of operation. 22. The thermostat of claim 19, wherein comparing the current time and current ambient temperature against the set of PCI comprises: determining, via the second processor, an amount of time relative to the first processor entering into the second mode of operation;determining, via the second processor, an ambient temperature condition of the set of PCI associated with the amount of time, the ambient temperature condition representing a temperature for which preconditioning should be performed; andcomparing, via the second processor, the current ambient temperature with the ambient temperature condition to determine whether the set of PCI criteria are satisfied. 23. The thermostat of claim 19, wherein processing the second setpoint temperature in conjunction with the first information to compute the set of PCI comprises: calculating a step function having a plurality of time durations and a plurality of ambient temperature conditions, wherein each time duration is associated with a respective ambient temperature condition, and wherein the step function is calculated by: determining the plurality of time durations, wherein each time duration is defined by a first time and a second time within the first time interval and measured relative to the second setpoint time; andderiving from the historical record and for each time duration, an ambient temperature condition that represents a temperature for which preconditioning should be performed. 24. The thermostat of claim 19, wherein the set of PCI comprises either or both an upper range representative of conditions for which preconditioning cooling should be performed and a lower range representative of conditions for which preconditioning heating should be performed. 25. A method comprising: providing a thermostat, the thermostat comprising: a housing;memory; anda processing system disposed within the housing, the processing system being in operative communication with one or more temperature sensors to determine an ambient temperature, and in operative communication with a heating, ventilation, and air conditioning (HVAC) system to control the ambient temperature according to an HVAC schedule stored in said memory, the HVAC schedule including a first setpoint characterized by a first setpoint temperature and a first setpoint time, the HVAC schedule including a second setpoint characterized by a second setpoint temperature and a second setpoint time, the first setpoint time and second setpoint time defining a first time interval therebetween, the processing system being configured to control the HVAC system to precondition the enclosure during at least a part of said first time interval such that the ambient temperature reaches substantially the second setpoint temperature by the second setpoint time, the processing system including a first processor characterized by at least a relatively high electrical power-consuming first mode of operation and a relatively low electrical power-consuming second mode of operation, and a second processor characterized by a relatively low electrical power-consuming mode of operation;entering the first processor into the first mode of operation to process the second setpoint temperature in conjunction with first information derived from a historical record stored in said memory of previous heating and cooling cycles for the HVAC system as controlled by the thermostat to compute a set of preconditioning criteria information (PCI) representative of time and ambient temperature conditions for which the preconditioning should be performed;communicating the set of PCI to the second processor;subsequent to communicating the set of PCI to the second processor, entering the first processor into the second mode of operation;while in the second mode of operation, comparing a current time and current ambient temperature with the second processor against the set of PCI to determine whether to enter the thermostat into a preconditioning state;entering the first processor into the first mode of operation; andentering the thermostat into the preconditioning state upon a determination that the PCI criteria are satisfied. 26. The method of claim 25, wherein the set of PCI is computed based on a time to temperature for the enclosure. 27. The method of claim 26, wherein the time to temperature is adjusted for a subsequent preconditioning operation based on a response of the enclosure to the preconditioning. 28. The method of claim 25, wherein the set of PCI comprises a step function within the first interval of time. 29. The method of claim 28, wherein the set of PCI comprises either or both an upper step function representative of conditions for which preconditioning cooling should be performed and a lower step function representative of conditions for which preconditioning heating should be performed.
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