This patent specification relates to the monitoring and control of heating, cooling, and air conditioning (HVAC) systems. More particularly, this patent specification relates to systems, methods, and related computer program products for facilitating a user-friendly thermostat installation process.
Substantial effort and attention continues toward the development of newer and more sustainable energy supplies, the conservation of energy by increased energy efficiency remains crucial to the world's energy future. According to an October 2010 report from the U.S. Department of Energy, heating and cooling account for 56% of the energy use in a typical U.S. home, making it the largest energy expense for most homes. Along with improvements in the physical plant associated with home heating and cooling (e.g., improved insulation, higher efficiency furnaces), substantial increases in energy efficiency can be achieved by better control and regulation of home heating and cooling equipment. By activating heating, ventilation, and air conditioning (HVAC) equipment for judiciously selected time intervals and carefully chosen operating levels, substantial energy can be saved while at the same time keeping the living space suitably comfortable for its occupants.
It would be beneficial, at both a societal level and on a per-home basis, for a large number of homes to have their existing older thermostats replaced by newer, microprocessor controlled “intelligent” thermostats having more advanced HVAC control capabilities that can save energy while also keeping the occupants comfortable. In furtherance of this goal, it would be desirable to provide a thermostat whose intelligence is directed not only toward energy savings and human comfort, but whose intelligence is also directed toward making its own installation process as simple and elegant as possible, such that the average do-it-yourselfer, handyman, or other person not having special HVAC system training could undertake the thermostat retrofit process.
In U.S. Ser. No. 05/065,813, which is incorporated by reference herein, an interactive electronic thermostat with installation assistance is discussed. As part of a user-interactive installation testing process discussed therein, the user is required to provide answers to questions presented to them by the system (such as the question, “What turned on?”) about HVAC events that are currently happening. The thermostat discussed in U.S. Ser. No. 05/065,813 believed to bring about one or more disadvantages and/or to contain one or more shortcomings that are addressed and/or avoided by a thermostat provided according to one or more of the embodiments described hereinbelow. Other issues arise as would be apparent to one skilled in the art upon reading the present disclosure.
Provided according to one or more embodiments is a thermostat and related systems, methods, and computer program products for facilitating user-friendly installation thereof. Provided according to one embodiment is a thermostat for controlling the operation of an HVAC system having a plurality of wires requiring connection to the thermostat, each wire being associated with a distinct HVAC signal type. The thermostat comprises a control unit including at least one processor and at least one environmental sensor, and further includes a plurality of connection ports. Each connection port is associated with a predetermined HVAC signal type, and is configured to receive one of the plurality of wires. Associated with each connection port is a wire insertion sensing circuit that identifies to the control unit the presence or absence of an inserted wire therein. The thermostat further comprises a user interface operatively coupled to the control unit, the user interface including at least one output device for providing output information to a user and at least one input device for receiving one or more user inputs. The control unit is configured and programmed to cause the thermostat to carry out an installation verification process. In the installation verification process, the insertion sensing circuits are operated to identify a first subset of the connection ports into which wires have been inserted, the first subset of connection ports having an associated first subset of HVAC signal types. A first candidate HVAC operating function that is consistent with the first subset of HVAC signal types is identified. A first set of control signals is applied to the HVAC system through one or more of the first subset of connection ports, the first set of control signals being configured to instantiate operation of the HVAC system according to the first candidate HVAC operating function. Upon application of the first set of control signals, a first time sequence of environmental readings is acquired using the environmental sensor and processed to automatically determine, without requiring an input from the user, whether the HVAC system has successfully operated according to the first candidate HVAC operating function. An indication of an error condition is provided on the user display if the automatic determination is that the HVAC system has not successfully operated according to the first candidate operating function.
According to another embodiment, the installation verification process carried out by the thermostat further comprises receiving a first input from the user that is indicative of a completion of insertion of the required plurality of wires. Subsequent to receiving the first input, and before applying any set of operating control signals to the HVAC system including the first set of control signals, a second input is received from the user indicative of a user selection to begin normal operation of the HVAC system. Responsive to the received second input and before applying any set of operating control signals to the HVAC system including the first set of control signals, the identification of the first candidate HVAC operating function proceeds in a manner that is consistent with normal operation of the thermostat. More particularly, the first candidate HVAC operating function is assigned as a heating function or a cooling function, but only if the normal operation of the thermostat would call for such heating or cooling function (e.g., the heating function if the current temperature is less than or equal to a heating trip point temperature of the thermostat and the heating function is consistent with the first subset of HVAC signal types, and the cooling function if the current temperature is greater than or equal to a cooling trip point temperature of the thermostat and the cooling function is consistent with the first subset of HVAC signal types). Thus, the first candidate HVAC operating function is not identified, and no operating control signals are applied to the HVAC system, unless and until such operating function would be normally carried out at the currently sensed temperature.
According to another embodiment, an automated determination of a heat pump call convention is performed as part of the installation verification process for cases in which the insertion of an O/B wire was automatically detected as part of the automated wire insertion sensing process. If the first candidate HVAC operating function is a heating function, a first heat pump heating call is applied to the HVAC system according to a first heat pump call convention, and the room temperature is monitored to sense an associated temperature change. If an associated temperature rise is detected, then a conclusion is made that the heat pump heating functionality has been successfully carried out and the HVAC system has the first heat pump call convention. In contrast, if an associated temperature decrease is detected upon applying the first heat pump heating call, a second heat pump heating call is applied to the HVAC system according to a second heat pump call convention, and the room temperature is again monitored to sense an associated temperature change. If an associated temperature rise is detected, then a conclusion is made that the heat pump heating functionality has been successfully carried out and the HVAC system has the second heat pump call convention, whereas an indication of an error condition is provided on the user display if the associated temperature rise is not detected. If the first candidate HVAC operating function is a cooling function, a first heat pump cooling call is applied to the HVAC system according to the first (or second) heat pump call convention, and the room temperature is monitored to sense an associated temperature change. If an associated temperature decrease is detected, then a conclusion is made that the heat pump cooling functionality has been successfully carried out and the HVAC system has the first (or second) heat pump call convention. In contrast, if an associated temperature rise is detected upon applying the first heat pump cooling call, a second heat pump cooling call is applied to the HVAC system according to the second (or first) heat pump call convention, and the room temperature is again monitored to sense an associated temperature change. If an associated temperature decrease is detected, then a conclusion is made that the heat pump cooling functionality has been successfully carried out and the HVAC system has the second (or first) heat pump call convention, whereas an indication of an error condition is provided on the user display if the associated temperature decrease is not detected. For one embodiment, the first heat pump call convention comprises (i) for a heat pump heating call, energizing a cooling call (Y1) signal type while not energizing the heat pump (O/B) signal type, and (ii) for a heat pump cooling call, energizing Y1 while also energizing O/B, while the second heat pump call convention is a reverse of the first convention, i.e., energizing Y1 while also energizing O/B for a heat pump heating call, and energizing Y1 while not energizing O/B for a heat pump cooling call. Advantageously, the identification of the heat pump call convention is made automatically in the background, without requiring the user to manually adjust any wirings or settings, and without requiring the user to tell the thermostat what particular actions the HVAC system is taking or not taking.
It is to be appreciated that while one or more embodiments are described further herein in the context of typical residential home installations, such as single-family residential homes, and are particularly advantageous in the context of HVAC systems having relatively modest complexity, the scope of the present teachings is not so limited. More generally, thermostats according to one or more of the preferred embodiments are applicable for a wide variety of enclosures having one or more HVAC systems including, without limitation, duplexes, townhomes, multi-unit apartment buildings, hotels, retail stores, office buildings and industrial buildings. By relatively modest complexity, it is meant for some embodiments that the HVAC signal types involved in controlling the HVAC system of the enclosure are limited to the following HVAC signal types or subsets thereof: heating call (W1), cooling call (Y1), fan call (G), heat pump (O/B), common (C), auxiliary (AUX), heating call power (Rh), cooling call power (Rc), and, for some systems not having separate heating/cooling call power, a generic call power (R). It is to be appreciated that while the terms user, customer, installer, homeowner, occupant, guest, tenant, landlord, repair person, and the like may be used to refer to the person or persons who are interacting with the thermostat or other device or user interface in the context of one or more scenarios described herein, these references are by no means to be considered as limiting the scope of the present teachings with respect to the person or persons who are performing such actions.
As discussed elsewhere in the commonly assigned incorporated applications, supra, for one embodiment the thermostat 100 is controlled by only two types of user input, the first being a rotation of the outer ring 106 (
The thermostat 100 comprises physical hardware and firmware configurations, along with hardware, firmware, and software programming that is capable of carrying out the currently described methods. In view of the instant disclosure, a person skilled in the art would be able to realize the physical hardware and firmware configurations and the hardware, firmware, and software programming that embody the physical and functional features described herein without undue experimentation using publicly available hardware and firmware components and known programming tools and development platforms.
As illustrated in
According to one embodiment, wire insertion sensing circuitry 304 includes, for each connection port 302, a port sensing circuit 442 that communicates with the processor 310 over a pair of electrical leads 444. Although the port sensing circuit 442 can operate in a variety of different ways without departing from the scope of the present teachings, in one embodiment the control port sensing circuit 442 comprises a two-position switch (not shown) coupled to the electrical leads 444, the two-position switch being closed to short the electrical leads 444 together when no wire has been inserted into the associated connection port 302, the two-position switch being mechanically urged into an open position to electrically segregate the electrical leads 444 when a wire is inserted into the associated connection port 302. The processor 310 thereby is able to readily sense when a wire is inserted into the connection port by virtue of the shorted or open state of the electrical leads 444. One particularly advantageous configuration that implements the combined functionality of the connection port 302 and the port sensing circuit 442 is described in the commonly assigned U.S. Ser. No. 13/034,666, supra.
Displayed on screen 501 is a photographic aerial view 502 of the connection ports 302 as they would actually appear to the user who is about to perform the wire insertion process. Although other graphical representations of the connection ports 302 are within the scope of the present teachings, the realism afforded by the photographic aerial view 502 is preferred in that there is one less mental step required in cognitively mapping between the physical world of the actual device and the conceptual world of the screen 501, thereby decreasing the likelihood of user mistakes or misinterpretations. The photographic aerial view 502 includes an aerial image 504 of each connection port including a symbol 505 thereon representative of its associated HVAC signal type. Next to each aerial image 504 is a simplified text description 508 of its associated HVAC signal type. For any particular connection port into which a wire insertion has been detected, the associated aerial image 504 is visually highlighted, such as by using superimposed visual shading 506, emboldening of the simplified test description 508, and superimposing a wire stub icon 507 thereon.
By looking at the screen 501, the user can quickly and accurately identify (i) the HVAC signal type identity of a first subset of the connection ports 302 into which wires have been inserted, as well as (ii) the HVAC signal type identity of a second subset of the connection ports 302 into which wires have not been inserted. For the example of
One of the features and advantages of one or more of the embodiments is that one or more potentially ambiguous scenarios (for example, the heat pump call signal convention as described further infra) are automatically resolved either by automated testing, by deduction based on the HVAC signal type identity of the inserted wires, and/or by a combination of automated testing and deduction. In this way, the user does not need to be bothered with details of resolving the ambiguity, thereby making the installation process more streamlined, enjoyable, and reliable. However, for the modest-complexity collection of HVAC signal types shown in the embodiment of
For HVAC systems having a W1 signal type without a G signal type, it is possible that the HVAC system has a type of forced-air gas or oil furnace that controls its own fan actuation and therefore requires no thermostat-provided G signal type, while also being possible that the HVAC system has radiant heat (which requires no G signal type). On the other hand, for HVAC systems having a W1 signal type with a G signal type, it is possible that the HVAC system has a type of forced-air gas or oil furnace that relies on the G signal type to be provided from the thermostat, while also being possible that the HVAC system has radiant heat (with the G signal type being used for cooling system actuation only), while also being possible that the HVAC system is the particular type of forced-air gas or oil furnace that controls its own fan actuation (with the G signal type being used for cooling system actuation only). If an automated testing process for the heating functionality were used in which the G signal was withheld, and if that process were applied to an HVAC system having the type of forced-air gas or oil furnace that relies on the thermostat to provide the G signal type fan actuation, then that furnace could switch into a safety lock-out mode to prevent overheating. It has been found prudent to request the clarifying inputs from the user shown in
An automated background-only installation verification process according to an embodiment can substantially enhance the overall appeal of the thermostat 100 to users, while also providing competent functional verification of the installation for the large number of homes and other enclosures having HVAC systems of modest complexity. The automated background-only installation verification process is characterized in that, in addition to being automated (i.e., no sensory feedback is required from the user about what the HVAC system is doing), there is no artificial actuation of the HVAC system into a heating mode or cooling mode that is not actually required at the current temperature of the enclosure, but rather the thermostat 100 will wait until that function is actually needed according to the normal operation of the thermostat 100 before testing it. By normal operation, it is meant that the thermostat 100 is operating to control the enclosure temperature according to one or more predetermined comfort settings, invoking the cooling function when the sensed temperature is above a cooling trip point and invoking the heating function when the sensed temperature is below a heating trip point, wherein the heating and cooling trip points (or equivalent settings such as temperature set point and swing levels) are not artificially modified for sole purpose of invoking a particular heating or cooling call.
For cases in which the user has not yet interacted with the thermostat 100 to establish their comfort preferences (e.g., in a setup interview), the thermostat 100 can use some conventional default comfort settings to begin the normal operation, such as a heating trip point of 66 degrees and a cooling trip point of 80 degrees. Notably, it may not always be necessary to begin with conventional default comfort settings, since the user may have interacted with the thermostat 100 prior to wiring the thermostat to enter their various comfort preferences, and/or may have, in accordance with another embodiment currently disclosed and/or disclosed in one or more of the above-referenced commonly assigned applications, entered their preferences on a web site provided by the manufacturer who then programmed in those preferences before shipping the unit to the customer.
If no known erroneous signal combination is present at step 608, then the method proceeds with determining whether there are any known ambiguous HVAC signal type combinations presented by comparing the first subset of HVAC signal types to information representative of known ambiguous HVAC signal type combinations. For reasons relating to the above description for
At step 620, a first candidate HVAC operating function that is consistent with the first subset of HVAC signal types is identified. According to one embodiment in which the automated installation verification is also a background-only process, the first candidate HVAC operating function is selected as a heating function if the current temperature is less than or equal to a normal operating heating trip point temperature of the thermostat and the heating function is consistent with the first subset of HVAC signal types, and is selected as a cooling function if the current temperature is greater than or equal to a normal operating cooling trip point temperature of the thermostat and the cooling function is consistent with the first subset of HVAC signal types, and if the temperature is such that neither of these criteria are met right away, the process halts until the temperature actually changes (and/or the normal comfort settings are changed) to a point where the normal heating or cooling triggers would be sent to the HVAC system. Thus, no operating control signals are sent to the to the HVAC system to activate heating or cooling unless and until such heating or cooling operation would be normally carried out at the currently sensed temperature according to the normal operation of the HVAC system.
It is to be appreciated that while background-only automated installation verification represents one particularly useful embodiment, the scope of the present teachings is not so limited. Thus, for example, in another embodiment a capability is provided in which the user can affirmatively request that the automated installation verification be carried out immediately. For such embodiment, the user would able to enjoy the benefit of not being required to stand by and tell the thermostat what the HVAC system is doing. This may be particularly convenient if the user plans on stepping out for a while. Notably, however, if the user is planning on staying inside during the automated testing, they should be prepared for the possibility that the HVAC system may drive the enclosure toward artificially uncomfortable temperatures for a period of time (e.g., the heating operation may be invoked on hot day to make an already-warm room hotter, or the cooling operation may be invoked on cold day to make an already-cool room colder).
At step 622, a first set of control signals is applied to the HVAC system through one or more of the first subset of connection ports, the first set of control signals being configured to instantiate operation of the HVAC system according to the first candidate HVAC operating function. Also at step 622, upon the application of the first set of control signals, a first time sequence of temperature readings is acquired and processed to automatically determine, without requiring an input from a user, whether the HVAC system has successfully operated according to the first candidate HVAC operating function.
At step 622, if the candidate HVAC operating function is forced air heating using an electric furnace, the first set of control signals includes energizing W1 and G together, if G is present, and the time period needed for affirming that the enclosure is successfully heating up at step 624 will typically be between 5-10 minutes and usually not more than 15 minutes. For forced air heating using a gas or oil furnace, the first set of control signals includes energizing W1 and energizing G if G is present and required, and the time period to affirm success at step 624 is also about 5-10 minutes and usually not more than 15 minutes. For radiant heating, the first set of control signals includes energizing W1 alone in all cases, and the time period needed at step 624 for affirming that the enclosure is successfully heating up will typically be between 30-60 minutes and usually not more than 90 minutes. For cooling without a heat pump, the first set of control signals includes energizing W1 and G together, if G is present, and the time period needed at step 624 for affirming that the enclosure is successfully cooling down will typically be about 20 minutes. For heating or cooling using a heat pump, the steps 622-628 are carried out according to a process that is more specifically set forth in
If it is determined at step 624 that the candidate HVAC operation did not occur, then at step 626 an error condition is indicated on the user interface. If it is determined at step 624 that the candidate HVAC operation did indeed occur, then at step 628 it is determined that the wiring and actuation associated with that candidate HVAC operation, as well as the underlying capability of the HVAC system itself, are all confirmed. The method then proceeds with identifying the next candidate HVAC function at step 620, which will generally be the opposing function (cooling or heating, respectively) to the function that was just verified (heating or cooling, respectively). Notably, for embodiments in which the automated installation verification is also a background-only process, the next candidate HVAC operation might not actually be verified for days, weeks, or even months depending on the time of year that the thermostat 100 is installed. For example, if thermostat 100 is installed in the midwestern United States in December, the heating functionality may be verified right away, while it may not be until May or June until the temperature gets warm enough that the cooling functionality is automatically tested. In view of the relatively large number of cases that are expected to turn out successfully for modest-complexity HVAC system, it is believed that both the small-scale and large-scale energy-saving benefits promoted by the elegance, simplicity, and user-friendliness afforded by the background-only installation verification process (i.e., faster adoption of the thermostat 100 by a larger number of customers) will outweigh the disadvantages of any delayed installation problem discovery that may take place.
A monitoring period of about 10-20 is usually sufficient for a determination to be made regarding whether the temperature of the enclosure is rising or falling (step 712). If the enclosure temperature is indeed found to be rising, then a conclusion is made that the heat pump heating functionality has been successfully carried out and the HVAC system has the first “O” heat pump call convention (step 714). In contrast, if an associated temperature decrease is detected, then at step 716 a second heat pump heating call is applied to the HVAC system according to the “B” heat pump call convention, and the room temperature is again monitored (step 718) to sense an associated temperature change. If an associated temperature rise is detected, then a conclusion is made that the heat pump heating functionality has been successfully carried out and the HVAC system has the second “B” heat pump call convention (step 720), whereas an indication of an error condition is provided on the user display (step 722) if the associated temperature rise is not detected.
If the first candidate HVAC operating function is a cooling function, then at step 724 a first heat pump cooling call is applied to the HVAC system according to the “O” heat pump call convention, and the room temperature is monitored to sense an associated temperature change (step 726). For an “O” convention heat pump cooling call, the Y1 signal type is energized with the O/B signal type is also energized, while for an opposing “B” convention heat pump cooling call the Y1 signal type is energized while the heat pump (O/B) signal type is not energized. If an associated temperature decrease is detected, then a conclusion is made that the heat pump cooling functionality has been successfully carried out and the HVAC system has the “O” heat pump call convention (step 728). In contrast, if an associated temperature rise is detected upon applying the first heat pump cooling call, a second heat pump cooling call is applied to the HVAC system according to the “B” heat pump call convention (step 730), and the room temperature is again monitored to sense an associated temperature change (step 732). If an associated temperature decrease is detected, then a conclusion is made that the heat pump cooling functionality has been successfully carried out and the HVAC system has the “B” heat pump call convention (step 734), whereas an indication of an error condition is provided on the user display (step 736) if the associated temperature decrease is not detected. Advantageously, the identification of the heat pump call convention is made automatically in the background, without requiring the user to manually adjust any wirings or settings, and without requiring the user to tell the thermostat what particular actions the HVAC system is taking or not taking.
Whereas many alterations and modifications of the present invention will no doubt become apparent to a person of ordinary skill in the art after having read the foregoing description, it is to be understood that the particular embodiments shown and described by way of illustration are in no way intended to be considered limiting. By way of example, while one or more of the above-described embodiments includes an inquiry to the user regarding whether the HVAC system has forced-air heat versus non-forced air (radiant) heat, in alternative embodiments this determination can be made empirically based on an initial test run of the HVAC heating functionality. According to one alternative embodiment, a time series of temperature readings acquired after instantiation of the HVAC heating operation is numerically processed to make an automated determination, without requiring an input from the user, regarding whether the HVAC system has forced-air heat versus non-forced air (radiant) heat. Preferably, the determination is based on both (i) the overall time that was needed to reach a target temperature (forced-air can typically take 5-15 minutes for an initial heating of an enclosure whereas radiant heat can typically take 30-60 minutes), as well as (ii) the particular shape of a graphical plot of temperature versus time (the forced-air curve can often have a more linear character than the radiant heat curve). Any of a variety of classification methods or other automated decision-making algorithms can be used, including systems that can be “trained” using a population of temperature-versus-time plots for a large number of enclosure-heating scenarios taken over a large population of real-world HVAC systems for which each relevant truth (i.e., whether it is forced-air heat versus radiant heat) is known. Therefore, reference to the details of the embodiments are not intended to limit their scope.
This application is a continuation of U.S. patent application Ser. No. 13/038,191 filed Mar. 1, 2011, which claims the benefit of U.S. Prov. Ser. No. 61/429,093 filed Dec. 31, 2010 and U.S. Prov. Ser. No. 61/415,771 filed Nov. 19, 2010, each of which is incorporated by reference herein. The subject matter of this patent specification relates to the subject matter of the following commonly assigned applications: U.S. Ser. No. 12/881,430 filed Sep. 14, 2010; U.S. Ser. No. 12/881,463 filed Sep. 14, 2010; U.S. Ser. No. 12/987,257 filed Jan. 10, 2011; U.S. Ser. No. 13/034,666 filed Feb. 24, 2011; U.S. Ser. No. 13/034,674 filed Feb. 24, 2011; and U.S. Ser. No. 13/034,678 filed Feb. 24, 2011. Each of the above-referenced patent applications is incorporated by reference herein. The above-referenced patent applications are collectively referenced hereinbelow as “the commonly assigned incorporated applications.”
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Number | Date | Country | |
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20140346239 A1 | Nov 2014 | US |
Number | Date | Country | |
---|---|---|---|
61429093 | Dec 2010 | US | |
61415771 | Nov 2010 | US |
Number | Date | Country | |
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Parent | 13038191 | Mar 2011 | US |
Child | 14292642 | US |