The present invention relates to network-based energy management network (EMN). More specifically, the present invention relates to a system and method for quickly configuring subscribers on the EMN.
According to an embodiment of the invention, there is a method for creating or updating a provisioning record for a subscriber on an energy management network, the method comprising:
According to another embodiment of the invention, there is provided a controller for operating HVAC equipment on a premise, the controller having a display, a processor, memory, and a RF module for communication with a home automation network, wherein the controller is operable to temporarily display at least one controller identifier, the at least one controller identifier being associated with the premise, and the at least one controller identifier is adapted to be used in the creation or updating of a provisioning record.
According to another embodiment of the invention, there is provided a mobile device equipped with identifier-sensing equipment, the mobile device being adapted to digitally record data for updating a provisioning record on an energy management server, the data being recordable including at least one controller identifier being displayed on a controller for operating HVAC equipment, and the mobile device being further adapted to transfer data which includes the at least one controller identifier to the energy management server providing service on the energy management network for the creation or updating of the provisioning record.
Embodiments will now be described by way of example only, with reference to the following drawings in which:
Referring now to
Controller 22 is adapted to control HVAC equipment 30 as well as other electrical devices 14, which are typically also located within or proximate to premise 12, and described in greater detail below. Controller 22 is often colloquially referred to as a ‘smart thermostat’, but of course may also regulate HVAC functions other than temperature. HVAC equipment 30 can include furnaces, air conditioning systems, fans, heat pumps, humidification/dehumidification systems and the like. Controller 22 can be connected to HVAC equipment 30 using a hard-line connection (such as a 4-wire connector), a wireless connection, or a combination of the two. In some configurations, an equipment interface module (EIM) 32 can be provided as an interface between the controller 22 and HVAC equipment 30. The EIM 32 receives commands from the controller 22 across the hard-line or wireless connection, and then activates or deactivates the appropriate relays required to control the HVAC equipment 30. In addition, the EIM 32 includes detectors operable to monitor the operational status of HVAC equipment and transmit error codes and conditions back to controller 22.
Electrical devices 14 include any number of electricity-consuming devices that are directly controlled by controller 22 or are connected to controller 22 via a network plug 16, Network plugs 16 either plug directly into standard electrical outlets (not shown) within premise 12 or replace standard electrical outlets entirely. Electrical devices 14 and/or network plugs 16 communicate directly with controller 22 via a home automation network 15 (such as ZigBee HA), and can be provided with current sensors and/or controllers to measure real-time electrical consumption of the attached device. Furthermore, network plugs 16 can regulate electrical consumption in an attached device, typically in a binary ON/Off fashion.
Other types of electrical devices 14 can include an energy measurement device 18. Examples of energy measurement devices 18 include smart utility meters or current transducers (CT) that are connected to the main circuit of an electrical panel (not shown) in premise 12. The CT would be operable to measure the actual total electricity consumed at the premises, independent of a meter. The CT would further be operable to transmit the consumption wirelessly to controller 22 through the HAN 15. In some cases, a premise 12 could be equipped with multiple HANS 15, each operating according to its own frequencies and/or protocols (such as ZigBee HA and ZigBee SE)
Referring now to
Referring now to
Processor 44 is adapted to run various applications 56, many of which are displayed on touch screen display 40 (
RF subsystem 48 includes a Wi-Fi chip 62 operably connected to a Wi-Fi antenna 64. In the presently-illustrated embodiment, Wi-Fi chip 62 support 802.11b/g communication to a router within range that is connected to network 28. As currently-illustrated, Wi-Fi chip 62 supports encryption services such as WPA, WPA2 and WEP. Other networking protocols such as 802.11a or n, or 802.16 (WiLan), as well as other encryption protocols are within the scope of the invention. RF subsystem 48 can further include other wireless communication subsystems and controllers, such as cellular communication subsystems, and/or home automation networks based upon Bluetooth networking, Zigbee networking, such as Zigbee Home Automation (HA) or Smart Energy (SE), ERT or IR networking. It is contemplated that RF subsystem 48 can include multiple radios, antennas and/or chipsets to support multiple protocols such as concurrent support of both Zigbee HA and Zigbee SE.
I/O interface 50 provides the physical connectors for controller 22. For example, I/O interface 50 may include the connectors for a 4-wire connection to HVAC equipment 30 (FIG. 1). I/O interface can also include a debug port, a serial port, DB9 pin connector, a USB or microUSB port, or other suitable connections that will occur to those of skill in the art. Power source 52 provides electrical power for the operation of controller 22 and can include both wire-line power supplies and battery power supplies. In the presently-illustrated embodiment, the four-wire connection to I/O ports 50 can also provide the necessary power for controller 22, as well as any necessary surge protection or current limiters. Power source 52 can also include a battery-based back-up power system. In addition, power source 52 may provide a power connection jack which allows the controller 22 to be powered on without being connected to the 4 wire connection, or relying upon battery backup. In the presently-illustrated embodiment, power source 52 further includes a current sensor 53 that is operable to measure the current draw of power source 52. Also in the presently-illustrated embodiment, power source 52 includes a voltage sensor 55 that is operable to measure the voltage at power source 52.
In addition, controller 22 can include one or more expansion slots or sockets 66. The expansion slot/socket 66 is adaptable to receive additional hardware modules to expand the capabilities of controller 22. Examples of additional hardware modules include memory expansion modules, remote sensor modules, home automation modules (to communicate with the electrical devices 14 over the HAN 15 via Zigbee HA or other such protocol), smart meter modules (to communicate over the HAN 15 with the energy measurement device 18), etc. The expansion slot/socket 66 could include an additional RF component such as a Zigbee® or Zwave™ module. The home automation module would allow capabilities such as remote control of floor diffusers, window blinds, etc. The combination of remote sensing and remote control would serve as an application for Zoning temperature Zone control.
Environmental sensor(s) 54 is adapted to provide temperature and humidity measurements to the processor 44. In the presently-illustrated embodiment, environmental sensor 54 is an integrated component, but could also be separate thermistors and hydrometers. It is contemplated that environmental sensor 54 could include additional sensing capabilities such as carbon-monoxide, air pressure, smoke detectors or air flow sensors. Other sensing capabilities for environmental sensor 54 will occur to those of skill in the art. The environmental sensor 54 may be built near vents located near the “bottom” of housing 34 (relative to when controller 22 is mounted on a wall) so as to minimize the effects of waste heat generated by the hardware of controller 22 upon environmental sensor 54.
Controller 22 can include additional features, such as an audio subsystem 68. The audio subsystem 68 can be used to generate audible alerts and input feedback. Depending on the desired features, audio subsystem 68 can be adapted to synthesize sounds or to play pre-recorded audio files stored in memory 46.
Another additional feature for controller 22 is a mechanical reset switch 69. In the presently-illustrated embodiment, mechanical reset switch 69 is a microswitch that when depressed either restarts the controller 22 or reinitializes the controller 22 back to its original factory condition.
Controller 22 may be operable to communicate with one or more remote sensors 70 that are distributed around the inside and/or the outside of premise 12. Remote sensors 70 are operable to provide remote sensor data for temperature, humidity, air flow, HVAC system monitoring (such as discharge and return air) and/or CO2. Within premise 12, multiple remote sensors 70inside are typically used to provide zone control, or averaged space temperature across multiple remote sensors 70. A remote sensor 70outside located outside the premise is used to provide weather information. In particular, remote sensor 70outside can provide local outdoor temperature, humidity, air pressure and/or air flow measurements, which can be used as inputs in the control algorithms of ECP 96 (described in greater detail below). Remote sensors 70 can also be used to monitor non-HVAC devices such as fridges or freezers. Remote sensors 70 can also include I/O modules that convert hardwired dry contact inputs to wireless signals that are sent back to controller 22, or conversely takes ON/OFF signals from the controller and transmits them wirelessly to this module. This module can then turn ON/OFF device locally to the module, in the manner described above with reference to smart plugs 16. Inputs for these remote sensors 70 can include flood sensors, door/window sensors, motion or other occupancy sensors, alarm system relays or KYZ pulse counter. Outputs for these remote sensors 70 can include Occupancy switches for lighting systems, HVAC Economizers, other HVAC switches, non-plug form factor loads (pool pumps, water tanks), etc.
Referring back to
The remote device 24, and most typically the personal computer 72 may connect to network 28 using either a wire-line connection or a wireless connection, for example. The personal computer 72 can be loaded with an appropriate browsing application for accessing and browsing the environmental web service 26 via network 28. Personal computer 72 is operable to run one or more PC applications 56PC (not illustrated), which can include web-based applications. As will be described in greater detail below, the PC applications 56PC are akin to the applications 56 found on controller 22, and generally provide similar functionality. However, PC applications 56PC are reformatted to account for the particular display and input characteristics found on personal computer 72. For example, a personal computer 72 may have a larger screen, and a mouse or touchpad input. It is also contemplated that PC applications 56PC may have greater or reduced functionality in comparison to their counterparts, applications 56.
The environmental web service 26 may be owned by a separate organization or enterprise and provides web portal application for registered users (typically the owners of controllers 22). Environmental web service 26 acts as a web server and is able to determine and deliver relevant content to controllers 22 and to remote devices 24 (i.e., personal computers 62 and mobile devices 64). For example, environmental web service 26 may deliver applications 56, 56remote and 56PC to any accessing device using the appropriate internet protocols. In effect, environmental web service 26 allows the controller 22 to communicate with remote devices 24. Environmental web service 26 may also transfer data between its own content databases, controllers 22 and remote devices 24. Environmental web service 26 is further operable to enable remote or web-based management of controller 22 from a client using the aforementioned remote device 24. Environmental web service 26 provides the set of web widgets and that provides the user interface for users of remote devices 24. It is further contemplated that environmental web service 26 is operable to provide remote software updates to the applications 56 over network 28. Environmental web service 26 may further includes an energy modelling server 86 that is operable to query aggregate data warehouse 84 and customer account data 80 to provide energy modelling services for customers
Another component of EMN 20 is electrical utility 88. Utility 88 provides electrical power to premise 12 through a transmission network (not depicted). As will be described in greater detail below, utility 88 is also able to transmit Time of Use (TOU) pricing information, critical peak power (CPP) and/or demand response (DR) events to controller 22. TOU pricing, CPP and DR events can be transmitted to controller 28 via environmental web service 26 through network 28. Alternatively, TOU pricing, CPP and DR events can be transmitted directly to an energy measurement device 18 via a cellular network or other means (not shown), where it can then be transmitted to controller 22 across the home automation network. Utility 88 includes one or more energy management servers 160. Energy management servers 160 maintain all the data needed to manage customer accounts, demand response policies, billings and equipment deployment records. This data includes provisioning records 158 for each premise 12. As will be described in greater detail below, provisioning records 158 contain unique identifiers for the energy management equipment installed on each premise 12. While the above-described functions will often be distributed between numerous servers, for the ease of illustration are shown as a single energy management server 160. While it is contemplated that the energy management server 160 will be operated by utility 88. Alternatively, energy management server can be operated by a third-party HVAC contracting company or a building services company that is providing environmental web services 26.
Controller 22, and in particular, in cooperation with the other components of EMN 20, can provide climate control functionality beyond that of conventional thermostats through the running of applications 56 on controller 22 and/or the running of applications 56remote, 56PC, etc. on their respective remote devices 24. Referring back to
ECP 96 is operable to display and regulate environmental factors within a premise 12 such as temperature, humidity and fan control by transmitting control instructions to HVAC equipment 30. ECP 96 displays the measured current temperature and the current temperature set point on touch screen display 40. ECP 96 may also display the measured current humidity and/or humidity set point (not currently illustrated). Alternatively, ECP 96 may simply indicate when HVAC equipment 30 is actively providing humidification. ECP 96 may also include an ECP Details program 96a, which provides additional control over ECP 96. In addition, ECP 96 maintains historical record data of set points and measured values for temperature and humidity. These can be stored locally in memory 46, or transmitted across network 28 for storage by environmental web service 26 in aggregate data warehouse 84.
ECP 96 may be manipulated by a user in numerous ways including a Scheduling program 106, a Vacation Override program 108, a Quick Save override program 110 and a manual temperature adjustment through the manipulation of a temperature slider 112. As shown in
Weather program 98 (
Energy use program 100 (
Remote sensor program 102 allows users to view, configure and control remote sensors 70 that are distributed around the inside and/or outside of premise 12. Using the remote sensor program 102, a user can change the on-screen name of specific remote sensors 70, as well as view and control the averaging of any remote sensor 70. Remote sensor program 102 may also send alerts (onscreen, or to e-mail) for remote devices indicating a low battery condition, indicating that the device will require a battery replacement soon. In addition, a similar alert can be sent out if a device has been successfully connected, but the thermostat has lost communications to that device for a predetermined period of time, an alert should be generated to advise the user. When remote sensors 70 are not utilized, then the remote sensor program 102 may be either dimmed out or not present on the touch screen display 40.
Configuration program 104 (alternatively called “Settings”) allows a user to configure many different aspects of their controller 22, including Wi-Fi settings, Reminders and Alerts, Installation Settings, display preferences, sound preferences, screen brightness and Password Protection. Users may also be able to adjust their own privacy settings, as well as configure details pertaining to their HVAC equipment 30, such as the type and manufacture of the furnace, air conditioning and/or humidification system. In addition, users of Configuration program 104 may be able to specify certain physical and environmental parameters of their premise 12, such as the size of premise 12, or the number of inhabitants of premise 12. Additionally, a user may be able to specify the type of construction and materials used for window panes 16, such as single or double paned, argon filled, etc. Other aspects of controller 22 that can be modified using the Configuration program 104 will occur to those of skill in the art.
Plugs program 126 allows users to configure many different aspects of their electrical devices 14 and smart plugs 16. When selected (
Selecting the More icon 140, the user can access additional features. For example, the user can modify options in the Preferences menu 142. An example of the Preferences menu 142, formatted for a personal computer 72 is shown in
Using the More icon 140, the user can also access Reports program 150. Using Reports program 150, the user can also see graphical reports for that particular electrical device 14 in greater detail, such as hourly, daily, weekly or monthly reports of energy consumption or cost.
Electrical devices 14 capable of joining the HAN 30, such as smart plugs 16, need to be connected to controller 22. In the presently-illustrated embodiment, devices can join HAN 30 in two ways. In the first way, upon power-up, the electrical device 14 automatically looks for a HAN 30 to join. Alternatively, the device could require that user actuate a manual switch before it begins to seek a HAN 30. Controller 22 may also include a Setup program that initiates a search for connectable electrical devices 14 to be joined to HAN 30.
As mentioned previously, it is contemplated that some electrical devices 14 connected to HAN 30 will follow a Device scheduling program 144 (
The Device scheduling program 144 includes one or more periods 146 (146A, 146B, etc.). However, rather than have a temperature setting, each device period 146 would typically have an operational state, such as OFF or ON (for electrical devices 14 that operate in a binary fashion). For electrical devices 14 which operate in a non-binary fashion, other operational states such as HIGHH/MEDIUM/LOW, or duty cycle percentages. Alternatively, electrical devices 14 could have temperature set point settings (for example, a pool heater).
As mentioned above, this Device scheduling program 144 can be unique to the individual electrical device 14, or can be linked to the HVAC schedule. In the current embodiment, the controller 22 prompts the user to select either linked scheduling or unlinked scheduling. When linked scheduling is selected, the Device scheduling program 144 is divided into device periods 146 that correspond to the usage periods 114 of the HVAC schedule in Scheduling program 106. For example, if Scheduling program 106 includes an “Awake” period from 7:00 AM to 9:00 AM on all weekdays, Device scheduling program 144 would create a device period 146B for 7:00 AM to 9:00 AM on all weekdays. The user would then define an operational state for the device period 146B as either ON or OFF. The user could subsequently define the operational state (ON or OFF) for each remaining device period 146B, 146C, etc. The time ranges for each device period 146 in Device scheduling program 144 would be updated automatically as the primary HVAC schedule was updated. Any overrides to the HVAC programming would carry over and be applied to the Device scheduling program 144 as well. As with the HVAC schedules, controller 22 may have separate device scheduling programs 144 that correspond to when the HVAC equipment 30 is in heat mode and in cool mode.
When Device scheduling program 144 is not linked to the HVAC schedule, each electrical device 14 can follow its own unique 7 day schedule, with its own periods that may or may not correspond to those of the HVAC schedule. When unlinked, each Device scheduling program 144 has its own independent overrides. Device scheduling program 144 may also usage link device periods 146 to sunrise or sunset. For example, an electrical device 14 such as an outdoor light might be switched to ON thirty minutes after sunset. Sunrise and sunset data could be retrieved from ECP 96 (or other remote source), or could be calculated using the controllers own internal clock and any latitude/longitude coordinates stored in its configuration file.
It is contemplated that the Vacation Override program 108 (
Another program provided by the More icon 140 is a Provisioning application 128. When selected, Provisioning application 128 displays a graphical representation 154 of at least one identifier 156 for the controller 22 (
At step 202, the user selects which electrical devices (typically smart plugs 16) are to be programmed.
At step 204, the user selects whether the selected electrical devices 14 will be linked to the HVAC schedule, or will be unlinked.
At step 206, the user selects the operational state (i.e., whether the selected electrical devices 14 will be ON or OFF) for each of the periods 146.
At step 208, the user selects which day(s) of the week will be included in the device program 144.
At step 210, the user can create a number of device periods 146.
At step 212, the device scheduling program is shown in graphic format illustrating when the electrical devices 14 are ON or OFF.
While the above method for programming a device scheduling program only shows binary ON/OFF options for the electrical devices 14, those of skill in the art will recognize that other operational states for the electrical devices 14, such as duty cycle or time percentages or set points, could be implemented similar manner.
It is contemplated that users may wish to modify their existing Scheduling programs 106 and/or device programs 144 in response to changing energy prices provided by their utility 88. Changing energy prices can include dynamic pricing, time-of-use (TOU) pricing and/or demand response (DR) events. TOU pricing (as defined by the utility 88) can be transmitted to controller 22 either directly or via environmental web portal 26, as discussed above. With dynamic pricing, electrical rates can change based upon current demand, but not according to predetermined, fixed periods. With TOU pricing, electrical rates move between fixed pricing tiers at fixed intervals based upon the time of day and/or day of the week. TOU pricing includes a tier schedule (i.e., the start and end times of each pricing tier) and tier prices (i.e., the electrical rate charge for each pricing tier). In the currently-illustrated embodiment, TOU pricing information such as the tier schedule and the tier prices can be displayed by the user using the energy use program 100. Furthermore, during the regular operation of controller 22, the current pricing tier and tier price is displayed on touch screen display 40.
TOU tier schedules and tier prices can be provided to controller 22 directly from utility 88 or through the environmental web portal 26. Alternatively, users can manually input a tier schedule and tier prices using energy use program 100 (
At a basic level, users will be able adjust their temperature set points and device states (ON/OFF, etc) based upon the pricing tier or the dynamic price. For example, the user could create different temperature set points in the Scheduling program 106 for the “Awake” period 114, one for each of the Low, Medium and High price tiers. By default, the normal Scheduling program 106 would be the defaults to the set points for the low price tier. As with the normal, non-TOU Scheduling program 106, the temperature set points can be adjusted for both the heat and cool modes. When changes are made to the temperature set points based upon TOU pricing, then preheating and cooling is typically be disabled by controller 22.
For Device scheduling program 144, the user could set the device period 146B to be ON for the low price tier, and OFF for the Medium and High price tiers. tiers. By default, the normal Device scheduling program 144 would be the default schedule for the low price tier. As with the normal, non-TOU Device scheduling program 144, the operating state for each period 146 can be adjusted for both the heat and cool modes.
On the home screen, during a TOU price adjustment, the user will see the adjusted operating state. As well the program button will be replaced by the resume button. As well in the text field (below Heat, Auto etc) notification of the current price tier will be displayed (High, Med., Low). If a manual adjustment of the temperature set point is requested by the user, or if the user presses the Resume button, then a warning message will appear on the touch screen display 40 to verify whether the user wishes to cancel the TOU override.
It is contemplated that the method described above will not always appeal to users, and in some cases, more granular control is desired. Referring now to
At step 302, the user selects the Scheduling program 106 (illustrated in
At step 304, the Scheduling program 106 automatically creates new usage periods 114 based upon where the pricing tier overlays 120 bisect existing usage periods 114. For example, in the scheduling program shown in
When the different usage periods are color coded (blue, orange, green, etc.), it is contemplated that the Scheduling program 106 may use subtle variations in the colour to indicate the pricing tier for each of the new usage periods 114. In the currently-illustrated example, usage period 114C-1 could be a light orange (indicating that it falls within the low pricing tier 122), usage periods 114C-2 and 114C-4 could be a mid-tone orange (mid price tier 124), and usage period 114C-3 could be a dark orange (high price tier 125). Other coloring schemes to indicate different pricing tiers will occur to those of skill in the art.
By default, the temperature set points for each of the new usage periods 114 defaults to the temperature set point of the old temperature set point. Alternatively, the temperature set points for each off the new usage periods 114 can be offset from the old temperature offset by a fixed (or user-adjusted) amount, or be set to a new, fixed temperature value.
At step 306, the user can manually adjust the temperature set points for each of the new or old usage periods 114. The method of manually-changing the temperature set point is not particularly limited. For example, on the controller 22, simply by touching the new usage period 114 using the touch screen display 40 the user can bring up set point adjustment indicia, slider, buttons, toggles, etc. (not shown). Alternatively, a set point adjustment window could be displayed onscreen (also not shown). if the user is interacting with the Scheduling program 106 using a personal computer 72, then selection of a usage period 114 is typically made with a mouse or other pointing device. When finished, the user simply exits the Scheduling program 106.
It is contemplated that TOU price scheduling can also be enabled when the user creates a Scheduling program 106 using the wizard 118. In such a case, the user will create a Scheduling program 106 (using the Editor 116 or the Wizard 118) having usage periods 114 that correspond to their natural behaviours and activities. If the user enables TOU price scheduling (or if it is already enabled), then the Scheduling program 106 will automatically subdivide the usage periods 114 into new usage periods. The user will then be able to manually adjust the newly-created usage periods in the manner described above.
While the aforementioned method and example illustrates the implementation of TOU price scheduling for the Scheduling program 106, it will be apparent that such a method can also be implemented for the Device scheduling program 144. When TOU price scheduling is implemented, the device periods 146 are also subdivided based upon their bisection by the pricing tier overlays 120. The operating state (e.g., ON/OFF) associated with each device period 146 can then be subsequently manually adjusted. If Device scheduling program 144 is linked to Scheduling program 106 (as is described above), then the Device scheduling program 144 will automatically implement TOU price scheduling and subdivide the existing device periods 146.
It is contemplated that utility 88 may sponsor or subsidize the purchase, installation and provisioning of controllers 22 within a premise 12, so that the premise owners may use the controllers 22 to benefit from an energy management device 18 which is also installed on premise 12. For each premise owner who has a controller 20 and who subscribes to EMN 20, a provisioning record will need to be created (or updated, if already existing). Referring now to
At step 402, the controller 22 is installed on the premise, and connected to the HVAC equipment 30. In many installs, controller 22 will be paired or configured to communicate directly with energy management device 18 over HAN 15 (i.e., controller 22 will be operable to receive and display real-time energy consumption data). When controller 22 is not paired to configured to communicate with energy management device 18 over HAN 15, indirect communication could also occur. In such cases, the energy management device 18 communicates directly with the utility 88 over network 28 or cellular network 76. Utility 88 could then communicate indirectly with controller 22 over network 28.
Those of skill in the art will recognize that steps 400 and 402 are substantially independent of each other so that each can be installed in either order, or simultaneously with each other, possibly by different persons or contracting companies. Neither the installer who performs step 402 or the utility 88 may have incomplete knowledge (or no knowledge) about the equipment being installed on premise 12 such as the model number(s) or serial number(s) of energy management device 18 or controller 22. As such, utility 88 needs to create the provisioning record 158 for the premise 12 (or update an existing provisioning record 158 already stored in energy management server 160).
At step 404, an installer records an EMD identifier 162 provided by energy management device 18. The EMD identifier 162 can be presented in an alphanumeric or in a graphical format such as a bar code or QR code. Typically, the EMD identifier 162 is a serial number on the device. Alternatively, the EMD identifier 162 can be a MAC address, or a unique installation code used to enable the networking of energy management device 18 over HAN 15.
The means of implementing step 404 are not particularly limited. In the presently-illustrated embodiment, the installer records the EMD identifier 162 using a mobile device 164 having identifier-sensing functionality. The mobile device 164 could be a smart phone, tablet or dedicated device. The identifier-sensing functionality could be provided by an optical reader, a bar code scanner or an NFC scanner connected to or integrated with the mobile device 164. Other implementations of a mobile device 164 with identifier-sensing functionality will occur to those of skill in the art. Alternatively, the installer could type in the EMD identifier 162 (with the potential for data entry errors). Typically, the EMD identifier 162 can be found on the housing of the energy management device 18, or the packaging for the energy management device 18. Alternatively, the EMD identifier 162 can be displayed temporarily on a display (if the energy management device 18 provides that capability). In some instances, the EMD identifier 162 may be pre-populated into the provisioning record 158 stored on energy management server 160 (possibly even prior to the installation of the energy management device 18). In these cases, step 404 may be omitted or skipped.
At step 406, the installer records at least one controller identifier 154 using the mobile device 164. In the currently-illustrated embodiment, the controller identifier 154 is temporarily displayed on the display 40 by activating the Provisioning application 128 (
At step 408, the installer can review, edit or supplement the data for provisioning record 158 recorded on mobile device 164.
At step 410, the data for the provisioning record 158 containing the at least one identifier (i.e., the EMD identifier, the controller identifier 154 or both) is transferred to the energy management server 160. In the presently-illustrated embodiment, the data for the provisioning record 158 (including the controller identifier 154) can be transferred almost immediately to energy management server 160 using the mobile device 164 and the URL stored in the controller identifier 154 via cellular network 76, or other such means. Alternatively, the data for provisioning record 158 can be held in the memory of the installer's mobile device 164 to be later transferred to energy management sever 160 as part of a batch process when the installer returns from the installation on premise 12.
At step 412, the energy management server 160 updates the provisioning record 158 with the data received from mobile device 164. The controller identifier 154 and the EMD identifier are now associated with the premise 12 in provisioning record 158. The subscriber to EMN 20 at premise 12 can participate fully in any smart grid or demand response program being run by the utility 88.
It is contemplated that the above method may be used in part when dealing with hardware updates or repairs. For example, if a Zigbee module located in expansion slot/socket 66 is defective, an installer would simply replace the module in the already-installed controller 22, and perform the task described in steps 406-410.
Although an energy management network with quick subscriber provisioning has been used to establish a context for disclosure herein, it is contemplated as having wider applicability. Furthermore, the disclosure herein has been described with reference to specific embodiments; however, varying modifications thereof will be apparent to those skilled in the art without departing from the scope of the invention as defined by the appended claims.