SYSTEMS AND METHODS FOR BALANCING AN ELECTRICAL GRID WITH NETWORKED BUILDINGS

Abstract

An electrical power grid includes multiple, networked buildings that receive electrical power from one or more power generation sources. A networking control system communicates with a utility control center to obtain information regarding the amount of power being supplied by the power generation sources. The networking control system further obtains information from one or more building automation controllers that are controllably associated with a plurality of networked buildings. The networking control system determines whether the total amount of power being supplied exceeds a total demand load for the plurality of buildings. And if so, the networking control system commands one or more of the building automation controllers to operate one or more of the buildings a reduced energy efficiency level, which may take the form of an optimization curve.

Claims

1. A method for controlling power consumption of a plurality of networked buildings, the method comprising: receiving information from a utility control center regarding a total amount of power presently being supplied by one or more power generation sources to the networked buildings; receiving information from a plurality of building automation controllers characterizing the total power load presently demanded by the networked buildings; determining whether the total amount of power presently being supplied exceeds the total power load presently demanded; and in response to determining that the total amount of power presently being supplied exceeds the total power load presently demanded, transmitting instructions to at least one of the building automation controllers to demand one or more power generation sources to increase the power supplied to at least one of the networked buildings for a predetermined finite period of time.

2. The method of claim 1, further comprising determining a reduced rate pricing structure for networked buildings permitting energy efficiency reduction during selected time periods.

3. The method of claim 1, wherein transmitting instructions includes providing a predetermined optimization curve to be utilized by one or more of the building automation controllers.

4. The method of claim 1, wherein receiving information from the plurality of building automation controllers includes accessing a database having demand load information for at least some of the plurality of buildings.

5. A networking control system comprising: a communications link to a utility control center to obtain information characterizing an amount of power presently being supplied by one or more electrical power generation sources to a plurality of networked buildings; and a communications link to a plurality of building automation controllers, the controllers operable to adjust an operating energy efficiency of at least one building of the plurality of networked buildings, wherein the networking control system is operable to compare the amount of power presently being supplied with a total power load amount presently demanded by the networked buildings, and based on a determination that the amount of power presently being supplied exceeds the total power load presently demanded, the networking control system determines a finite period of time, and instructs one or more of the building automation controllers to demand one or more power generation sources to reduce the operating energy efficiency of at least one building of the networked buildings for the finite period of time.

6. The networking control system of claim 5, further comprising a database having one or more environmental parameters about the plurality of networked buildings.

7. The networking control system of claim 6, wherein the database includes continuously updated information regarding the one or more environmental parameters.

8. The networking control system of claim 5, wherein the operating energy efficiency follows an energy optimization curve determined by the networking control system.

9. A non-transient computer-readable medium on which are stored instructions that, when executed by a processing device, enable the processing device to perform a method for controlling power consumption of a plurality of networked buildings, the method comprising: receiving information from a utility control center regarding a total amount of power presently being supplied by one or more power generation sources to the networked buildings; receiving information from a plurality of building automation controllers characterizing the total power load presently demanded by the networked buildings; determining whether the total amount of power presently being supplied exceeds the total power load presently demanded; and in response to determining that the total amount of power presently being supplied exceeds the total power load presently demanded, transmitting instructions to at least one of the building automation controllers to demand one or more power generation sources to reduce the operating energy efficiency of at least one of the networked buildings for a period of time.

10. The medium of claim 9, wherein the method further comprises determining a reduced rate pricing structure for networked buildings permitting energy efficiency reduction during selected time periods.

11. The medium of claim 9, wherein transmitting instructions includes providing a predetermined optimization curve to be utilized by one or more of the building automation controllers.

12. The medium of claim 9, wherein communicating with the plurality of building automation controllers includes accessing a database having demand load information for at least some of the plurality of buildings.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] Preferred and alternative embodiments of the present invention are described in detail below with reference to the following drawings:

[0017] FIG. 1 is a schematic system diagram of an electric power grid having at least one power generation source supplying power to a plurality of buildings that are in communication with a networking control system and a utility control center according to an embodiment of the present invention;

[0018] FIG. 2 is a front plan view of a display screen showing a listing of buildings that are and are not being controlled by the networking control system of FIG. 1 according to an embodiment of the present invention; and

[0019] FIG. 3 is an optimization curve showing a method of balancing an electrical power grid with networked buildings according to an embodiment of the present invention.

[0020] FIG. 4 is a flow diagram of a method for balancing an electrical grid with networked buildings.

DETAILED DESCRIPTION OF THE INVENTION

[0021] In the following description, certain specific details are set forth in order to provide a thorough understanding of various embodiments of the invention. However, one skilled in the art will understand that the invention may be practiced without these details. In other instances, well-known structures associated with electrical power grids, which may include smart grid systems, HVAC systems, utility control centers, transmission or power lines, building automation controllers, communication networks, various computing and/or processing systems, various HVAC system operational parameters, and methods of operating any of the above with respect to one or more buildings have not necessarily been shown or described in detail to avoid unnecessarily obscuring descriptions of the embodiments of the invention.

[0022] In one embodiment of the present invention, an electrical power grid having multiple, networked buildings and one or more power sources may be balanced to minimize inefficiencies and costs on the supply (i.e., source) side of the grid. In general, the balancing of the networked buildings includes controlling an energy optimization level for each building using a networked control system that communicates directly with both a utility control center and the networked buildings. Alternatively stated, the balancing of the grid provides the ability to appropriately and temporally, preferably in real-time, balance the power load demands of the networked buildings vis-à-vis the supply capacities of the power generation sources.

[0023] By way of example and looking at the grid over the course of a single day, the demand load for each of the networked buildings will naturally increase or decrease depending on a variety of variables such as, but not limited to, the amount of people in the building and the outside weather conditions. Likewise on the supply side, the power output capacity for the power sources may also vary. For example, wind and solar power sources are dependent on the amount of wind and sun energy available, which naturally changes throughout the day.

[0024] In conventional electrical grids, it is common to shut down or deactivate one or more of the power sources when the overall demand loads decrease. Regardless of the power source, there is a cost associated with bringing that power source back online to a full operational capacity. A coal plant for instance will release extra amounts of Carbon Dioxide (CO.sub.2) into the atmosphere when being brought back online. A wind turbine will utilize additional energy to overcome the inherent friction in the turbine as the blades begin to rotate, and this is energy that could have been supplied.

[0025] Thus, one objective of the present invention is to reduce the load on the grid to prevent a “brown out,” which was previously defined as a reduction or cutback in electric power, especially as a result of a shortage, a mechanical failure, or overuse by consumers. Another objective of the present invention is to prevent or eliminate the need to take a power generation source offline, but instead keep it on-line and running at a reduced level (e.g., idling) while any operating efficiencies of the overall grid are dealt with on the demand side (e.g., by adjusting the energy optimization levels for one or more of the networked buildings).

[0026] FIG. 1 shows an electrical power grid 100 having a plurality of electrical power generation sources 102, a utility control center 104, a plurality of buildings 106, and a networking control system 108. For purposes of the present description, the buildings 106 are networked (i.e., interconnected) in that environmental control data or other information about the buildings may be obtained from, extracted from, or exchanged with other buildings and the networking control system 108 by way of building automation controllers (BACs) 109. The networking control system 108 may transmit, receive and exchange computer readable instructions or other encoded signals with the BACs 109. The flow of information to/from the BACs 109 and networking control system 108 may be accomplished using a wired or wireless building communication platform 110. In one embodiment, the network control system 108 and the BACs 109 are connected to a local area network or a wide area network, such as the Internet.

[0027] The power generation sources 102 may take a variety of forms such as, but not limited to, a wind powered generation source 102a, a solar powered generation source 102b, a coal powered generation source 102c, or a nuclear powered generation source 102d. Likewise, the networked buildings 106 may take a variety of forms such as, but not limited to, an office building 106a, a medical building 106b, or a residential building 106c. For the present description, a building may generally include any structure that utilizes a heating, ventilation and air conditioning (HVAC) system and demands a non-zero electrical load. Likewise, the term “load” generally means an electrical power requirement required by the building's HVAC or lighting system to keep the building in a desired state. As mentioned above, the load required by a particular building often fluctuates throughout the day due to temperature changes, weather changes, time of day (e.g., primary work hours), etc.

[0028] On the supply side of the grid, the power generation sources 102 supply electrical power through one or more supply transmission lines 112. The utility control center 104 communicates with the power generation sources 102 by way of a wireless or non-wireless power generation communication platform 113 (shown in dashed lines to distinguish from the transmission lines 112).

[0029] On the demand side, the buildings 104 receive the electrical power from demand transmission lines 114, which may interface with or be the same as the supply transmission lines 112. Similarly, the utility control center 104 communicates with the networking control system 108 by way of a wireless or non-wireless communication platform 116. In turn, the networking control system 108 communicates with each of the BACs 109, as described in more detail below.

[0030] The BACs 109 receive information from the respective building's HVAC system, lighting system or some other environmental control system (for purposes of brevity hereinafter all the various systems will simply be referred to as the HVAC system). In one embodiment, the BACs 109 include various executable programs for determining a real time operating efficiency, simulating a predicted or theoretical operating efficiency, comparing the same, and then adjusting one or more operating parameters on equipment utilized by a building's HVAC system. In one embodiment the executable programs control variable speed loop cooling plants to establish a decrease or increase of energy usage for the building's HVAC system.

[0031] In addition, at least one or more of the executable algorithms employed by the BACs 109 may comport with an equal marginal performance principle such as provided in an article entitled “Designing Efficient Systems with the Equal Marginal Performance Principle,” ASHRAE Journal, Vol. 47, No. 7, July 2005, which is incorporated herein by reference in its entirety. Additionally or alternatively, at least one or more of the executable algorithms employed by the BACs 109 may comport with a sequencing control strategy for chillers in an all variable speed chiller plant or some other control strategy that includes adjusting one or more numerical constants associated with the operation of an HVAC system. By way of example, the numerical values may be related to a variety of HVAC system components such as, but not limited to, centrifugal pumps, fans, and variable speed drive centrifugal chillers. In one embodiment, the numerical values are derived and/or adjusted based on the likelihood that more HVAC equipment operates in parallel and on-line near its natural operating curve.

[0032] In some embodiments, the BACs 109 may communicate with an all-variable speed system to compensate for changes to equipment or operating conditions automatically, using self-correcting computer executable instructions. The BACs 109, in communication with and with information from the networking control system 108, may advantageously provide an automated technique to replace the current manual tuning methods used to tune the HVAC system for one or more of the networked buildings 106. In other embodiments, the networking control system 108 automatically corrects the operation of the BACs to compensate for changes in HVAC equipment characteristics or external building load characteristics that may be attributed to the building and local climate. In one embodiment, the BACs 109 may include or operate as a self-learning controller as described in U.S. Patent Publication No. 2010/0114385, which is also incorporated by reference in its entirety.

[0033] Still referring to FIG. 1, the networking control system 108 communicates with a database 118 that includes information about whether a particular building 106 is in a network that includes the networked buildings 106. By way of example and referring briefly to FIG. 2, the database 118 includes a list of buildings 106 and a corresponding list of real-time demand loads 120 for each building. In one embodiment, the database 118 includes continuously updated information regarding one or more environmental parameters about the plurality of buildings. Such parameters may include, but are not limited to, total building power (e.g., KW), total building load (e.g., tons/BTUh), building efficiencies, power usage, and building temperature. If the particular building is not in the network then it may be identified as “not commissioned.” However, other terms or phrases may be used to indicate a non-networked building. In some cases if the building is “not commissioned” then the networking control system 108 will be unable to obtain the demand loads 120, however other buildings may be “not commissioned” and still be able to provide their demand loads 120 through one or more communication platforms.

[0034] In one embodiment, the networking control system 108 may include a pricing module configured to determine electric rates of the networked buildings based on a calculated operating efficiency determined during peak and off-peak periods. Based on this, reduced power rates may be offered to networked buildings that permit energy optimization control during certain times.

[0035] FIG. 3 shows an energy optimization chart 300 for one of the networked buildings. During the course of a day, for example, the BAC will attempt to keep its respective building at 100% optimized or close thereto, which means a real-time energy efficiency is equal to or substantially equal to a theoretical energy efficiency for the building. Thus, if a building is less than 100% optimized then the building is using more energy than it needs to meet its demand load. Thus on the chart 300, the vertical axis 302 indicates the percentage of optimization for a networked building while the horizontal axis 304 indicates time.

[0036] In one embodiment of the invention, the BAC can vary the optimization percentage using one or more of the executable algorithms or control strategies, which have been previously described above. Further, the BAC may be controlled or commanded by the networking control system 108 to follow a particular percentage optimization curve other than 100% optimized, such as an optimization curve 306 as shown in the illustrated embodiment.

[0037] By way of example, if there is too much power being supplied by the power sources and the utility control center determines it does not want to bring one or more of the power sources offline, then the networking control system 108 may balance the incoming power over the networked buildings by instructing one or more of the buildings to operate below a 100% optimized level. The building represented by optimization curve 306 is shown operating at a 50% optimization level according to curve 406 to keep one or more of the power sources from having to go completely offline. As needed, the optimization level of the building may be decreased below 50% for a period of time, which may be energy inefficient when it comes to that particular building, but in the aggregate be more energy efficient with respect to the entire grid, especially as compared to bring one or more power sources completely offline. The optimization curve 306 further shows that as the demand loads increase for other networked buildings and/or the power output from one or more of the power sources decreases then the percentage optimization of the represented building may be increased up to the 100% optimization level according to curve 410. This controlled shifting of the optimization curve for each networked building results in a balanced grid capable of smoothly adjusting to the ebbs, flows, peaks and valleys of the supply and demand within the grid.

[0038] Now referring to FIG. 4 and also referring back to FIG. 1, FIG. 4 shows a flow diagram of a method 400 for balancing an electrical grid with networked buildings. At 402, the utility control center 104 receives operating data regarding a total amount of power presently being supplied by one or more of the power generation sources 102. This information is provided to the networking control system 108, which in turn determines whether the total amount of power presently being supplied exceeds a total amount of demand load for the networked buildings 106. If not, then the utility control center 104 continues to monitor the power supplied by the power sources and may also communicate with one or more of the power sources to increase its supplied power output.

[0039] However at Step 404, if the total amount of power presently being supplied does exceed the total amount of demand load for the networked buildings 106, then at 406 the networking control system 108 instructs at least one of the BACs 109 to decrease an energy optimization level of its respective building, which is illustrated as the 50% optimization level curve 406 in FIG. 3. The decreased optimization level may follow an optimization curve similar to the one illustrated in FIG. 3. Accordingly, the respective building will operate at a reduced energy efficiency level for an amount of time determined by the networking control system 108, which continually communicates with the utility control center 104. If the building demand loads greatly exceed the total power supplied then multiple BACs may be commanded to control their respective buildings at a sub-optimized level for the same or differing periods of time. At Step 408, if the total amount of power presently being supplied does NOT exceed the total amount of demand load for the networked buildings 106, then at Step 410 the networking control system 108 instructs at least one of the BACs 109 to increase an energy optimization level of its respective building, which is illustrated as the 100% optimization level curve 410 in FIG. 3.

[0040] At least one embodiment of the present invention may advantageously prevent brown outs from occurring during high demand cycles, low power supply cycles or some combination of each. In addition, it may advantageously allow excess power to be utilized, albeit more inefficiently, by the networked buildings instead of bringing an entire power source offline. This power management strategy may, in the aggregate and over time, actually save energy and minimize or eliminate unwanted pollutants that may enter the atmosphere during the start-up cycle of certain types of power sources. Other advantages will also be apparent to those of skill in the art.

[0041] While the preferred embodiment of the invention has been illustrated and described, as noted above, many changes can be made without departing from the spirit and scope of the invention. Accordingly, the scope of the invention is not limited by the disclosure of the preferred embodiment. Instead, the invention should be determined entirely by reference to the claims that follow.