This invention relates to the control of an HVAC system using information gathered from locations to be provided with conditioned air from the HVAC system.
The control of an HVAC system has heretofore depended on gathering information such as sensed temperature from the locations in which conditioned air is to be provided by the system. The temperatures are usually sensed by temperature sensors in these locations. The sensed temperatures are usually compared with arbitrarily defined set point temperatures for the locations. The difference in these temperatures is used to define the demand for heating or cooling at each location. These location specific demands are used to control one or more HVAC systems providing conditioned air to the locations.
The above control may not completely reflect the appropriate levels of demand for heating or cooling at one or more of the locations. In this regard, some locations may have certain unique demands for heating or cooling that are not necessarily reflected in simply a temperature difference. For instance, a location might have a certain exposure to solar heating or cooling, or it might be an interior versus an exterior office area, or it may simply have certain occupants that are to be accorded a higher priority than the occupants in other locations.
It would be helpful to include information that may be used to differentiate demands for heating or cooling by other than expressed levels of comfort provided by the location.
A computer receives information as to comfort level from various locations that are to receive conditioned air. The level of comfort for each location is preferably first computed based upon the received information. These levels of comfort are thereafter preferably adjusted by weighting factors for each location. The adjusted levels of comfort for each location are sent to at least one HVAC control for further analysis prior to controlling an HVAC system that is to provide conditioned air to the locations. The resulting control of the HVAC system is influenced by the over weighting or under weighting factors used in generating the comfort levels for the locations. This gives some locations a stronger or weaker vote on the control of the HVAC system that is providing conditioned air to all of the locations.
In a preferred embodiment, the information received by the computer includes individual selections of comfort entered into data entry devices at the various locations. Each data entry device is operative to store selected comfort levels and timely provide the stored results to the network computer.
The preferred embodiment deals with processing levels of comfort for temperature in a number of locations. The invention is, however, equally applicable to other measurements of comfort that may be analyzed and thereafter acted upon, including for instance, humidity or air flow.
Further advantages of the present invention will be apparent from the following detailed description in conjunction with the accompanying drawings, wherein:
Referring to
Each office area location is seen to include a number of individual personal computers such as computer 16 located in an office 18. Each office within office area location 12 is identified by an office index “K” where K=for instance 1 for office 18 and is for instance another value for office 20.
Each computer within an office in a particular office area location is preferably connected to a network computer 22. As will be explained in detail hereinafter, the network computer 22 is operative to collect comfort level information entered in each of the computers within the individual offices of each office area location. The collected information is analyzed by particular office area index value. The network computer is thereafter operative to generate overall indications as to level of comfort in each office area. These overall indications as to comfort level are preferably indexed in accordance with the office area index and provided to an HVAC system control 24. The HVAC system control 24 is operative to control the HVAC system 10 so as to provide appropriate amounts of conditioned air to each of the office areas in accordance with the information received from the network computer 22.
Referring now to
Referring now to
Referring now to
Referring again to step 48, in the event that “T_CLUSTER_AVG” is not greater than “T_AVG_HI_LIMIT”, then the processor will proceed along a no path to a step 52. Referring to step 52, the processor will inquire as to whether “T_CLUSTER_AVG” is less than the value of “T_AVG_LOW_LIMIT”. It is to be appreciated that the value of “T_AVG_LOW_LIMIT” will be set for all office areas in the office building or for the particular office area then under review. This value will again be set so as to require that the net sum of “T INPUTS” is predominantly negative so as to indicate a predominance of “TOO COLD” having been selected from the menu 30 on each screen of an office computer within the office area indicated by the index “N”. For instance, this variable may be set equal to −3, −4, or even −5 for an office area including ten separate office computers. In the event that “T_CLUSTER_AVG” is less than the value of “T_AVG_LO_LIMIT”, then the processor will proceed from step 52 to a step 54 and set “CLUSTER_N_AVG” equal to −1. This will be an overall indication that the office area having an office area index equal to the current value of N is too cold.
The processor proceeds from either step 50 or step 54 to a step 55 and adjusts the previously computed “CLUSTER_N_AVG” by a weighting factor “CLUSTER_N_WT” for the particular office area “N”. This weighting factor is preferably accessed from a table of weighting factors for each office area previously stored in memory within or associated with the network computer 22. The weighting factor is preferably previously computed using any number of relevant parameters that would differentiate the heating or cooling needs of the particular office area from the other office areas to be provided with conditioned air. These relevant parameters might for instance include the size of the particular office area versus the sizes of other office areas that are to be provided with conditioned air. The relevant parameters might also include the exposure of the particular office area to solar heating or cooling depending on the time of day. The relevant parameters might also include the particular construction of the office area versus the other office areas that might account for a need for less heating or cooling versus other office areas. The relevant parameters might also include simply noting whether the office area is an interior space without windows or an office space with a number of windows. The relevant parameters might also include relative priorities based on who is occupying particular locations. For example, the president's office or the corporate board room may have a higher priority to that of a mail room. Finally, it is to be noted that the weighting factor “CLUSTER_N_WT” could be computed in real time taking into account any number of the aforementioned parameters for the particular location that might vary from day to day or even hour to hour. It is finally to be noted that the weighting factor is preferably normalized relative to all other weighting factors so that it is either a fractional amount less than one or a fractional amount greater than one. The thus preferably normalized weighting factor, “CLUSTER_N_WT” is multiplied times the previously computed “CLUSTER_N_AVG” in step 57 so as to produce an adjusted CLUSTER_N_AVG. This “CLUSTER_N_AVG” will itself either be minus one or a fractional amount less than or a fractional amount greater than minus one for an adjusted CLUSTER_N_AVG originally computed in step 54. On the other hand, the “CLUSTER_N_AVG” will either be one or a fractional amount less than or a fractional amount greater than one for an adjusted CLUSTER_N_AVG originally computed in step 50.
Referring again to step 52, in the event that “T_CLUSTER AVG” is not less than “T_AVG_LO_LIMIT”, then the processor will proceed to step 56 and set “CLUSTER_N_AVG” equal to 0, wherein the value of “N” will be the particular value of the office area index. This will be an overall indication that the temperature level is “JUST RIGHT” for the particular office area.
The processor proceeds from either steps 55 or 56 to step 58 and inquires as to whether the office area index “N” is equal to “MAX_CLUSTER_INDEX”. The value of “MAX_CLUSTER_INDEX” will be equal to the highest value of the office area index identifying the last office area to be analyzed. In the event that the value of the office area index “N” is not equal to “MAX_CLUSTER_INDEX”, then the processor will proceed to a step 60 and increment the office area index “N” by one before returning to step 44. It is to be understood that the processor within the network computer will again execute steps 44-58 so as to determine the overall indication of comfort for the office area indicated by the new value of office area index “N” This will be stored in the new “CLUSTER_N_AVG”. The value of the office area index “N” in the variable “CLUSTER_N_AVG” will identify the particular office area to which the overall comfort level indication applies.
Referring again to step 58, it will be understood that at some point, all office areas will have been analyzed and all overall comfort level indications will have been defined in respective values of “CLUSTER_N_AVG”. When this occurs, the processor will proceed to a step 62 and send all CLUSTER_N_AVGs for N=0 to N=MAX_CLUSTER to the HVAC system control 24. The processor will proceed to step 64 and inquire as to whether the value of “TIMER_CLOCK” equals “MAX_TIME”. The value of “MAX_TIME” will be arbitrarily set for the particular office building or office area under examination. In either case, the “TIMER CLOCK” must exceed the “MAX TIME” in order for the processor to proceed back to step 42 and again begin to collect the comfort level selections that have been made and stored as “T_INPUT K” for each office computer in the first office area having an office area index value of 1. The menu sections from all such office computers will again be analyzed and an overall comfort level indication for each particular office area will be defined in CLUSTER_N_AVG before proceeding to the next office area. When all such office areas have been analyzed, the overall comfort level indications for each office area will be forwarded to the HVAC control 24 again in step 62.
Referring now to
Referring to step 74, the resulting value of “HVAC_DEMAND” is compared with a fractional value greater than zero. This fractional value is particularly set at one tenth, but could be set higher or lower depending on what threshold setting is desired for the particular HVAC system control. In the event that “HVAC_DEMAND” is greater than the stipulated fractional value, the processor proceeds to a step 76 and orders the HVAC system to decrease the temperature of a conditioned medium used to provide conditioned air to the locations by a prescribed ΔT amount. In this regard, if the HVAC system was a hydronic system providing conditioned water to each location, than the temperature of the water being provided would be reduced by the ΔT amount. Such systems typically include fan coil heat exchangers that circulate air over coils containing the circulated water. On the other hand, if the HVAC system were directly providing conditioned air then the amount of compressed refrigerant flowing through one or more evaporator coils would be increased to thereby lower the temperature of the conditioned air to be provided to each location by the ΔT amount. It is also to be appreciated that other cooling schemes could be implemented that might proportionally decrease the temperature of the medium conditioned by the HVAC system in response to the particular amount by which the “HVAC _DEMAND” exceeds the stipulated fractional amount in step 76.
Referring to step 78, the resulting value of “HVAC_DEMAND” from step 72 is compared with a fractional value less than zero which is particularly set at minus one tenth. In the event that “HVAC_DEMAND” is less than the stipulated fractional value, the processor proceeds to a step 80 and orders the HVAC system to increase the temperature of a conditioned medium used to provide conditioned air to the locations by a prescribed ΔT amount. In this regard, if the HVAC system being controlled is a hydronic system providing conditioned water to each location, than the temperature of the water being provided would be increased by the ΔT amount. Such systems typically include fan coil heat exchangers that circulate air over coils containing the circulated water. On the other hand, if the HVAC system were a heat pump directly providing conditioned air than the amount of compressed refrigerant flowing through one or more condenser coils would be increased to thereby raise the temperature of the conditioned air to be provided to each location by the ΔT amount. If on the other hand, the HVAC system being controlled were a boiler, than the burner in the boiler would be activated for a period of time long enough to increase the temperature of the water being heated by the ΔT amount. It is also to be appreciated that other heating schemes could be implemented that might proportionally increase the temperature of the medium conditioned by the HVAC system in response to the particular amount by which the “HVAC_DEMAND” exceeds the stipulated fractional amount in step 78.
Referring now to step 82, the processor within the HVAC control will either have arrived at this step from step 76 or steps 78, or 80. The processor will implement a TIME_DELAY of δt before again returning to step 70 to inquire as to whether a new set of CLUSTER_AVGs” have been received from the network computer. In this regard, the network computer will preferably be programmed so as to compute a new set of “CLUSTER_AVGs” by the time that the time delay of δt has expired so as to prompt the processor within the HVAC system control 24 to again implement the process of FIG. 5. The processor will again compute a new HVAC DEMAND and thereafter adjust the temperature of the conditioned medium as previously discussed.
Referring now to
It is to be appreciated from the above that a number of programs resident in processors within an office computer, a network computer, and an HVAC system control have been disclosed. Alterations, modifications and improvements to these various individual programs may readily occur to those skilled in the art. For instance, the particular comfort control menu may vary as to how it is displayed as well as how many particular comfort level selections may be made. Furthermore, the processor program executed by the network computer could compute the overall comfort level indications for each particular office area in a different manner. This could include summing all comfort level values provided by the office computers and dividing by the number of computers in the particular office area. This could thereafter be compared with an appropriate high and low limit for such a computed average before adjusting the particular overall comfort level indication for that particular office area. The adjustment factors used by the network computer program could furthermore be computed differently either in real time or prior to being used in the network computer. It is to be furthermore understood that the particular program implemented by an HVAC system control downstream of the network computer could vary considerably depending on the HVAC system that is to be controlled and the particular HVAC DEMAND that would be computed. Accordingly, the foregoing description of the particular programs in the preferred embodiment is by way of example only and the invention is to be limited by the following claims and equivalents thereto.
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Number | Date | Country | |
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20030216838 A1 | Nov 2003 | US |