The present invention relates to Heating, Ventilating, and Air Conditioning (HVAC) systems and in particular to outdoor air introduced into buildings during HVAC operation through economizer outdoor air dampers or non-economizer outdoor air dampers.
Buildings are required to provide a minimum flow of outdoor air into their HVAC systems per the American Society of Heating Refrigeration and Air-Conditioning Engineers (ASHRAE) Standard 61.1 (ANSI/ASHRAE 62.1-2010. Standard Ventilation for Acceptable Indoor Air Quality) and the California Energy Commission (CEC) Building Energy Efficiency Standards for Residential and Nonresidential Buildings (CEC-400-2012-004-CMF-REV2). When the outdoor airflow exceeds the minimum required airflow, the additional airflow may introduce unnecessary hot outdoor air when the HVAC system is cooling the building, or introduce unnecessary cold outdoor air when the HVAC system is heating the building. This unnecessary or unintended outdoor airflow reduces space cooling and heating capacity and efficiency and increases cooling and heating energy consumption and the energy costs required to provide space cooling and heating to building occupants. Known methods for measuring the amount of outdoor airflow to meet minimum requirements introduced into buildings are inaccurate and better methods are required to improve thermal comfort of occupants, reduce cooling and heating energy usage, and improve cooling and heating energy efficiency.
U.S. Pat. No. 6,415,617 (Seem 2002) discloses a method for controlling an air-side economizer of an HVAC system using a model of the airflow through the system to estimate building cooling loads when minimum and maximum amounts of outdoor air are introduced into the building and uses the model and a one-dimensional optimization routine to determine the fraction of outdoor air that minimizes the load on the HVAC system. The '617 patent does not provide apparatus or methods to measure the Outdoor Air Fraction (OAF) defined as the ratio of outdoor airflow through the economizer or non-economizer dampers to total system airflow. Nor does the '617 patent provide methods to adjust the economizer outdoor air damper minimum damper position until OAF is within the allowable minimum regulatory requirement.
US Patent application publication No. 2015/0,309,120 (Bujak 2015) discloses a method to evaluate economizer damper fault detection for an HVAC system including moving dampers from a baseline position to a first damper position and measuring the fan motor output at both positions to determine successful movement of the baseline to first damper position. The '120 publication does not teach how to measure the OAF or electronically control the actuator to adjust the economizer outdoor air damper minimum damper position until OAF is within the allowable minimum regulatory requirement.
U.S. Pat. No. 7,444,251 (Nikovski 2008) discloses a system and method to detect and diagnose faults in HVAC equipment using internal state variables under external driving conditions using a locally weighted regression model and differences between measured and predicted state variables to determine a condition of the HVAC equipment. The '251 patent does not provide apparatus or methods to measure the OAF. The '251 patent does not provide apparatus or methods to measure the OAF. Nor does the '251 patent provide methods to adjust the economizer outdoor air damper minimum damper position until OAF is within the allowable minimum regulatory requirement or measure the temperature difference across the evaporator or heat exchanger to determine whether or not the sensible cooling or heating capacities are within tolerances.
U.S. Pat. No. 6,223,544 (Seem 2001) discloses an integrated control and fault detection system using a finite-state machine controller for an air handling system. The '544 method employs data regarding system performance in the current state and upon a transition occurring, determines whether a fault exists by comparing actual performance to a mathematical model of the system under non-steady-state operation. The '544 patent declares a fault condition in response to detecting an abrupt change in the residual which is a function of at least two temperature measurements including: outdoor-air, supply-air, return-air, and mixed-air temperatures. The '544 patent measures the mixed-air temperature with a single-sensor and without a minimum temperature difference between outdoor and return air temperatures. The '544 patent does not provide apparatus or accurate methods to measure the OAF. Nor does the '544 patent provide methods to adjust the economizer outdoor air damper minimum damper position until the OAF is within the allowable minimum regulatory requirement or measure the temperature difference across the evaporator or heat exchanger to determine whether or not the sensible cooling or heating capacities are within tolerances.
Thus, known methods and apparatus currently do not exist to accurately measure the outdoor airflow through economizer or non-economizer outdoor air dampers. The present invention provides an apparatus and method to accurately measure and establish the OAF to optimize economizer damper position either manually or automatically using an economizer fault detection diagnostic (FDD) controller and actuator to meet ASHRAE 62.1 minimum outdoor airflow requirements. Optimizing the OAF will improve space cooling and heating efficiency, save energy, and reduce carbon dioxide emissions.
The present invention addresses the above and other needs by providing a method for determining the Outdoor Air Fraction (OAF), (the ratio of outdoor airflow through the economizer or non-economizer outdoor air dampers and/or cabinet, to the total airflow introduced into the air conditioner evaporator or heat exchanger) and the mixed-air humidity ratio and mixed-air wetbulb temperature, for packaged and split-system HVAC equipment equipped with economizer or non-economizer outdoor air dampers. An outdoor airflow exceeding the American Society of Heating Refrigeration and Air-Conditioning Engineers (ASHRAE) Standard 62.1 minimum outdoor air requirements wastes space cooling and heating energy and increases carbon dioxide emissions contributing to global warming. The OAF measurements are used to optimize the minimum economizer or non-economizer outdoor air damper position to meet but not exceed ASHRAE 62.1 minimum outdoor airflow requirements. The present invention provides a method to measure OAF versus damper actuator voltage at the initial damper position, fully-open-damper maximum damper position, and closed-damper position. The present invention uses these measurements and matrix algebra to calculate coefficients for a quadratic regression equation of OAF versus control voltage in order to establish the optimal economizer damper position actuator control voltage to adjust the damper to achieve the optimally minimum OAF to just meet outdoor airflow regulatory requirements to reduce over ventilation and save energy. After the economizer damper position is optimized, the mixed-air wetbulb temperature is determined to measure evaporator entering air drybulb and wetbulb temperatures and supply air drybulb temperature to evaluate temperature split, sensible cooling or heating capacity, and refrigerant charge Fault Detection Diagnostics (FDD) in order to determine whether or not the evaporator airflow, sensible cooling or heating capacity, and refrigerant charge of the air conditioning system, needs to be adjusted or corrected.
In accordance with one aspect of the invention, there is provided a method for accurately measuring mixed air temperature by positioning an averaging temperature sensor in the passage between the mixed air chamber of the HVAC system and the air conditioner evaporator and furnace/heat exchanger of the HVAC system. The averaging temperature sensor is preferably formed into a quasi-rectangular or quasi-circular spiral in the shape of the passage in order to measure the average temperature of air flowing through the mixed-air chamber from the return duct and the outdoor air dampers. The mixed-air drybulb temperature measurement is considered accurate when the difference between return drybulb temperature and outdoor air drybulb temperature is preferably at least 10 degrees Fahrenheit and more preferably at least 20 degrees Fahrenheit. OAF measurements made at lower temperature differences will have slightly lower accuracy.
In accordance with another aspect of the invention, there is provided a method for recursively computing mixed air humidity ratio W*s. An initial value of mixed air wetbulb temperature t*m is made based on a drybulb temperature measurement. A saturation pressure at wetbulb temperature pws is computed using the estimate of t*m. An updated value of W*s is computed from pws. The process is repeated using updated value of W*s until it converges.
In accordance with yet another aspect of the invention, there is provided a method for measuring the sensible temperature split across the evaporator in cooling mode or the sensible temperature rise across the heat exchanger in heating mode. The sensible temperature split for cooling, or for temperature rise for heating, can be used to evaluate over ventilation, airflow, sensible cooling capacity, sensible heating capacity, and/or refrigerant charge FDD information.
In accordance with still another aspect of the invention, there is provided a method to use sensors to transmit temperature or humidity measurement data using wires or wirelessly to a device or controller in order to display, store, or use the data to measure the OAF or to provide measurement data to an economizer controller or outdoor air damper controller where the controller uses the data to calculate the measured OAF and compares the measured OAF to a minimum outdoor airflow specification for a building conditioned space and occupancy, and communicates a low-voltage signal to an actuator to energize the actuator to adjust the damper position to establish an optimally minimum damper position to provide an OAF within tolerances of the minimum outdoor airflow based on regulatory requirements for a building conditioned space and occupancy.
The above and other aspects, features and advantages of the present invention will be more apparent from the following more particular description thereof, presented in conjunction with the following drawings wherein:
Corresponding reference characters indicate corresponding components throughout the several views of the drawings.
The following description is of the best mode presently contemplated for carrying out the invention. This description is not to be taken in a limiting sense, but is made merely for the purpose of describing one or more preferred embodiments of the invention. The scope of the invention should be determined with reference to the claims.
Where the terms “about” or “generally” are associated with an element of the invention, it is intended to describe a feature's appearance to the human eye or human perception, and not a precise measurement. Drybulb temperature measurements at indicated without asterisks and corresponding wetbulb temperatures are indicated by the addition of an asterisk.
An air handler 10 of a packaged Heating, Ventilation, Air Conditioning (HVAC) system with manually adjusted outdoor air dampers 50 is shown in
The outdoor air dampers 50 and return air dampers 52 are coupled by a gear assembly so when outdoor air dampers 50 are opened, the return air dampers 52 close, and vice versa. Closing the outdoor air dampers 50 reduces the volumetric airflow rate of the outdoor air 16 into the mixed air chamber 12 and opens the dampers 52 to increase the volumetric airflow rate of return air 18 into the mixed air chamber 12. Preferably, the positions of the dampers 50 and the dampers 52 are coupled by the gear assemblies 50a and 52a so that opening the dampers 50 closes the dampers 52, and opening the dampers 52 closes the dampers 50, to maintain a generally consistent volumetric airflow rate into the mixed air chamber 12.
The temperature sensor 28 measures the return air drybulb temperature, tr, and temperature sensor 30 measures the outdoor air drybulb temperature to. The temperature sensor 32 is used to measure the supply air drybulb temperature ts, used with the return air drybulb or mixed air drybulb to calculate the temperature split decrease across the evaporator in cooling mode or the temperature split increase across the heat exchanger in heating mode. The mixed-air drybulb temperature, tm, measurement is considered minimally accurate when the difference between return drybulb temperature, tr, and outdoor air drybulb temperature, to, is preferably at least ten degrees Fahrenheit and is considered more accurate when the difference between return drybulb temperature, tr, and outdoor air drybulb temperature, to, is at least 20 degrees Fahrenheit. The measurement device 40 (see
The return air drybulb temperature tr, and the return air wetbulb temperature t*r, are preferably measured in well-mixed return air. The outdoor air drybulb temperature to and outdoor air wetbulb temperature t*o are preferably measured in well-mixed outdoor air entering an economizer 49 controlling the outdoor air flow 16b into the mixed air chamber 12 through outdoor air dampers 50.
The averaging temperature sensor 24 shown in
An air handler 10a of a packaged HVAC system with an economizer controller 56 and actuator 54 used to adjust outdoor air dampers is shown in
The sensor 28 measures the return air drybulb temperature, tr, and the optional temperature sensor 28* measures the return air wetbulb temperature, t*r, respectfully. The temperature sensor 30 measures the outdoor air drybulb temperature, to, and the optional temperature sensor 30* measures the outdoor air wetbulb temperature, t*o, respectively. The temperature sensor 32 is used to measure the supply air drybulb temperature, ts, used with the return air drybulb or mixed air drybulb to calculate the temperature split decrease across the evaporator in cooling mode or the temperature split increase across the heat exchanger in heating mode. The mixed-air drybulb temperature, tm, measurement is considered minimally accurate when the difference between return drybulb temperature, tr, and outdoor air drybulb temperature, to, is preferably at least ten degrees Fahrenheit and considered more accurate when the difference between return drybulb temperature, tr, and outdoor air drybulb temperature, to, is at least 20 degrees Fahrenheit.
An air handler of a HVAC system 10b and including a measurement instrument or control device 40b mounted to an HVAC system 10b is shown in
The measurement device 40b may also provide low-voltage outputs to control the actuator A for controlling the position of outdoor air dampers 50 and return dampers 52. The measurement device 40b may also be wired or wireless and provide economizer damper position and Outdoor Air Flow (OAF) measurements and operational Fault Detection Diagnostic (FDD) signals through a built-in display or external display through wireless communication signals to a building energy management system, standard thermostat, WIFI-enabled thermostat, internet-connected computer, internet telephony system, or smart phone indicating maintenance requirements to check and correct outdoor air damper position, evaporator airflow and/or refrigerant charge of the air conditioning system.
After 5 minutes of fan operational time, the method includes checking if the absolute value of the return-air minus outdoor-air temperature difference, δTro, is greater than a minimum temperature difference, preferably 10 degrees Fahrenheit, at step 104 according to the following equation.
δTro=|tr−to|≧10 Eq. 1
If the absolute value of the return-air minus outdoor-air temperature difference is not greater than 10 degrees Fahrenheit, then the method loops back to step 100.
If the temperature difference is greater than 10 degrees Fahrenheit, then the method includes computing the Outdoor Air Fraction (OAF) from tr, to and tm at step 106 using the following equation.
The method may be implemented manually on units without a damper actuator. The method may be further implemented on units with an analog economizer controller with temperature sensors and low-voltage output signals to measure, adjust and correct the OAF using a damper actuator. The method may be further implemented on units with a digital economizer controller with microprocessor with FDD capabilities, temperature sensors and low-voltage output signals to control a damper actuator, and low-voltage output actuator control signals to measure, adjust and correct the OAF using a damper actuator and evaluate low airflow, low cooling capacity or low heating capacity. The controller may be able to take temperature measurements at specific initial, maximum, and closed economizer damper actuator control voltages, and use this information to calculate regression equation coefficients for the OAF versus economizer damper actuator voltage and with use the target minimum OAF based on regulatory requirements with the regression equation to solve for the optimal actuator voltage to achieve the target minimum OAF using the quadratic formula, and adjust the economizer dampers as necessary to achieve the optimally minimum OAF and then measure the OAF to verify the optimally minimum OAF is within an accepted tolerance of the minimum OAFr based on regulatory requirements for the building and occupancy. A preferred accepted tolerance is within plus or minus ten percent of the minimum OAFr based on regulatory requirements for the building and occupancy.
At step 108, the method includes checking the measured outdoor air fraction (OAF) to determine whether or not it is within ten percent of the minimum required outdoor air fraction (OAFr) based on regulatory standards.
0.9×OAFr≦OAF≦1.1×OAFr Eq. 5
At step 110, the method includes fully opening the economizer dampers and looping back to step 100 and measuring tr, to and tm at the maximum damper position and computing and storing the maximum Outdoor Air Fraction (OAFmax) based on tr, to and tm at step 106 using Equation 2. For an HVAC system with an economizer damper actuator, opening the dampers involves adjusting the damper actuator control voltage to the maximum voltage, typically 10V, and looping back to step 100 and measuring tr, to and tm at the maximum damper position and computing and storing the maximum Outdoor Air Fraction (OAFmax) based on tr, to and tm at step 106 using Equation 2.
Repeating step 110, the method includes fully closing the economizer dampers and looping back to step 100 and measuring tr, to and tm at the closed damper position and computing and storing the closed Outdoor Air Fraction (OAFclosed) based on tr, to and tm at step 106 using Equation 2. For an HVAC system with an economizer damper actuator, closing the dampers involves adjusting the damper actuator control voltage to the minimum voltage, typically 2V, and looping back to step 100 and measuring tr, to and tm at the closed damper position and computing and storing the closed Outdoor Air Fraction (OAFclosed) based on tr, to and tm at step 106 using Equation 2.
At step 112, the present invention method includes developing the regression equations used to adjust the damper position to the optimize Outdoor Air Fraction (OAFo) to meet regulatory requirements per the following equations.
y
i
=ax
i
2
+bx
i
+c Eq. 7
Where, yi=outdoor air fraction (OAF) based on economizer damper position (dimensionless),
The method includes solving the above equation based on three OAF measurements at the initial, maximum, and closed damper positions by multiplying the inverse of the 3×3 matrix A times 1×3 matrix C to obtain the coefficients of the quadratic regression using the following equation.
C=X
−1
Y Eq. 11
Where, X−1=inverse of the 3×3 matrix X calculated according to the following equation,
Where, detX=determinant of matrix X which cannot equal zero.
After calculating the 1×3 matrix C coefficients a, b, and c, using the above equations, the method includes calculating the position or control voltage, xr, required for economizer dampers to achieve the required minimum OAFr, to meet regulatory requirements using the following quadratic formula.
Where, OAFr=the required minimum OAFr, to meet regulatory requirements, and
The HVAC manufacturer protocols or regulatory standards require accurate measurement of mixed-air drybulb, tm, and mixed-air wetbulb, t*m, entering the evaporator in order to lookup the required or target temperature difference across the evaporator (defined as the difference between mixed-air drybulb, tm, minus supply-air drybulb, ts, temperature) to diagnose and correct improper evaporator airflow or low cooling capacity. Low airflow can cause ice to form on the air filter and evaporator which blocks airflow and reduces cooling capacity and efficiency. Low cooling capacity can be caused by many faults including excess outdoor airflow, dirty or blocked air filters, blocked evaporator caused by dirt or ice buildup, blocked condenser coils caused by dirt or debris buildup, low refrigerant charge, high refrigerant charge, refrigerant restrictions, and non-condensable air or water vapor in the refrigerant system.
The HVAC manufacturer protocols or regulatory standards also require accurate measurement of mixed-air drybulb, tm, and mixed-air wetbulb, t*m, entering the evaporator in order to lookup the required or target superheat (defined as the difference between refrigerant suction temperature and evaporator saturation temperature) in order to diagnose and correct refrigerant charge or other faults which can cause improper superheat outside published tolerances established by the manufacturer or regulatory agency. Superheat must be within published tolerances in order to maintain proper cooling capacity and efficiency and prevent liquid refrigerant from entering and damaging the refrigerant system compressor. Not having a method to accurately measure mixed-air drybulb, tm, or wetbulb, t*m, will cause improper airflow and refrigerant system FDD as well as improper setup and operation of economizers and economizer FDD systems required by regulatory agencies.
Calculating the humidity ratios (Ibm/Ibm) of return-air Wr, outdoor-air, Wo and mixed-air Wm in step 114 are preferably performed using the following equations based on the Hyland Wexler formulas from the 2013 ASHRAE Handbook.
p1ws=EXP[C1/t*r+C2+C3t*r+C4t*r2+C5t*r3+C6 ln(t*r)] Eq. 21
Where, p1ws=saturation pressure at wetbulb temperature (psia) for the return air.
Where, W*r=humidity ratio corresponding to saturation at the return air wetbulb temperature, t*r (Ibm/Ibm),
Where, Wr=return air humidity ratio (Ibm/Ibm).
Computing humidity ratio of outdoor air Wo (Ibm/Ibm) at step 114 is preferably performed using the following equations:
p2ws=EXP[C1/t*o+C2+C3t*o+C4t*o2+C5t*o3+C6 ln(t*o)] Eq. 27
Where, p2ws=saturation pressure at wetbulb temperature (psia) for the outdoor air,
Where, W*o=humidity ratio corresponding to saturation at the outdoor air wetbulb temperature, t*o (Ibm/Ibm),
and
Where, Wo=outdoor air humidity ratio (Ibm/Ibm).
The method includes preferably calculating an initial value of the mixed-air humidity ratio Wm from the OAFm, Wr, and Wo at step 114 using the following equation.
W
m
=W
r
−[W
r
−W
o]OAFm Eq. 33
Where, Wm=humidity ratio at the mixed-air conditions (Ibm/Ibm).
Estimating an initial value of mixed-air wetbulb temperature (t*m) at step 116 is preferably setting an initial value of mixed-air wetbulb temperature (t*m) to the mixed-air drybulb temperature minus 10 degrees Fahrenheit in cooling mode (t*m=tm−10). Computing saturation pressure (pws) for the mixed-air wetbulb temperature (t*m) at step 118 is preferably performed using the initial or previous time-step estimate of the mixed-air wetbulb temperature, t*m, in the following equation.
p
ws=EXP[C1/t*m+C2+C3t*m+C4t*m2+C5t*m3+C6 ln(t*m)] Eq. 35
Where, pws=saturation pressure at wetbulb temperature (psia)
Where, W*m=humidity ratio at the mixed-air saturation pressure (pws) (Ibm/Ibm).
The method includes calculating a new estimate of mixed-air wetbulb temperature (t*m) at step 120, preferably performed using the following equation including the previous step mixed-air wetbulb temperature (t*m
Where t*m=new estimate of mixed-air wetbulb temperature (F), and
The new estimate of mixed-air wetbulb temperature is tested for convergence at step 122, to evaluate whether or not the absolute value of the change in Δt*m is less than or equal to 0.01 degrees Fahrenheit using the following equation.
|Δt*m|≦0.01 Eq. 41
If the absolute value of the change in Δt*m is less then or equal to 0.01 degrees Fahrenheit, then the method includes proceeding to step 124 to check whether or not the unit is operating in cooling mode. If step 124 determines that the absolute value of the change Δt*m is not less than or equal to 0.01 degrees Fahrenheit, then steps 118, 120, and 122 are preferably repeated calculating pws and W*s a new estimate of t*m until the absolute value of the recursive change in wetbulb temperature Δt*m is less than or equal to 0.1 degrees Fahrenheit.
At step 124 the method includes storing coefficients a, b, and c, and the economizer actuator control voltage, xr, to meet the minimum outdoor air fraction, OAFr, to meet regulatory requirements, maximum OAFmax, closed OAFclosed, mixed-air drybulb temperature tm, mixed-air wetbulb temperature, t*m, and return and outdoor air drybulb and wetbulb temperature measurements, tr, t*r, to, and t*o, and proceeding to step 126.
At step 126, the method includes checking whether or not to evaluate HVAC FDD, and if not, ending the OAF optimization method at step 128, or going to step 129 and proceeding to step 131 and starting the HVAC FDD evaluation method shown in
If the fan has not been operating continuously, then the method proceeds to Step 136 and checking whether or not the HVAC system is in cooling or heating mode. If in cooling mode, the method includes detecting and diagnosing low airflow and low cooling capacity faults in steps 138 through 158. In some embodiments in cooling mode, the method includes performing FDD of refrigerant superheat based on t*m and to in steps 138 through 158. If in heating mode, the method includes steps for detecting and diagnosing low heating capacity faults in steps 154 through 182.
At step 138, the method includes checking if the cooling system has been operating for at least a minimum cooling run time, preferably five minutes, and if not, then the method includes checking short cycle cooling operation for five successive cycles (i.e., failing the test of step 138 five consecutive times) at Step 140, and if yes, then generating an FDD alarm signal reporting a cooling short cycle fault at Step 142.
After the minimum fan run time of cooling system operation at Step 144, the method includes calculating the actual temperature split difference (δTa) based on the mixed-air drybulb temperature (tm) minus the supply-air temperature (ts) according to the following equation.
δTa=tm−ts Eq. 43
At step 144, the method also includes calculating the target temperature split difference (δTt) across the cooling system evaporator and the temperature split difference ΔTS defined as the actual temperature split minus the target temperature split. The method includes calculating the target temperature split difference (δTt) using a target temperature split lookup table shown in
δTt=C7+C8tm+C9tm2+C10t*m+C11t*m2+C12(tm×t*m) Eq. 45
Where, δTt=target temperature difference between mixed-air and supply-air in cooling mode (F),
At step 144, the method also includes calculating the delta temperature split difference (ΔTS) based on the actual temperature split difference (δTa) minus the target temperature split difference (δTt) using the following equation.
ΔTS=δTa−δTt Eq. 47
Where, ΔTS=delta temperature split difference between actual temperature split and target temperature split (F).
At step 146 the method checks whether or not the temperature split difference ΔTS is within plus or minus a temperature split threshold, preferably ±3 degrees Fahrenheit (or a user input value). If ΔTS is within plus or minus the temperature split threshold (or the user input value), then the cooling system is within tolerances, no FDD alarm signals are generated, and the method loops back to continue checking proper operation of the cooling system by repeating steps 144 and 146.
At step 148, the method checks whether or not the temperature split difference (ΔTS) is less than a negative minimum temperature split difference threshold, preferably less than −3 degrees Fahrenheit (or a user input value). If the method determines the temperature split difference (ΔTS) is less than the negative minimum temperature split difference threshold (or the user input value), then the method includes providing an FDD alarm signal reporting a low cooling capacity fault at step 152 to check for low cooling capacity which can be caused by many faults including excess outdoor airflow, dirty or blocked air filters, blocked evaporator caused by dirt or ice buildup, blocked condenser coils caused by dirt or debris buildup, low refrigerant charge, high refrigerant charge, refrigerant restrictions, or non-condensable air or water vapor in the refrigerant system.
At step 148, if the method determines that the temperature split difference (ΔTS) is not greater than the negative minimum temperature split difference threshold, then the method includes providing an FDD alarm signal at step 150 reporting a low airflow fault to check for low airflow which can cause ice to form on the air filter and evaporator which blocks airflow and severely reduces cooling capacity and efficiency.
At step 136 if the method determines the system is in heating mode, then the method includes proceeding to step 154.
At step 154, the method includes checking if the heating system has been operating for greater then a minimum heater run time, preferably five minutes, and if no, then the method includes checking short cycle heating operation for 5 successive cycles at Step 156, and if yes, then generating an FDD alarm signal reporting a heating short cycle fault at Step 158.
After at least the minimum heater run time of heating system operation at Step 160, the method includes calculating the actual temperature rise (δTRa) for heating based on the supply-air temperature minus the mixed-air temperature according to the following equation.
δTRa=ts−tm Eq. 49
At step 162, the method includes checking whether or not the heating system is a gas furnace, and if the method determines the heating system is a gas furnace, then the method proceeds to step 164.
At step 164, the method includes calculating the minimum acceptable target supply-air temperature rise for a gas furnace which is preferably a function of airflow and heating capacity based on furnace manufacturer temperature rise data shown in
δTRt
Where, δTRt
The minimum acceptable furnace temperature rise may vary from 30 to 100 degrees Fahrenheit or more depending on make and model, furnace heating capacity, airflow, and return temperature.
At step 164, the method also includes calculating the delta temperature rise for the gas furnace heating system, ΔTRfurnace, according to the following equation.
ΔTRfurnace=δTa−δTRt
At step 170 the method includes calculating whether or not the delta temperature rise for the furnace is greater than or equal to zero degrees Fahrenheit according to the following equation.
ΔTRfurnace=δTa−δTRt
At step 170, if the method determines the delta temperature rise for the furnace is greater than or equal to zero degrees Fahrenheit, then the gas furnace heating system is considered to be within tolerances, no FDD alarm signals are generated, and the method includes a loop to continue checking the temperature rise while the furnace heating system is operational using steps 160 through 170.
At step 170, if the method determines the delta temperature rise for the furnace is less than zero degrees Fahrenheit, then proceeds to step 172.
At step 172, for a gas furnace heating system, the method includes preferably providing at least one FDD alarm signal reporting a low heating capacity fault which can be caused by excess outdoor airflow, improper damper position, improper economizer operation, dirty or blocked air filters, low blower speed, blocked heat exchanger caused by dirt buildup, loose wire connections, improper gas pressure or valve setting, sticking gas valve, bad switch or flame sensor, ignition failure, misaligned spark electrodes, open rollout, open limit switch, limit switch cycling burners, false flame sensor, cracked heat exchanger, combustion vent restriction, improper orifice or burner alignment, or non-functional furnace.
At step 162, the method includes checking whether or not the heating system is a gas furnace, and if the method determines the heating system is not a gas furnace, then the method proceeds to step 170.
At step 174, the method includes checking whether or not the heating system is a heat pump, and if the method determines the heating system is a heat pump, then the method proceeds to step 176.
At step 176, the method includes measuring the target temperature rise for heat pump heating based on the minimum acceptable target temperature rise which is preferably a function of outdoor air temperature as shown in the following equation based on heat pump manufacturer minimum acceptable temperature rise data shown in
δTRt
Where, δTRt
At step 176, the method also includes calculating the delta temperature rise for the heat pump heating system according to the following equation.
ΔTRheat pump=δTa−δTRt
At step 178, the method includes calculating whether or not the delta temperature rise for the heat pump heating system is greater than or equal to zero degrees Fahrenheit according to the following equation.
ΔTRheat pump=δTa−δTRt
At step 178, if the method determines the delta temperature rise for the heat pump is greater than or equal to zero degrees Fahrenheit, then the heat pump heating system is considered to be within tolerances, no FDD alarm signals are generated, and the method includes a loop to continue checking the temperature rise while the heat pump heating system is operational using steps 160 through 178.
At step 178, if the method determines the delta temperature rise for the heat pump is less than zero degrees Fahrenheit, then the method proceeds to step 172.
At step 172, for a heat pump heating system, the method includes preferably providing at least one FDD alarm signal reporting a low heating capacity fault to check the system for low heating capacity which can be caused by many faults including excess outdoor airflow, improper damper position, improper economizer operation, dirty or blocked air filters, blocked heat pump indoor coil caused by dirt buildup, improper thermostat setup or malfunction, loose wire connections, blocked outdoor coil caused by ice, dirt or debris, defective capacitor or relay, failed outdoor coil fan motor or capacitor, failed reversing valve or improper reversing valve control, improper refrigerant charge, refrigerant restriction (filter drier or expansion device), non-condensable air or water vapor in system, malfunctioning defrost controller, high airflow above 450 cfm/ton, failing compressor (locked rotor, leaking valves, etc.), or non-functional heat pump.
At step 174, if the method determines the heating system is not a heat pump, then the method proceeds to step 180.
At step 180, the method measures the target temperature rise for the hydronic heating system based on the minimum acceptable target supply-air temperature rise according to the following equation which is preferably a function of hot water supply temperature and may vary from 18 to 73 degrees Fahrenheit depending on airflow, coil heating capacity, and hot water supply temperature, thw, as shown in
δTRt
Where, δTRt
The method also includes the following simplified equation to measure the target temperature rise for the hydronic heating system for all systems regardless of hot water supply temperature as shown in
δTRt
Where, δTRt
At step 180, the method also includes calculating the delta temperature rise for the hydronic heating system according to the following equation.
ΔTRhydronic=δTa−δTRt
At step 182, the method includes calculating whether or not the delta temperature rise for the hydronic heating systems greater than or equal to zero degrees Fahrenheit according to the following equation.
ΔTRhydronic=δTa−δTRt
At step 182, if the method determines the delta temperature rise for the hydronic heating system is greater than or equal to zero degrees Fahrenheit, then the hydronic heating system is considered to be within tolerances, no FDD alarm signals are generated, and the method includes a loop to continue checking the temperature rise while the hydronic heating system is operational using steps 160 through 182.
At step 182, if the method determines the delta temperature rise for the hydronic heating system is less than zero degrees Fahrenheit, then the method proceeds to step 172.
At step 172, for a hydronic heating system, the method includes preferably providing at least one FDD alarm signal reporting a low heating capacity fault to check the system for low heating capacity which can be caused by many faults including excess outdoor airflow, improper damper position, improper economizer operation, dirty or blocked air filters, blocked hydronic coil caused by dirt buildup, improper thermostat setup or malfunction, loose wire connections, failed or stuck hydronic control valve, defective capacitor or relay, low hot water temperature setting, failed water heater or boiler, leak or loss of hydronic fluid, failed capacitor, high airflow above 450 cfm/ton, air in hydronic system, or non-functional hydronic circulation controller or pump.
In some embodiments, the method includes providing FDD alarms regarding the following faults: excess outdoor air, damper actuator failure, low airflow, low cooling capacity, or low heating capacity. In some embodiments the present invention includes methods to communicate FDD alarms using wired or wireless communication to display error codes or alarms on the present invention apparatus through a built-in display or external display through wired or wireless communication signals to a building energy management system, standard thermostat, WIFI-enabled thermostat, internet-connected computer, internet telephony system, or smart phone indicating maintenance requirements to check and correct outdoor air damper position, evaporator airflow and/or refrigerant charge of the air conditioning system.
While the invention herein disclosed has been described by means of specific embodiments and applications thereof, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope of the invention set forth in the claims.