The present invention relates to a climate control system and method for optimizing energy consumption in a vehicle.
Automatic climate control is increasingly prevalent in vehicles today. In some vehicles, a driver merely chooses a temperature setting, and a control system operates a climate control system to achieve the desired temperature. The climate control system may control the functions of a fan—e.g., on/off and fan speed—and an air conditioning system. Such a climate control system may also control the position and movement of various air dampers, or air flow doors, to control movement of air through an evaporator core or a heater core, the recirculation of air through the vehicle, the intake of fresh air, or some combination thereof.
The air conditioning system uses an air conditioning compressor and a condenser to effectuate cooling of a passenger cabin of the vehicle. A cooling fan is disposed adjacent the condenser to further effectuate cooling. One limitation of such systems is that operation of the air conditioning compressor and/or the cooling fan uses a relatively large amount of energy.
Moreover, some automatic climate control systems monitor a temperature and humidity level of the vehicle cabin to determine if a defogging operation of the windshield is desirable. When it is determined that an automatic defogging operation is desired, the air conditioning system is typically operated to provide a supply of relatively dry air to the windshield to quickly effect the defogging operation.
In the case of a conventional vehicle, where the engine mechanically drives the compressor, the increased load on the engine reduces efficiency and increases fuel consumption. Opportunities for controlling climate control systems to improve fuel economy are limited because the compressor power consumption depends upon the speed of the engine. Further, hot air mixing done to achieve a desired target discharge temperature often results in significant energy waste.
In the case of a hybrid electric vehicle (HEV), operation of an electric compressor and a cooling fan often necessitates starting the engine to ensure that the battery is not over-discharged. One of the benefits of an HEV is the fuel savings achieved by driving the vehicle using electric motor power, while maximizing the time the engine is shut down. Thus, inefficient operation of the climate control system can offset some of the benefits gained by driving an HEV. Accordingly, a need exists for a system and method for vehicle climate control that strikes a balance between meeting the comfort requirements of vehicle occupants and minimizing the overall power consumed by the climate control system.
In general, control of cabin temperature, as well as temperature and defogging of a windshield, within an automobile is accomplished using various actuators to adjust the temperature and flow of air supplied to the cabin of the vehicle.
The doors may be part of an air distribution system for directing the flow of conditioned air to various locations within a passenger cabin 29 of the vehicle, such as to the windshield, floor, or instrument panel as is commonly known. The doors 22, 24 and 28 may be driven by vacuum motors (not shown) between their various vacuum, partial vacuum and no vacuum positions in a conventional fashion as indicated in
The HVAC system 20 may also include a variable speed fan system (also referred to herein as an HVAC blower) 30 including a blower wheel 32 for generating airflow. The HVAC system 20 may further include a heating system, shown in
The heater core 34 and the evaporator core 36 respectively heat and cool the airflow generated by the fan system 30. The generated airflow may be distributed through an airflow distribution system and associated ducting 38. The HVAC system 20 may control the temperature, the direction of the airflow, and the ratio of fresh air to recirculated air. The HVAC system 20 may further include a low-pressure cycle switch 39 that communicates with the compressor 37. The low-pressure switch 39 may be operable to deactivate the compressor 37 under certain conditions. In addition, the compressor 37 can be deactivated when the evaporator core temperature drops below a predetermined value; this helps to prevent freezing of the evaporator core 36.
The liquid working fluid may then enter an expansion device 50, as is known in the art, which is in fluid communication with the condenser 46. As the working fluid moves through the expansion device 50, the pressure drops causing the working fluid to evaporate into a cooler, low-pressure gas. The evaporator core 36 may be provided in fluid communication with the expansion device 50 and the compressor 37. Upon reaching the evaporator 36, the working fluid absorbs heat thereby cooling the ambient air proximate to the evaporator. The HVAC blower 30 may be provided to further effectuate the cooling and force the cooled air into, for example, the passenger cabin 29 of the vehicle through the ducting 38. The working fluid, now a cold, low-pressure gas, may then re-enter the compressor 37 and the cycle repeats.
As described in more detail below, operation of the HVAC system 20 may be controlled by a climate control system 52.
In addition to receiving inputs from the sensors 58-72, the controller 54 may also receive inputs from a vehicle occupant via an input device 74. The input device 74 may be a control head as commonly used in vehicle instrument panels and illustrated in
The climate control head 74 may include a fan selector switch 84 for providing on-off, manual and automatic speed control of the HVAC blower 30. A recirculation switch 86 allows for full recirculation of cabin air, all fresh air, or some combination thereof. Further, an A/C switch 88 allows an occupant to manually select air conditioning. The control head 74 is just one example of a control head that can be used in accordance with embodiments of the present application. Other control heads, including other analog or digital control heads may also be used.
Turning now to
As shown in
Once the vehicle operating characteristics are measured, the system may determine whether the vehicle is in motion at step 104. For example, the system may conclude that the vehicle is moving if VS is greater than 0 mph. If the vehicle is not moving, there may be an opportunity to increase cooling fan speed in an effort to reduce total power consumption. Accordingly, the system may next determine if the engine cooling fan 48 is operating at its maximum rated power (FPmax), as provided at step 106. If FP1 is not at its maximum, then more cooling power can be added by increasing the engine cooling fan speed. As previously discussed, the cooling fan power curve as a function of cooling fan speed and the compressor power curve as a function of compressor speed may be mapped to one or more lookup tables. Thus, for the sake of simplicity, it can be assumed that a reference made to an increase or decrease in cooling fan power refers to an increase or decrease in cooling fan speed, and vice versa, respectively. Likewise, a reference made to an increase or decrease in compressor power may also refer to an increase or decrease in compressor speed, and vice versa, respectively.
Therefore, if FP1 is less than FPmax, the engine cooling fan power may be increased by a predetermined amount (Δ1), as shown at step 108. In this regard, cooling fan speed is increased by an amount that corresponds to an increase in cooling fan power of Δ1. Δ1 may be determined in one of several ways without departing from the scope of the present application. As one example, Δ1 may be determined according to one or more lookup tables, and may be affected by one or more environmental conditions, such as the ambient outside temperature. This is because the cooling impact of the engine cooling fan 48 may be more sensitive at higher temperatures. Additional lookup tables for determining Δ1 may be necessary for different vehicle speeds because the amount of air flowing through the condenser varies. As another example, Δ1 may be a constant value selected in accordance with design criteria and/or other vehicle and system restraints, constraints and specifications. The exemplary methodology of
As a result of the increase in cooling fan power, a second cooling fan power value is obtained (FP2), where FP2 equals FP1 plus Δ1. Next, at step 110, a second compressor power value (CP2) is measured corresponding to the amount of power being consumed by the electric compressor 37 once FP2 is obtained. It may next be determined whether increasing the engine cooling fan power by Δ1 resulted in a reduction in the amount of compressor power being consumed. Often, adding cooling power by increasing the engine cooling fan speed can allow the electric compressor speed to be reduced without substantially affecting the discharge air temperature. At step 112, it may be determined whether the compressor power was reduced by an amount greater than Δ1. In other words, as provided in
Should it be determined that compressor power consumption was reduced by an amount greater than the additional power, Δ1, being consumed by the engine cooling fan as a result of increasing the cooling fan speed, then it may be concluded that the increase in cooling fan power resulted in a net overall reduction in power consumption by the climate control system. As previously discussed, the less power consumed by the climate control system, the less the drain is on a vehicle's battery. Preserving battery charge can minimize the amount of time the engine is on, thereby improving fuel economy. Accordingly, if it is determined that the electric compressor power consumption was reduced by more than Δ1, then the engine cooling fan power may be maintained at FP2, as provided by step 114. On the other hand, if increasing the cooling fan power by Δ1 did not result in a reduction of compressor power more than Δ1, then the cooling fan speed may be set to its initial speed measured at step 102, where cooling fan power is equal to FP1, as provided at step 116. This is because increasing the cooling fan speed did not result in a net overall power savings for the climate control system.
Returning to step 104, if it is determined that the vehicle is moving, the method may proceed to step 118. Likewise, the method may proceed to step 118 should it be determined at step 106 that the engine cooling fan 48 is operating at its maximum rated power, FPmax. In other words, the methodology may proceed to step 118 if either the vehicle is moving or the engine cooling fan speed cannot be increased any further. At step 118, the power being supplied to the engine cooling fan 48 may be reduced by a predetermined amount (Δ2), providing the second cooling fan power value, FP2. Again, Δ2 may be determined in much the same way as Δ1. Once the cooling fan power has been reduced, the power being consumed by the electric compressor 37 is measured again to provide the second compressor power value, or CP2, at step 120. Likewise at step 120, the discharge air temperature is remeasured to provide a second discharge air temperature value (DAT2). Thus, input corresponding to the impact that reducing the engine cooling fan speed has on compressor speed and discharge air temperature can be obtained.
The method may then proceed to step 122 where it may be determined whether the discharge air temperature increased by more than a predetermined amount (X). If it is determined that the discharge air temperature did increase by an amount greater than X, then the engine cooling fan power may be set or returned to the first cooling fan power value, FP1, as provided at step 116. Although optimizing total power consumption by the climate control system in the air conditioning mode is part of the strategy illustrated in
On the other hand, should it be determined that the discharge air temperature did not increase by an amount greater than X, it may then be determined at step 124 whether the electric compressor power consumption increased by more than Δ2 as a result of the reduction in cooling fan power. In other words, it may be determined whether CP2-CP1<Δ2. If it is determined that the amount of power being consumed by the electric compressor 37, as a result of reducing the cooling fan power, increased by an amount greater than Δ2, then the method may proceed to step 116 where the cooling fan power is set to the first cooling fan power value, FP 1. The reason for this is that although power consumption by the cooling fan 48 was reduced by Δ2, such a reduction may result in an increase in the power consumed by the electric compressor 37 by more than Δ2 in order to achieve or otherwise maintain the automatic cabin temperature setting value. Thus, the result would be a net gain in overall power consumption, which is to be avoided. If, however, it is determined that reducing the cooling fan power by Δ2 does not result in a compressor power increase by more than Δ2, a net overall reduction in power consumption by the climate control system may be realized. In this instance, the reduction of cooling fan power by Δ2 may be maintained, as provided at step 124.
It should be noted that the methodology depicted in
Turning now to
As shown in
Referring briefly to
It should be noted that Tevap1 may provide a target evaporator core temperature base point representative of the target temperature in a dry air setting. The method may then proceed to step 208 wherein a dew point temperature (Tdew,) may be determined according to the following exemplary equation:
Tdew may account for how much humidity is present in the passenger cabin 29. It may then be determined whether the initial target evaporator core temperature, Tevap1, is greater than the dew point temperature, Tdew, at step 210. If Tevap1 is greater than Tdew, then the target evaporator core temperature (Tevap) may be set equal to the dew point temperature, Tdew, as provided at step 212. Setting Tevap equal to Tdew can adjust for the impact of relative humidity on passenger comfort. Alternatively, if it is determined that Tevap1 is not greater than Tdew, then the target evaporator core temperature, Tevap, may be set to the initial target evaporator core temperature, Tevap1, as provided at step 214.
Once the target evaporator core temperature, Tevap, is set to either the dew point temperature, Tdew, or the initial target evaporator core temperature, Tevap1, the methodology may proceed to step 216. At step 216, a fogging probability may be determined. The fogging probability may be determined by one or more known methods understood by those skilled in the art. For example, fogging probability may be determined according to methods disclosed in U.S. Pat. No. 5,516,041, entitled Method And Control System For Controlling An Automotive HVAC System To Prevent Fogging, which is hereby incorporated by reference in its entirety.
Determining the fogging probability at step 216 may produce a fogging probability value (Y). At step 218, it may be determined whether there exists a risk that a vehicle windshield will fog based upon the fogging probability value, Y. Should it be determined that a risk of fogging does not exist, the method may proceed to step 220 wherein the target evaporator core temp, Tevap, is maintained. If, however, it is determined that a risk of windshield fogging does exist based upon the fogging probability value, Y, then a second target evaporator core temperature (Tevap2) may be determined at step 222. To this end, the current target evaporator core temperature, Tevap, may be reduced by a predetermined amount (ΔTevap), wherein ΔTevap can be determined based upon a lookup table, such as table 92 depicted in
Again, the methodology 200 of
It should be noted that the methods of
While the best mode for carrying out the invention has been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention as defined by the following claims.
This application is a continuation of U.S. application Ser. No. 12/436,413, filed May 6, 2009.
Number | Date | Country | |
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Parent | 12436413 | May 2009 | US |
Child | 13487313 | US |