Abstract:
In a transport refrigeration system which is susceptible to having its drive motors connected to a power source in reverse phase relationship to thereby operate the drive motors in reverse, provision is made to measure the current flow to the motors during operation in each direction and for comparing those current flows to determine which is greater and therefore representative of operation in the proper direction. A backup method is also provided for sensing the ambient temperature of the air downstream of the condenser coil, both before and during motor operation to determine whether the temperature during motor operation is greater than that prior to operation to thereby indicate a proper connection.

Description:
BACKGROUND OF THE INVENTION  
       [0001]     This invention relates generally to transport refrigeration systems and, more particularly, to a method and apparatus for sensing and correcting a reverse motor condition when a transport refrigeration system is operating in a stand-by mode.  
         [0002]     In a transport refrigeration system, such as a container, truck or truck trailer, for example, the power to operate the compressor and the fan motors of the refrigeration system is derived from a generator or alternator that is driven by the prime mover, i.e. the truck&#39;s engine. However, when the truck&#39;s engine is shut down, such as when it has reached its destination and waiting to be unloaded, for example, an auxiliary or a stand-by system at the site is relied on to provide that power.  
         [0003]     One problem that may occur when operating in stand-by power is that of a phase reversal, such that the electric motors are driven in the wrong direction. This results from that fact that the phase relationships may be reversed from one facility to another, such that a motor driven by the stand-by power may be caused to operate in the proper direction but may, just as well, be caused to operate in a reversed direction. If this occurs, then the motor driven equipment, such as the compressor, a condenser fan or an evaporator fan will not operate efficiently.  
         [0004]     One approach that has been employed in refrigerated containers wherein a scroll compressor is used, is that of sensing a pressure differential across the compressor to determine whether it is being driven in the proper direction. While this approach is satisfactory for systems with a scroll compressor, it is not effective when using reciprocating compressors since they have negligible pressure differential between correct and incorrect phasing.  
         [0005]     An alternative approach that has been used is to provide a dedicated electronic module to sense and correct phasing during two-phase stand-by operation. With this approach, the electronic module operates to sense the voltage drop across two of the three legs of the three-phase motor to see which phase is leading the others. While this approach is effective, it requires the use of a dedicated module, with its attendant manufacturing and reliability expense.  
       SUMMARY OF THE INVENTION  
       [0006]     Briefly, in accordance with one aspect of the invention, when a transport refrigeration system is first connected to a stand-by power system, it is first connected such that the drive motor is made to operate in a first direction, and the amount of current flow is sensed during that period of operation. The power is then disconnected and reconnected in such a way to cause the motor to operate in the opposite direction, and the current flow is again sensed during that period of operation. The two sensed levels of current flow are then compared and the one drawing the most current is determined to be the correct arrangement.  
         [0007]     By another aspect of the invention, a microprocessor is used to store the current flow measurements taken during the two operational periods and then automatically determining which arrangement resulted in the greatest current flow.  
         [0008]     In the event that the current sensing approach is not successful in producing a current differential, then a backup system is provided. An existing ambient temperature sensor, which is mounted to the condenser grill, is used for this purpose. If the condenser fan is caused to operate in reverse, the ambient temperature sensor will sense the relatively warm air coming off the condenser coil. That is, if the ambient temperature after start up is greater than the ambient temperature before start up, then the microprocessor will conclude that the phases are reversed.  
         [0009]     In the drawings as hereinafter described, a preferred embodiment is depicted; however, various other modifications and alternative constructions can be made thereto without departing from the true spirit and scope of the invention. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0010]      FIG. 1  is a schematic illustration of a transport refrigeration system with the present invention incorporated therein.  
         [0011]      FIG. 2  is a circuit diagram of a portion thereof showing particular components of interest.  
         [0012]      FIGS. 3A and 3B  illustrate a flow chart showing a method in accordance with one aspect of the invention. 
     
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0013]     Referring now to  FIG. 1 , the invention is shown generally at  10  as incorporated in a transport refrigeration system including, in serial flow relationship, a compressor  11  a condenser  12  a thermal expansion valve  13  and an evaporator  14 . Such a system is typically installed on a truck, trailer or container with the evaporator  14  providing the cooling function to the installation. Other components, such as a heater is normally included but is not shown. Draw-thru fans  16  and  17  are provided for the condenser  12  and evaporator  14 , respectively. The condenser fan  16  is driven by a motor  18  and the evaporator fan  17  is driven by the motor  19 . the compressor  11  is driven by a motor  21 . Each of these three drive motors are normally three-phase AC motors.  
         [0014]     In normal periods of operation, such as when the vehicle is in transit, power to the transport refrigeration system is provided by way of a generator or an alternator that is powered by the prime mover. When that vehicle is shut down, such as when it is parked at a facility awaiting loading or unloading. The transport refrigeration system is caused to operate in a stand-by condition wherein a power source at the facility is connected to the system. Such a power source is shown at  22  and is connected to the compressor motor  21  by line  23 , to the condenser motor  18  by the line  24 , and to the evaporator motor  19  by line  26 . Current sensors  27  and  28  are provided to sense the current flow in lines  23 ,  24  and  26 , respectively. A controller  31  is, in turn, connected to the sensors  27  and  28  by lines  32  and  33 , respectively. The sensing of current flow to the motors  18 ,  19  and  21  is important in the implementation of the present invention as will be discussed hereinbelow. In this regard, it should be mentioned that the current sensors are commonly included in such a system for other purposes, such as that of controlling total power.  
         [0015]     As discussed hereinabove, a problem that can occur with the connection to a power source  22  is that, because of the different phase relationships that exist at the various power sources, a reversed phase relationship can exist, which will cause the drive motors to operate in reverse. This will, of course, cause inefficiencies in the system and should be avoided.  
         [0016]     While the current measuring approach is the primary method used for determining whether the power source  22  is connected in proper phase relationship, a backup method is also provided, using preexisting components. A common component in such transport refrigeration system is an ambient temperature sensor with its output passing to the controller  31  for proper control of the unit. In the present system the ambient temperature sensor  36  is placed on the air inlet side of the condenser  12  as shown and connected to the controller by line  37 . The manner in which this is used as a backup method to determine whether the phase relationship is correct will be described more fully hereinafter.  
         [0017]     Referring now to  FIG. 2 , the circuitry for providing power to the motors is shown. The motors include the compressor motor  21 , the condenser motors  18   a  and  18   b,  and the evaporator fan motors  19   a  and  19   b.  The motors are all three phase motors with legs a, b and c as shown. The power source  22  is connected to each of the motors by way of contactors that are controlled by the controller  31 . That is, in the compressor drive motor  21  is connected by way of contactors CCON, the condenser motors  18   a  and  18   b  are connected by way of contactors CDCON, and the evaporator fan drive motors  19 A and  19 B are connected by way of contactors FCON. Current sensors  27  and  28  are provided to measure the current for purposes of determining whether the motors are properly connected in phase as will be more fully described hereinafter.  
         [0018]     The method, in accordance with one embodiment of the invention, is shown in  FIG. 3A and 3B . For use in the backup method, the ambient temperature (ATS1) is first measured and recorded in the controller  31 , as shown at block  41 .  
         [0019]     The contactors CDCON and EVCON are then closed to energize “phase abc” of their respective motors as shown in block  42 . The current sensors  27  and  28  are then used to sense and record the AC current for “phase abc” as shown in block  43 .  
         [0020]     Again, for purposes of the backup approach, the ambient temperature ATS2 is measured and recorded as shown at block  44 . This may or may not be used, depending on the success of the primary method.  
         [0021]     The CDCON and EVCON contactors are then opened to de-energize the “phase abc” mode and the contactors are then closed to energize the “phase acb” mode of operation as shown in block  46 . Again, the current sensors  27  and  28  are used to measure and record the AC current for those “phase acb” periods of operation as shown in block  47 .  
         [0022]     In block  48 , a third ambient temperature “ATS3” is measured and recorded for the backup method.  
         [0023]     In block  49 , the two measurements for “phase acb” and “phase acb” are compared to determine which is greater, which would indicate that more work was being done and therefore the correct phase relationship. Thus, if “phase abc” is greater than “phase acb”, the correct phasing is “abc” as shown in block  51 . On the other hand, if the “phase abc” is not greater than “phase acb” current, then we pass to block  52  wherein a determination is made as to whether the “phase abc” is less than “phase acb” current. If it is, then the correct phasing is “acb” as shown in block  53 . If those currents are the same, then we can determine that this method has been inconclusive, and we need to use the backup method as shown in block  54 .  
         [0024]     In block  56 , the stored temperatures are compared to determine whether “ATS2” is greater than “ATS1”. If it is, we can conclude that the fan motor  18  is operating in reverse with the hot air of the condenser is being blown over the sensor  36 , and therefore the correct phasing is “acb” as shown in block  57 . If it is not, then we pass to block  58  wherein a comparison is made between ATS3 and ATS1. If “ATS3” is greater than “ATS1” then we can conclude that the proper phasing is “abc” as shown in block  59 . If “ATS3” is not greater than “ATS1” then we can determine that the backup method is not conclusive either. In such a case, it would be necessary for the operator to investigate and determine why neither of these two methods were successful.  
         [0025]     While the present invention has been particularly shown and described with reference to a preferred embodiment as illustrated in the drawings, it will be understood by one skilled in the art that various changes in detail may be affected therein without departing from the true spirit and scope of the invention as defined by the claims.