This invention relates generally to refrigerated transport compartments and more specifically to a method and system for improving temperature control in a multiple compartment refrigerated transport.
Transport refrigeration systems are used for transporting perishable goods, such as refrigerated and frozen food products. Transport refrigeration systems include refrigerated containers, trucks, and railroad cars. Some products require more accurate temperature control of the refrigerated compartment than others to preserve product freshness. For example, some frozen foods may need only to be kept below a certain freezing temperature, with less sensitivity to a specific set point temperature. Other goods, such as some perishable produce such as fruits or vegetables might require a tighter temperature regulation to preserve optimal product freshness.
Transport refrigeration systems can be divided into two or more compartments by inserting an internal wall. The individual spaces can be kept at different temperatures. For example, one compartment can be a freezer compartment and the other compartment can be refrigerated. Typically such dual compartment shipping container systems use one refrigeration compressor and two evaporators, one for each compartment. While the primary compartment might have a proportional refrigerant pressure control, the existing method of secondary compartment temperature control is to cycle on and off the liquid refrigerant line to the secondary compartment evaporator. This method of cycling the secondary evaporator liquid refrigerant line on and off to control the temperature in the secondary compartment cannot achieve the temperature regulation tolerance that is needed in many applications. Therefore what is needed is a method and apparatus to improve the temperature regulation in a secondary refrigerated compartment.
Another problem involving multiple compartment transport refrigeration systems is how to apportion the available cooling capacity at startup and/or under high load conditions, such as when the ambient temperature is very high. What is needed is a control algorithm to apportion available cooling capacity by a priority system between a primary compartment and a secondary compartment.
Yet another problem is to limit the electrical power consumption of a multiple compartment transport refrigeration system at startup and/or under high load conditions, such as when the ambient temperature is very high. For example, ocean going container ships may have power limits and/or circuit breakers that limit the ampacity of the electrical power supply line to each refrigerated transport container. A typical current limit is 15 to 23 amperes, with circuit interruption protection typically set to 30 amperes (maximum). Therefore, what is also needed is a method of control for a multi-compartment transport refrigeration system that can limit the electrical load to a preset value while apportioning the resulting cooling capacity between the compartments.
A refrigerated transport system includes a compressor to supply high pressure refrigerant vapor to a condenser. The compressor is coupled to the condenser, the condenser to condense the high pressure vapor to a high pressure liquid. The refrigerated transport system also includes a primary compartment evaporator to accept heat from the air in a primary compartment and to transfer the heat to a refrigerant circulated within the primary compartment evaporator to refrigerate the primary compartment, the primary compartment evaporator coupled to a primary compartment expansion device for receiving low pressure liquid from the primary compartment expansion device. The primary compartment expansion device is coupled to the condenser, and a primary refrigerant flow through the primary compartment evaporator is controlled by a controller using a primary compartment temperature feedback from a temperature sensor in the primary compartment to control the temperature in the primary compartment. The refrigerated transport system also includes at least one secondary compartment evaporator to accept heat from the air in a secondary compartment and to transfer the heat to a refrigerant circulated within the secondary compartment evaporator to refrigerate the secondary compartment, the secondary compartment evaporator is coupled to a secondary compartment expansion device for receiving low pressure liquid from the secondary compartment expansion device. The secondary compartment expansion device is coupled to the condenser. A secondary refrigerant flow through the secondary compartment evaporator is controlled by a controller using a secondary compartment temperature feedback from a temperature sensor in the secondary compartment to control the temperature in the secondary compartment and wherein a prioritizing algorithm limits the maximum amount of refrigerant flow available to at least one limited cooling compartment by holding a delta T (difference between the supply air temperature and return air temperature) instead of a setpoint temperature in the at least one limited cooling compartment when the available cooling capacity is insufficient to hold a substantially constant temperature in all compartments.
A method for creating multiple refrigerated compartment spaces having precision temperature control includes the steps of: providing a common compressor to supply high pressure refrigerant vapor; providing a common condenser to condense the high pressure refrigerant vapor to a high pressure liquid; providing a primary compartment evaporator to accept heat from the air in a primary compartment and to transfer the heat to a refrigerant; providing a secondary compartment evaporator to accept heat from the air in a secondary compartment and to transfer the heat to a refrigerant; compressing the refrigerant; condensing the refrigerant; supplying the refrigerant via expansion devices to the primary compartment evaporator and the secondary compartment evaporator; regulating the refrigerant flow to the primary compartment evaporator and the secondary compartment evaporator to control the temperature in both compartments to respective setpoint temperatures using temperature feedback signals from each respective compartment; prioritizing the compartments by identifying at least one priority compartment to be held at a setpoint temperature; and limiting refrigerant flow to all but the priority compartment when there is insufficient cooling capacity to maintain all compartments at their respective setpoint temperatures.
For a further understanding of these and objects of the invention, reference will be made to the following detailed description of the invention which is to be read in connection with the accompanying drawing, where:
The solution to the problem of achieving precision temperature control in a secondary transportation compartment as shown in
The operation of the exemplary dual compartment refrigerated container according to the invention as shown in
To accommodate precise temperature control in a secondary compartment (compartment 2), the high pressure liquid refrigerant that supplies TXV 104 can also supply refrigerant to a second TXV 110. Note that solenoid valve 112 is provided to turn off (secure) the refrigeration in compartment 2, but that solenoid valve 112 is not used for temperature control of compartment 2 as is done by the prior art. TXV 110 causes the liquid refrigerant to expand to a low pressure liquid. Secondary compartment evaporator 109 transfers heat energy from the secondary compartment to the refrigerant circulating in evaporator 109 converting it from a low pressure liquid to a low pressure vapor. An electronic suction modulating valve ESMV 108 regulates the temperature in a secondary compartment (compartment 2) using electronic controls as described below.
Prior art solutions have added remote refrigeration compartments by cycling on and off the liquid refrigerant supply line to a secondary compartment evaporator to attempt to maintain an evaporator pressure or to maintain a crude temperature regulation in the remote compartments. According to the invention, the temperature in a secondary connected refrigeration compartment (such as a compartment 2 shown in
Computational blocks 205 and 210 include algorithms such as PID control algorithms to modulate (set the position of) ESMV 102 and ESMV 108. When there is adequate cooling capacity as provided by compressor 119 and condenser 118 both PID control loop algorithms modulate the corresponding ESMV to maintain the temperature in each respective compartment as is typically measure using a supply side temperature sensor (such as temperature sensors 204 and 211). However at unit startup and/or during high ambient temperature there might not be enough cooling capacity available for both compartments.
The solution to multiple compartment refrigeration where refrigeration loading exceeds the available refrigeration capacity is to use an algorithm to prioritize refrigeration in one compartment over the other. For example, during startup, most of the cooling capacity can be used to cool a primary compartment that is to be kept below freezing. The freezer compartment ESMV can be modulated to, full open or near fully open, giving maximum refrigerant flow to the corresponding freezer compartment evaporator. During the initial cool down, the ESMV used for the secondary chilled compartment can be modulated to a near closed position. The near closed position can be chosen such that some refrigerant flow is still available at the minimum ESMV modulation position, so some cooling will begin in the secondary compartment. According to one exemplary prioritization, a prioritized primary compartment freezer PID loop will eventually be satisfied when the freezer compartment nears and eventually holds the desired sub zero temperature set point within some preset temperature range. A secondary compartment PID loop is allowed to modulate its ESMV open, perhaps as far as full open, as system cooling capacity becomes available as the primary (higher priority) compartment nears setpoint. With the increased refrigerant flow available to the secondary compartment evaporator, the secondary compartment PID control similarly achieves the desired secondary compartment setpoint temperature within its present allowable temperature range. In the event that some condition, such as an anomalously high ambient temperature, causes the primary freezer compartment to exceed its allowable temperature range, the priority algorithm can limit the maximum setting to the secondary compartment ESMV, thus diverting most or all of the available cooling capacity to the higher priority compartment. In the exemplary description above, it can be seen that it is important to maintain a freezing condition in the higher priority freezer compartment, even at the expense of allowing a wider than normal deviation of the temperature in a secondary refrigeration compartment. In this case, the temporary loss of a precise refrigeration temperature control in the secondary compartment less important than the risk of a thawing condition in the high priority freezer compartment.
According to one embodiment of the invention, a remote delta T can be set in the lower priority compartment. As used herein, remote delta T is the difference between the remote supply air temperature and the remote return air temperature. One way to apportion available cooling capacity between the compartments of a multi-compartment transport refrigeration system, is by setting a delta-T in a remote secondary compartment while allowing a prioritized compartment to make use of the remaining available refrigerant. By setting the remote delta T below that delta T that would otherwise exist with unlimited cooling, the flow of refrigerant to the remote secondary compartment is reduced, but not necessarily limited to an absolute minimum setting. In a remote delta T limiting situation, the remote ESMV is set to a position that allows the temperature difference between the supply and return air to equal the remote delta T setting. This setting allows for some minimal amount of cooling (but, not necessarily an absolute minimum amount) until the host unit reaches a condition where it doesn't require the majority of the capacity available. Ideally, the remote compartment can still maintain its current temperature, or even slowly lower in temperature, depending on the type of cargo in the remote compartment. A remote delta T setting of zero can be used to signal the controller board to shut off the remote unit totally until the host unit is ready to share some refrigerant. Note that a delta T of zero means that no cooling is being done by the remote evaporator because the remote supply air temperature and the remote return air temperature are the same when delta T equals zero.
The flow chart of
In the case of a freezer compartment, prioritizing actions are only required if the freezing temperature reaches a still frozen safety “ceiling”. As long as the freezing temperature is below the ceiling, there is no significant deterioration of the frozen goods. This path is shown by the “yes” arrow indicating a freezer compartment temperature below the ceiling that results in a still unrestricted flow of refrigerant to a lower priority secondary compartment. Note that even though in this case the secondary compartment has been deemed of lower priority, there could be a situation where perishable goods in the secondary compartment require a relatively tight temperature tolerance to limit deterioration. In this path, it can be seen that both products have been optimally protected, since the frozen goods remained frozen, albeit not exactly at the desired freezing temperature.
On the other hand, if the temperature in the prioritized freezer compartment is at or above the ceiling temperature, there can be a high risk that those goods might be destroyed by thawing if immediate action is not taken. Following the “No” arrow indicating a ceiling temperature or higher, the algorithm checks the delta T programmed setting for the remote compartment. If it is specified at zero (perhaps indicating an empty secondary compartment), the refrigerant flow to the secondary compartment can be completely turned off until the temperature of the prioritized freezer falls to below the ceiling temperature. Or, if the remote compartment delta T has not been set to zero, a predefined delta T can be used to provide a reduced refrigerant flow to the secondary compartment until the condition is remedied by the prioritized freezer temperature cooling to below the ceiling temperature.
The solution to coping with a finite electrical ampacity in the electrical power supply lines can also be handled by an algorithm to apportion available cooling capacity in light of power demands nearing a preset limit. In an exemplary situation, an ocean going container transport ship might limit the normal AC power load to each container to 23 amperes. Ideally a filled refrigerated compartment is roughly near set point from a precooling device used prior to loading the refrigerated container on the ship. There might be a somewhat higher power load caused by the relatively short time the container was without power, but it is likely that frozen products are still frozen and refrigerated products are still refrigerated below the ambient temperature. The initial cool down could still create a cooling load exceeding the available 23 ampere electrical supply line. More likely, the cooling load could exceed the available supply current during high ambient temperatures, such as a container in full sun with limited outside airflow on the hottest summer days. In such conditions, a multiple compartment refrigerated container according to the invention can cause a limit to be placed on the ESMV in the lower priority compartment. The limit can be to a fully closed modulation position (which still allows a minimal flow of refrigerant) or to some other limit below a full open modulation position. The electrical power limiting algorithm can monitor the load current on the electrical supply line from the container ship and vary the limit on then secondary ESMV to maintain the exemplary limit of 23 amperes. When the condition, such as an anomalous high ambient temperature subsides, the electrical power algorithm detects the lighter load and begins to increase the available maximum secondary compartment ESMV position until there are no restrictions and the secondary compartment PID loop is allowed to use the full available ESMV modulation range from some minimum percentage to some maximum percentage.
The algorithm illustrated by the flow chart of
Note that in either the case of insufficient cooling or the case of excessive electrical load current, a minimum delta T, but still above zero, can be pre-programmed into a prioritizing algorithm, or provision can be made on the software or firmware running on a controller board to allow an operator to manually enter a delta T value for the limited cooling compartment and/or the prioritized compartment.
A test was conducted to show how modulating the suction pressure from a secondary evaporator compares to prior art technology where secondary compartment temperature control has been achieved by cycling on and off the refrigerant flow to the supply line of the secondary evaporator.
A two compartment refrigerated container was built using the inventive dual suction temperature control method.
It should be noted that while the invention has been illustrated by embodiments having two compartments, that additional secondary compartments (including remote compartments) can be added using additional suction valves such as additional ESMVs.
While ESMV Other suction valves have been used in a preferred embodiment of the invention, other types of suction valves can be suitable for use in place of the ESMV units.
Sensors 204 and 211 have been described as thermistors using signal conditioning 207 and 212 as circuitry to convert a temperature sensitive resistance to a proportional voltage representing that resistance that can be digitized and correlated to a temperature. The circuitry has also been described as including filtering such as by RC filtering. A sensor such as a thermistor is preferred at least in part because it has a relatively large change in value over the typical temperature ranges encountered in refrigerated compartments. It should be noted however, that any type of sensor that can create a signal proportional to a measured temperature might be suitable for use in this application. Also, there is no specific requirement for signal conditioning blocks 207 and 212 (that can be located inside or outside of the compartment). For example, one modern sensor trend is towards smart sensors that include all needed signal conditioning in one package. Such a smart sensor might also eliminate the need for an ADC on controller blocks 205 and 210. Conversely, the invention could be implemented solely in analog electronics using all analog signals and linear negative feedback loops. There could be one conversion to digital signals to control the types of ESMV units heretofore described, or there could be other types of suction valves that can analog input signals to position the suction valve.
In a preferred embodiment, controllers 205 and 210 are part of a microcontroller board. Analog sensor signals can be converted to digital sensor signals off or on controller boards 205 and 210. Algorithms can include control loop techniques such as conventional proportional-integral-derivative (PID) or proportional-integral (PI) loops to control the suction valves based on temperature sensor 204 and 211 temperature measurements. Other feedback and control strategies including less traditional control loop approaches can be used as well as long as there is a suction valve in the refrigerant return line of an evaporator serving a remote compartment and it responsive to a temperature measurement made in the remote compartment.
While the present invention has been particularly shown and described with reference to the preferred mode as illustrated in the drawing, it will be understood by one skilled in the art that various changes in detail may be effected therein without departing from the spirit and scope of the invention as defined by the claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2006/002444 | 1/20/2006 | WO | 00 | 6/25/2008 |