This application relates to a refrigerant system having tandem compressors, wherein at least one compressor that has been shut down for a prolonged period of time, is periodically engaged for a short period of time to ensure proper oil return throughout the refrigerant system back to the tandem compressors.
Heating, ventilation, air conditioning and refrigeration (HVAC&R) systems are utilized to condition various environments. The HVAC&R systems typically use a refrigerant circulating throughout a closed-loop refrigerant circuit and are applied as air conditioners, heat pumps, refrigeration units, etc. Various enhancement techniques and system configurations are known and implemented to provide a required performance over a wide spectrum of environmental conditions to satisfy diverse thermal load demands.
In a very basic refrigerant system, a compressor compresses a refrigerant and delivers it downstream to a heat rejection heat exchanger, which is a condenser for subcritical applications and a gas cooler for transcritical applications. Refrigerant passes from the condenser to an expansion device, and from the expansion device to an evaporator. From the evaporator, refrigerant returns to the compressor. This basic refrigerant system is typically supplemented and enhanced by a number of different options and features to satisfy application requirements.
One such enhancement is the use of tandem compressors. Tandem compressors include a plurality of compressors operating in parallel each typically receiving refrigerant from a common suction manifold, each separately compressing the refrigerant and typically delivering the refrigerant to a common discharge manifold. Each of these compressors may be independently turned on or off to vary refrigerant system capacity at part-load operation. In this manner, the capacity provided by the tandem compressor subsystem to the overall refrigerant system can be tailored to the thermal load demands in the conditioned space as well as environmental conditions. Quite often, tandem compressor configurations include oil and/or vapor equalization lines connecting tandem compressors for functionality and reliability enhancement. Also, tandem compressors having only one suction or discharge common manifold are known in the art. Further, tandem compressor configurations may include at least some economized compressors that may have a common economizer manifold.
One concern with tandem compressors occurs when at least one of the tandem compressors is shut off under system part-load conditions. As one compressor is shut down, the refrigerant mass flow through the refrigerant system is substantially reduced, which can often lead to problems associated with lubrication oil not being returned back to the compressors. This occurs as reduced refrigerant mass flow causes oil to be retained throughout the refrigerant system, and in the evaporator in particular. This problem can become especially acute in refrigerant systems equipped with microchannel heat exchangers, since the size of the refrigerant channels in these heat exchangers is particularly small, and refrigerant flow may not have enough momentum to overcome viscous drag forces and to carry oil with it. The cause for the oil holdup and poor oil return back to the compressor unit is that the refrigerant mass flow throughout the refrigerant system and its components could be drastically reduced when some of the tandem compressors are shut off. Additionally, lubrication oil logged in the refrigerant system heat exchangers causes performance degradation for the heat exchanger and entire refrigerant system.
When a refrigerant system is operating with at least one tandem compressor turned off for a prolonged period of time, that one tandem compressor is periodically engaged for a short period of time. By engaging the shutdown compressor, the refrigerant mass flow through the system is increased instantaneously. In some applications, several or all of the tandem compressors can be engaged simultaneously or in sequence during this short period of time. When tandem compressors are activated in sequence, they can be deactivated in sequence as well or shut off simultaneously.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
The oil return problem can become especially acute when the economized compressor is shutdown for a prolonged period of time, as substantial amount of oil can be retained in the non-operating economizer heat exchanger and the economizer lines leading to the compressors.
The engagement of the shutdown compressors need not be for any undue length of time, simply, it should be long enough to ensure the proper oil return and short enough not to disrupt the controlled parameters in the conditioned space. The duration of compressor engagement can normally vary from 10 seconds to 10 minutes. As explained above, the time intervals t2 and t1 can be adjusted based upon environmental conditions and/or system operational characteristics, and depend on a particular configuration of the refrigerant system and tandem compressor unit. For instance, if one of two equally sized tandem compressors of the basic refrigerant system was shutdown for more than 2 hours at a saturated suction temperature of 45° F., this compressor can be activated for 2 minutes and then shut down again. To enhance oil return even further, a shutdown tandem compressor can be activated several times in sequence within a short period of time. This will create intermittent refrigerant flow that will facilitate the oil return process. For instance, for the example cited above, the shutdown tandem compressor can be activated 3 times for 1 minute intervals with 30 second 2 shutdown periods in between these intervals.
Furthermore, the shutdown tandem compressor engagement may be based upon a compressor safety device or a sensor. For instance, an oil level sensor may be installed in the compressor sump. If the oil level falls below a predetermined level, then at least one of the shutdown tandem compressors is turned on by the refrigerant system controller that had received a feedback from the oil level sensor.
If a refrigerant system has multiple (more than two) tandem compressors, such as shown in
The present invention augments time-averaged refrigerant system performance (capacity and efficiency) by removing the unwanted excessive oil from the internal surfaces of the heat rejection heat exchanger and evaporator, improving heat transfer and pressure drop characteristics for these heat exchangers. Also, system reliability is improved by ensuring the compressor has adequate lubrication oil amount. This application is especially beneficial for microchannel heat exchangers, where the oil return problem becomes especially prevalent. No new hardware is required for achieving this invention, and only the control logic for operation of the refrigerant systems having tandem compressors need to be enhanced. Further, this invention can be applied to newly built refrigerant systems and even to those systems that are now installed in the field. Also, it has to be recognized that the refrigerant system may be operated in the oil return mode during normal occupancy hours of the conditioned space or may be preferably controlled in this mode during unoccupied hours.
It should be pointed out that many different compressor types could be used in this invention. For example, scroll, screw, rotary, or reciprocating compressors can be employed.
The refrigerant systems that utilize this invention can be used in many different applications, including, but not limited to, air conditioning systems, heat pump systems, marine container units, refrigeration truck-trailer units, and supermarket refrigeration systems.
Although the embodiments of this invention have been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2007/080873 | 10/10/2007 | WO | 00 | 2/9/2010 |