The subject matter disclosed herein relates to a brazed plate water-cooled gas cooler/condenser.
Container customer demands dictate that container refrigeration units (CRUs) have the capability to reject heat to a water source and the capability to reject heat to the ambient air. This typically happens when the CRUs are on board a ship, where the water-cooled heat rejection heat exchanger is typically positioned in a refrigerant circuit downstream from an air-cooled heat rejection heat exchanger, with respect to a direction of refrigerant flow (although other configurations are also feasible). In these cases, when the unit uses the water-cooled heat rejection heat exchanger as the heat sink, the air-cooled heat rejection heat exchanger is typically rendered inoperable. This is achieved by turning the condenser fan off.
The currently known water-cooled heat rejection heat exchanger design is the shell-and-tube type, with the water on the tube side, and the refrigerant on the shell side. The heat exchanger shell for these units is typically made of carbon steel to contain refrigerant and cupronickel tubes to contain water. Cupronickel is chosen for its excellent resistance to corrosion when exposed to sea water, as sea water in the past has been used as the water source. It has to be understood, that although this configuration is preferred for a number of reasons, refrigerant can be flown inside the tubes and water contained on the shell side. Also, other liquid coolants, such as glycol solutions, can be utilized in place of water. The population of CRUs made with the water-cooled heat rejection heat exchangers is about 20% of the total production volume.
Typically, water-cooled heat rejection heat exchangers of CRUs operate as condensers, where refrigerant flown through the heat rejection heat exchanger is below the critical point and is condensing from vapor to liquid. However, for some refrigerants (such as carbon dioxide), a water-cooled heat rejection heat exchanger may operate as a condenser for a portion of the time, while operating as a gas cooler for another portion of the time. In the latter case, refrigerant flown through the heat rejection heat exchanger is above the critical point and, while cooled by water, is maintained in a single phase. Additionally, the high operating pressures induced by refrigerants such as carbon dioxide require special structural design considerations for the heat rejection heat exchangers. Lastly, other heat exchangers, such as intercoolers positioned between the compression stages, may assist in the heat rejection process.
According to one aspect of the invention, a heat rejection heat exchanger is provided and includes a housing having first and second opposing end plates and sidewalls extending between the end plates to form an enclosure, at least the first end plate including first and second inlet/outlet pairs for first and second fluids, respectively, a plurality of plates disposed within the enclosure between the first and second end plates to define a first fluid pathway disposed in fluid communication with the first inlet/outlet pair and a second fluid pathway disposed in fluid communication with the second inlet/outlet pair and a plurality of brazed formations disposed between adjacent ones of the first end plate, the plurality of plates and the second end plate to isolate the first fluid pathway from the second fluid pathway.
According to another aspect of the invention, a heat rejection heat exchanger is provided and includes a housing having first and second opposing end plates and sidewalls extending between the end plates to form an enclosure, at least the first end plate including high and low temperature inlet/outlet pairs for high and low temperature fluids, respectively, a plurality of plates disposed within the enclosure between the first and second end plates to define a high temperature fluid pathway disposed in fluid communication with the high temperature inlet/outlet pair and a low temperature fluid pathway disposed in fluid communication with the low temperature inlet/outlet pair and a plurality of brazed formations disposed between adjacent ones of the first end plate, the plurality of plates and the second end plate to isolate the high temperature fluid pathway from the low temperature fluid pathway.
According to yet another aspect of the invention, a refrigeration unit is provided and includes a vapor compression cycle including an evaporator, an air-cooled heat rejection heat exchanger and a compressor operably disposed between the evaporator and the condenser, and a water-cooled brazed plate heat rejection heat exchanger operably disposed between the compressor and the evaporator receiving high temperature fluid from the compressor and low temperature fluid from an external source, whereby the high temperature fluid is cooled via thermal communication with the low temperature fluid and is flown from the compressor to the evaporator, the water-cooled brazed plate heat rejection heat exchanger being formed to define high and low temperature fluid pathways and including a plurality of brazed formations to isolate the high temperature fluid pathway from the low temperature fluid pathway.
These and other advantages and features will become more apparent from the following description taken in conjunction with the drawings.
The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The foregoing and other features, and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:
The detailed description explains embodiments of the invention, together with advantages and features, by way of example with reference to the drawings.
With reference to
The vapor compression cycle unit 12 may further include a heat rejection heat exchanger 13, such as a water-cooled brazed plate heat rejection heat exchanger 50. The water-cooled brazed plate heat rejection heat exchanger 50 is operably disposed between the compressor 40 and the evaporator 20 and is configured to be in fluid communication with the air-cooled heat rejection heat exchanger 30 and sources of high temperature fluid (e.g. compressor) and low temperature fluid (e.g. water tank), respectively. Within the water-cooled brazed plate heat rejection heat exchanger 50, the high temperature fluid is cooled via thermal communication with the low temperature fluid and the cooled high temperature fluid is then flown from the water-cooled brazed plate heat rejection heat exchanger 50 toward the evaporator 20. As will be described below with reference to
The high temperature fluid is flown from the high temperature fluid source (typically compressor) to the air-cooled heat rejection heat exchanger 30 in thermal communication with ambient air, when an associate fan 140 is operational, through the water-cooled brazed plate heat rejection heat exchanger 50 in thermal communication with the low temperature fluid (when in operation) flown from the low temperature source (such as water tank) and then to the evaporator 20.
In accordance with embodiments, the high temperature fluid may include conventional refrigerants operating below the critical point and condensing during heat transfer interaction in the air-cooled heat rejection heat exchanger 30 and the water-cooled brazed plate heat rejection heat exchanger 50 (while in operation) or refrigerants, such carbon dioxide, operating below the critical point, at least for a portion of the time and above the critical point for another portion of the time, and the low temperature fluid may include water or glycol solutions. While operating above the critical point, refrigerant remains in a single phase. However, it is to be understood that other fluids and/or gases may be used interchangeably within the scope of the description provided herein.
As shown in
The water-cooled brazed plate heat rejection heat exchanger 50 is operably disposed downstream from the condenser/gas cooler 31. Refrigerant leaving the condenser/gas cooler 31 is transmitted to the water-cooled brazed plate heat rejection heat exchanger 50 for further cooling operations therein, when each heat exchanger is actively engaged in the heat transfer interaction, with ambient air and a source of the cold fluid respectively. However, the condenser/gas cooler 31 and the water-cooled brazed plate heat rejection heat exchanger 50 can be used interchangeably depending on availability of the ambient air and cold fluid source. For instance, while onboard a ship, only a cold fluid source may be available, rendering only water-cooled brazed plate heat rejection heat exchanger 50 operational.
A secondary water-cooled brazed plate heat rejection heat exchanger 60 may be operably interposed between the intercooler 32 and the second stage compressor 42. Cooled refrigerant vapor from the intercooler 32 may be flown to the second stage compressor 42 passing through the secondary water-cooled brazed plate heat rejection heat exchanger 60 for further cooling communication therein. Similar to the condenser/gas cooler 31 and the water-cooled brazed plate heat rejection heat exchanger 50, intercooler 32 and secondary water-cooled brazed plate heat rejection heat exchanger 60 may operate simultaneously or alternately with one another depending on the low temperature source availability.
It also has to be understood that the water-cooled brazed plate heat rejection heat exchanger 50 and the secondary water-cooled brazed plate heat rejection heat exchanger 60 may both be disposed upstream of the condenser/gas cooler 31 and the intercooler 32, respectively. Further, the water-cooled brazed plate heat rejection heat exchanger 50 and the secondary water-cooled brazed plate heat rejection heat exchanger 60 may be two separate units, as depicted on
The vapor compression cycle unit 12 may further include a flash tank 70, a high pressure regulating valve 80, which is operably interposed between the water-cooled brazed plate heat rejection heat exchanger 50 and the flash tank 70, and an evaporator expansion valve 90. The evaporator expansion valve 90 is operably interposed between the flash tank 70 and the evaporator 20. The high pressure regulating valve 80 conveys the cooled high temperature fluid in the 2-phase thermodynamic state to the flash tank 70, which is configured to separate the gaseous phase from the liquid phase. Once the separation is complete, the flash tank 70 communicates the gaseous phase to the compressor 40 by way of a shutoff valve and check valve combination 95 and directs the liquid phase to the evaporator 20 via the evaporator expansion valve 90. The evaporator expansion valve 90 communicates the further expanded high temperature fluid in the 2-phase thermodynamic state to the evaporator 20. A probe 100, such as a pressure gage or a thermocouple, may be operably interposed between the high pressure regulating valve 80 and the flash tank 70.
The container refrigeration unit 10 and/or the vapor compression cycle unit 12 may further include a motor 110 to drive the compressor 40 and a variable frequency drive 120. The variable frequency drive 120 serves to actuate the motor 110 to drive the compressor 40 at varying speeds. In accordance with embodiments, the variable frequency drive 120 may be disposed at one or more of multiple positions including, but not limited to, a position #1 proximate to the evaporator 20, a central position #2, a position #3 proximate to the flash tank 70, a position #4 proximate to the secondary water-cooled brazed plate heat rejection heat exchanger 60, a position #5 proximate to the water-cooled brazed plate heat rejection heat exchanger 50 and an external position #6.
As shown in
With reference to
The plurality of plates 52 along with the other components of the water-cooled brazed plate heat rejection heat exchanger 50 are typically formed of stainless steel or another similar material. The plurality of plates 52 is disposed within the enclosure formed between the first and second end plates 511 and 512 to define the high and low temperature fluid pathways 501 and 502 with the high temperature fluid pathway 501 being disposed in fluid communication with the first inlet/outlet pair 53 and the low temperature fluid pathway 502 being disposed in fluid communication with the second inlet/outlet pair 54. The plurality of brazed formations 503 is formed between adjacent ones of the first end plate 511, the plurality of plates 52 and the second end plate 512 to isolate the first fluid pathway 501 from the second fluid pathway 502 and vice versa.
In accordance with embodiments and, as shown in
While the invention has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the invention is not limited to such disclosed embodiments. Rather, the invention can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the invention. Additionally, while various embodiments of the invention have been described, it is to be understood that aspects of the invention may include only some of the described embodiments. Accordingly, the invention is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims.
This application is a National Stage Application of PCT Application No. PCT/US2012/023334 filed Jan. 31, 2012, which is a PCT Application of U.S. Provisional Application No. 61/440,662 Filed Feb. 8, 2011, the disclosures of which are incorporated by reference herein in their entireties.
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PCT/US2012/023334 | 1/31/2012 | WO | 00 | 8/7/2013 |
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WO2012/109057 | 8/16/2012 | WO | A |
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