The present invention relates to a suction line heat exchanger, and more particularly, to a microchannel suction line heat exchanger for use in a refrigeration circuit.
The primary components of a typical refrigeration circuit include a compressor, a condenser, an expansion valve, and an evaporator. The evaporator receives a vapor refrigerant from the expansion valve and subjects the refrigerant to a medium to be cooled (e.g., an airflow). The thermodynamic state of the refrigerant exiting the evaporator is typically very near a saturated vapor but often contains a small amount of liquid refrigerant, which if introduced into the compressor may impair compressor operation and permanently damage the compressor.
Some refrigeration circuits braze the liquid tube upstream of the evaporator to the suction tube downstream of the evaporator to form a suction line heat exchanger. Other refrigeration circuits include tube-in-tube heat exchangers. However, these existing suction line heat exchangers suffer from very low effectiveness while entailing relatively high material and labor costs and taking up a substantial amount of space.
In one construction, the invention provides a refrigeration system including a refrigeration circuit that has an evaporator, a compressor, and a condenser that are fluidly connected and arranged in series with each other. A liquid line fluidly connects the evaporator to the condenser and a suction line fluidly connects the compressor to the evaporator. The refrigeration system also includes a heat exchanger that has a plurality of first refrigerant flow tubes that is in fluid communication with one of the suction line and the liquid line, and a second refrigerant flow tube that is in fluid communication with the other of the suction line and the liquid line. Each of the first refrigerant flow tubes and the second refrigerant flow tube have microchannels, and the second refrigerant flow tube positioned between and cooperates with the first refrigerant flow tubes to heat vapor refrigerant flowing in the suction line.
In another construction, the invention provides a refrigeration system including a refrigeration circuit that has an evaporator, a compressor, and a condenser that are fluidly connected and arranged in series with each other. A liquid line fluidly connects the evaporator to the condenser and a suction line fluidly connects the compressor to the evaporator. The refrigeration system also includes a heat exchanger that has a plurality of vapor refrigerant tubes in fluid communication with and receiving vapor refrigerant from the evaporator, and a liquid refrigerant tube sandwiched between the vapor refrigerant tubes and receiving liquid refrigerant from another portion of the refrigerant circuit. The heat exchanger further includes a first header positioned adjacent one end of the vapor refrigerant tubes and the liquid refrigerant tube, and a second header positioned adjacent the other end of the vapor refrigerant tubes and the liquid refrigerant tube to receive vapor refrigerant and liquid refrigerant adjacent both ends of the vapor and liquid refrigerant tubes.
In another construction, the invention provides a heat exchanger including an elongated body that defines an axis and that has a first end and a second end. The heat exchanger also includes first refrigerant flow tubes that define microchannels extending between the first end and the second end, and a second refrigerant flow tube that defines microchannels extending between the first end and the second end and at least partially positioned between the first refrigerant flow tubes. One of the first refrigerant flow tubes and the second refrigerant flow tube receives vapor refrigerant from an evaporator, and the other of the first refrigerant flow tubes and the second refrigerant flow tube receives liquid refrigerant from a source other than the evaporator. The heat exchanger also includes a header in fluid communication with the first refrigerant flow tubes and the second refrigerant flow tube. The header defines a vapor header section to receive vapor refrigerant and a liquid header section to receive liquid refrigerant such that vapor and liquid refrigerant flow through the heat exchanger in one of a counterflow and a unidirectional flow arrangement.
In another construction, the invention provides a heat exchanger including a plurality of first refrigerant flow tubes in fluid communication with one of a suction line and a liquid line, and a second refrigerant flow tube in fluid communication with the other of the suction line and the liquid line. Each of the first refrigerant flow tubes and the second refrigerant flow tube have microchannels. The second refrigerant flow tube is positioned between and cooperates with the first refrigerant flow tubes to heat vapor refrigerant flowing in the suction line, the refrigerant directed to or exiting the second refrigerant flow tube flows around a portion of at least one of the first refrigerant flow tubes.
In another construction, the invention provides a heat exchanger that includes a plurality of vapor refrigerant tubes receiving vapor refrigerant, and a liquid refrigerant tube sandwiched between the vapor refrigerant tubes and receiving a liquid refrigerant. A first header is positioned adjacent one end of the vapor refrigerant tubes and the liquid refrigerant tube, and a second header is positioned adjacent the other end of the vapor refrigerant tubes and the liquid refrigerant tube to receive vapor refrigerant and liquid refrigerant adjacent both ends of the vapor and liquid refrigerant tubes. One or both of the first and second headers includes longitudinally-spaced end walls and a partition that is positioned between the end walls and that separates a vapor header section and a liquid header section.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways.
The refrigeration circuit 10 also includes a receiver 25 located downstream of the condenser 20 to accumulate and store liquid refrigerant and an expansion valve 30 downstream of the receiver 25. An evaporator 35 receives refrigerant from the receiver 25 via a liquid line 37 and cools a medium (e.g., an airflow through a refrigerated display case) via heat exchange between refrigerant flowing through the evaporator 35 and the medium. The compressor 15 is fluidly connected to the evaporator by a suction line 38. An accumulator 40 may be disposed upstream of the compressor 15 and downstream of the evaporator 35 to store any liquid refrigerant not vaporized in the evaporator 35 and to deliver gaseous refrigerant to the compressor 15. As one of ordinary skill in the art will appreciate, the refrigeration circuit 10 can include other components depending on the desired characteristics of the refrigeration circuit 10 and the conditioning needs for which the refrigeration circuit 10 is being used.
As illustrated in
Specifically, each illustrated header 60 is defined by a top wall 80, a bottom wall 85, side walls 90 extending between the top and bottom walls 80, 85 (as viewed in
With reference to
The liquid header section 110 is bounded by the top wall 80, the bottom wall 85, the side walls 90, the inner end wall 95, and the partition 115. As shown in
The liquid port 135 of one header 60 defines an entrance for liquid refrigerant to the heat exchanger 50, and the liquid port 135 of the other header 60 defines an exit for liquid refrigerant from the heat exchanger 50. The top wall 80 includes an aperture 147 to allow refrigerant flow between the liquid header section 110 and the liquid port 135. As shown in
With reference to
Generally, each of the microchannel vapor and liquid tubes 70, 75 has a plurality of relatively small internal channels 160 that transfer heat between the liquid and vapor refrigerant in the respective tubes. As will be understood by one of ordinary skill in the art, the microchannels 160 define multiple internal passageways through the tubes 70, 75 that are smaller in size than the internal passageway of a coil in a conventional fin-and-tube evaporator. As illustrated, the microchannels 160 are defined by a rectangular cross-section, although other cross-sectional shapes are possible and considered herein. For example, each microchannel 160 of the illustrated tubes 70, 75 has a width of approximately 1.5 mm and a height of approximately 6 mm. In other constructions, the microchannels 160 may be smaller or larger depending on desired heat transfer characteristics for the heat exchanger 50. Thus, the quantity of microchannels 160 within each tube 70, 75 will depend on the width of the corresponding tube 70, 75 and the size of each microchannel.
Due to the flattened profile of each tube section 65, the tubes 70, 75 include one row of microchannels 160 spaced laterally across the width the tubes 70, 75, although other constructions of the heat exchanger 50 can include two or more rows of microchannels 160. The vapor and liquid tubes 70, 75 can be sized to accommodate the heat transfer requirements of the application for which the heat exchanger 50 is used. The precise length, width, and quantity of microchannels 160 are a function of the amount of refrigerant needed for the particular application to maximize heat transfer between the tubes 70, 75 while minimizing system refrigerant pressure drop. The microchannels 160 are fluidly coupled to and extend between the vapor and liquid header sections 105, 110.
As shown in
The illustrated heat exchanger 50 provides a longitudinal counterflow arrangement with respect to liquid refrigerant entering the heat exchanger 50 from the condenser 20 and vapor refrigerant entering the heat exchanger 50 from the evaporator 35. Alternatively, vapor refrigerant and liquid refrigerant can flow in the same direction in a parallel flow arrangement through the heat exchanger 50, depending on the desired heat transfer characteristics within the heat exchanger 50. As illustrated, the vapor header 60 and the liquid header 60 of each header 60 provide an efficient use of space, enhanced heat transfer, and system connection flexibility.
Generally, liquid refrigerant entering the liquid header 60 is in a subcooled state and is further subcooled upon exiting the liquid tube 75 by heat exchange with the vapor refrigerant in the adjacent vapor tubes 70. The partition 115 separates the vapor header section 105 from the liquid header section 110 so that vapor and liquid refrigerant do not commingle in the headers 60. The vapor header section 105 is in fluid communication with the vapor tubes 70 and receives vapor refrigerant flowing to or from the vapor tubes 70. The liquid header section 110 is in fluid communication with the liquid tube 75 and receives liquid flowing to or from the liquid tube 75.
In counterflow operation of the heat exchanger 50, condensed liquid refrigerant from the condenser 20 enters the liquid port 135 of one of the headers 60, flows through the adjacent liquid header section 110, and enters the openings 125 of the liquid tube 75. Vapor refrigerant from the evaporator 35 enters the vapor port 130 of the other header 60, flows through the adjacent vapor header section 105, and enters the openings 120 of the vapor tubes 70. As a result, vapor refrigerant in the vapor tubes 70 is heated via heat transfer from the warmer liquid refrigerant flowing within the sandwiched liquid tube 75. Subcooled liquid refrigerant exits the liquid tube 75 at the opposite openings 125, flows through the adjacent liquid header section 110, and out the liquid port 135 to the expansion valve 30. Heated (e.g., superheated) vapor refrigerant exits the vapor tubes 70 at the opposite openings 120, flows through the adjacent vapor header section 110, and out the vapor port 130 to the compressor 15.
Parallel, unidirectional flow operation of the heat exchanger 50 is similar to counterflow operation, except that vapor refrigerant and liquid refrigerant flow through the tube section 65 in the same direction. Specifically, in parallel, unidirectional flow operation of the heat exchanger 50, condensed liquid refrigerant from the condenser 20 enters the liquid port 135 of one of the headers 60, flows through the adjacent liquid header section 110, and enters the openings 125 of the liquid tube 75. Vapor refrigerant from the evaporator 35 enters the vapor port 130 of the same header 60, flows through the adjacent vapor header section 105, and enters the openings 120 of the vapor tubes 70. Like counterflow operation, vapor refrigerant in the vapor tubes 70 is heated by heat exchange with liquid refrigerant flowing within the sandwiched liquid tube 75. Heated vapor and subcooled liquid refrigerant exits the tube section 65 through respective openings 120, 125 in the same header 60. Vapor refrigerant then flows through the vapor header section 105 and out the vapor port 130 to the compressor 15, and liquid refrigerant flows through the adjacent liquid header section 110 and out the liquid port 135 to the expansion valve 30.
The microchannel vapor and liquid tubes 70, 75 of the heat exchanger 50, whether used in a counterflow or parallel unidirectional flow setup, maximize the heat transfer surface between the tubes 70, 75 while minimizing the size of the heat exchanger 50. In this manner, the cooling capacity of the refrigeration circuit 10 is higher relative to conventional circuits while reducing the power needed to operate the circuit.
Various features and advantages of the invention are set forth in the following claims.
This is a continuation of U.S. application Ser. No. 13/399,511, filed on Feb. 17, 2012, the contents of which are hereby incorporated by reference in its entirety.
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Number | Date | Country | |
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Parent | 13399511 | Feb 2012 | US |
Child | 15056788 | US |