This disclosure relates to scroll compressors with intermediate injection. More Specifically, this disclosure relates to providing intermediate injection into a scroll compressor in heating, ventilation, air conditioning, and refrigeration (HVACR) systems.
A scroll compressor is a type of compressor used to compress a gas. Heating, ventilation, air conditioning, and refrigeration systems (“HVACR”) may utilize compressors to compress a gaseous working fluid. One type of compressor is a scroll compressor which generally includes a pair of scroll members which orbit relative to each other to compress gas (e.g., air, refrigerant, or the like). Typically, a scroll compressor includes a first, fixed scroll member with a generally spiral wrap and a second, orbiting scroll member with a generally spiral wrap. The spiral wraps of the two scroll members are intermeshed, creating a series of compression pockets. The second, orbiting scroll member is driven by a rotating shaft to orbit the first, stationary scroll member by a rotating shaft causing gas to be compressed within the compression pockets.
In an embodiment, a scroll compressor includes a compressor housing, a plurality of chambers disposed in the compressor housing, an orbiting scroll member, and a non-orbiting scroll member, and a first band and a second band disposed within the compressor housing. The plurality of chambers includes a suction chamber, a discharge chamber, and an intermediate injection chamber. The orbiting scroll member and the non-orbiting scroll member are intermeshed to form compression pockets within the compressor housing. The compression pockets are configured to suction from the suction chamber and discharge into the discharge chamber. The non-orbiting scroll member includes an intermediate injection port that fluidly connects the intermediate injection chamber to at least one of the compression pockets. The first band and the second band each extend between the non-orbiting scroll member and the compressor housing. The intermediate injection chamber is defined by the first band and the second band.
In an embodiment, the first band forms a seal between the intermediate injection chamber and the discharge chamber, and the second band forms a seal between the intermediate injection chamber and the suction chamber.
In an embodiment, the first band and the second band each extend from the non-orbiting scroll member to the compressor housing.
In an embodiment, the compressor includes a suction inlet, an intermediate injection inlet, and a discharge outlet in the compressor housing. The suction chamber fluidly connects the suction inlet to an inlet of the compression pockets. The discharge chamber fluidly connects an outlet of the compression pockets to the discharge outlet. The intermediate injection chamber fluidly connects the intermediate injection inlet to an intermediate injection port in the non-orbiting scroll member.
In an embodiment, the intermediate injection chamber encircles the non-orbiting scroll member.
In an embodiment, the first band and the second band each encircle the non-orbiting scroll member.
In an embodiment, the intermediate injection chamber has an annular shape.
In an embodiment, the compressor housing includes an upper portion and a lower portion. The first band extends from the non-orbiting scroll member to the upper portion of the compressor housing. The intermediate injection chamber is defined by the upper portion of the compressor housing.
In an embodiment, the upper portion of the compressor housing is shrink fitted onto the non-orbiting scroll member via the first band and the second band.
In an embodiment, the first band contacts the compressor housing and the non-orbiting scroll member.
In an embodiment, a heating, ventilation, air conditioning, and refrigeration (HVACR) system includes a refrigerant circuit. The refrigerant circuit includes a condenser, an expander, an evaporator, and a scroll compressor that are fluidly connected. A working fluid flows through the refrigerant circuit. The scroll compressor includes a compressor housing, a plurality of chambers disposed in the compressor housing, an orbiting scroll member, and a non-orbiting scroll member, and a first band and a second band disposed within the compressor housing. The plurality of chambers includes a suction chamber, a discharge chamber, and an intermediate injection chamber. The orbiting scroll member and the non-orbiting scroll member are intermeshed to form compression pockets within the compressor housing. The compression pockets are configured to suction from the suction chamber and discharge into the discharge chamber. The non-orbiting scroll member includes an intermediate injection port that fluidly connects the intermediate injection chamber to at least one of the compression pockets. The first band and the second band each extend between the non-orbiting scroll member and the compressor housing. The intermediate injection chamber is defined by the first band and the second band.
In an embodiment, the first band forms a seal between the intermediate injection chamber and the discharge chamber, and the second band forms a seal between the intermediate injection chamber and the suction chamber.
In an embodiment, the first band and the second band each extend from the non-orbiting scroll member to the compressor housing.
In an embodiment, the compressor includes a suction inlet, an intermediate injection inlet, and a discharge outlet in the compressor housing. The suction chamber fluidly connects the suction inlet to an inlet of the compression pockets. The discharge chamber fluidly connects an outlet of the compression pockets to the discharge outlet. The intermediate injection chamber fluidly connects the intermediate injection inlet to an intermediate injection port in the non-orbiting scroll member.
In an embodiment, the intermediate injection chamber encircles the non-orbiting scroll member.
In an embodiment, the first band and the second band each encircle the non-orbiting scroll member.
In an embodiment, a method is directed to making a scroll compressor. The method includes placing an upper portion of a compressor housing over a non-orbiting scroll member. The upper portion of the compressor housing surrounding the non-orbiting scroll member, and a first band and a second band are each disposed between the upper portion of the compressor housing and the non-orbiting scroll member. The method also includes interference fitting the upper portion of the compressor housing onto the non-orbiting scroll member via the first band and the second band. The interference fitting forms an intermediate injection chamber that is defined by the first band, the second band, the upper portion of the compressor housing, and the non-orbiting scroll member. The intermediate injection chamber fluidly connects an intermediate injection inlet in the compressor housing to an intermediate injection port in the non-orbiting scroll member.
In an embodiment, the method also includes heating of the upper portion of the compressor housing, prior to placing the upper portion of the compressor housing over the non-orbiting scroll member. The interference fitting is a shrinking fitting that includes cooling of the upper portion of the compressor housing, which results in the upper portion of the compressor housing being shrink fit onto the non-orbiting scroll member via the first band the second band. The first band and the second band being shrink bands.
In an embodiment, the scroll compressor includes a non-orbiting scroll member intermeshed with the non-orbiting scroll member to form compression pockets. The interference fitting forms a discharge chamber that fluidly connects an outlet of the compression pockets to the discharge outlet.
In an embodiment, a scroll compressor includes a compressor housing, an orbiting scroll member and a non-orbiting scroll member intermeshed to form compression pockets within the compressor housing, and at least three bands disposed within the compressor housing. The compressor housing contains a suction chamber, a discharge chamber, and intermediate injection chambers. The compression pockets are configured to suction from the suction chamber and discharge into the discharge chamber. The non-orbiting scroll member includes intermediate injection ports that fluidly connect the intermediate injection chambers to the compression pockets. Each of the at least three bands extends between the non-orbiting scroll member and the compressor housing. The intermediate injection chambers are defined by pairs of the three or more bands.
In an embodiment, the intermediate injection chambers include a first intermediate injection chamber and a second intermediate injection chamber. The intermediate injection ports include a first intermediate injection port and a second intermediate injection port. The first intermediate injection port fluidly connects the first intermediate injection chamber to at least one of the compression pockets. The second intermediate injection port fluidly connects the second intermediate injection chamber to at least one of the compression pockets.
In an embodiment, the pairs of the three or more bands include a first pair of the bands and a second pair of the bands. The first intermediate injection chamber is defined by the first pair of bands. The second intermediate injection chamber is defined by the second pair of bands.
In an embodiment, the at least three bands include a first band. The first pair of the bands and the second pair of the bands each include the first band.
In an embodiment, the at least three bands include a second band and a third band. The first pair of the bands includes the second band. The second pair of the bands includes the third band.
In an embodiment, the scroll compressor includes in the compression housing, a suction inlet, a discharge outlet, a first intermediate injection inlet, and a second intermediate injection inlet. The suction chamber fluidly connects the suction inlet to an inlet of the compression pockets. The discharge chamber fluidly connects an outlet of the compression pockets to the discharge outlet. The first intermediate injection chamber fluidly connects the first intermediate injection inlet to the first intermediate injection port in the non-orbiting scroll member. The second intermediate injection chamber fluidly connects the second intermediate injection inlet to the second intermediate injection port in the non-orbiting scroll member.
In an embodiment, the at least three bands include a first band that forms a seal between the intermediate injection chambers and the discharge chamber a second band that forms a seal between the intermediate injection chambers and the suction chamber.
In an embodiment, the at least three bands each extends from the non-orbiting scroll member to the compressor housing.
In an embodiment, the at least three bands each contact the non-orbiting scroll member and the compressor housing.
In an embodiment, one or more of the at least three bands encircles the non-orbiting scroll member. One or more of the intermediate injection chambers encircles the non-orbiting scroll member and has an annular shape.
In an embodiment, the compressor housing includes an upper portion and a lower portion. The three or more bands include a first band that extends from the non-orbiting scroll member to the upper portion of the compressor housing. The intermediate injection chambers including a first intermediate injection chamber is defined by the first band, the upper portion of the compressor housing, and the non-orbiting scroll member.
In an embodiment, the upper portion of the compressor housing is shrink fitted onto the non-orbiting scroll member via the three or more bands.
In an embodiment, a heating, ventilation, air conditioning, and refrigeration (HVACR) system includes a refrigerant circuit. The refrigerant circuit includes a condenser, an expander, an evaporator, and a scroll compressor that are fluidly connected. A working fluid flows through the refrigerant circuit. The scroll compressor includes a compressor housing, an orbiting scroll member and a non-orbiting scroll member intermeshed to form compression pockets within the compressor housing, and at least three bands disposed within the compressor housing. The compressor housing contains a suction chamber, a discharge chamber, and intermediate injection chambers. The compression pockets are configured to suction from the suction chamber and discharge into the discharge chamber. The non-orbiting scroll member includes intermediate injection ports that fluidly connect the intermediate injection chambers to the compression pockets. Each of the at least three bands extends between the non-orbiting scroll member and the compressor housing. The intermediate injection chambers are defined by pairs of the three or more bands.
In an embodiment, the pairs of the three or more bands include a first pair of the bands and a second pair of the bands. The intermediate injection chambers include a first intermediate injection chamber defined by the first pair of bands. The intermediate injection chambers include a second intermediate injection chamber defined by the second pair of bands.
In an embodiment, the intermediate injection chambers include a first intermediate injection chamber and a second intermediate injection chamber. The intermediate injection ports include a first intermediate injection port and a second intermediate injection port. The first intermediate injection port fluidly connects the first intermediate injection chamber to at least one of the compression pockets. The second intermediate injection port fluidly connects the second intermediate injection chamber to at least one of the compression pockets.
In an embodiment, the suction chamber is configured to receive a suction flow of the working fluid. The discharge chamber is configured to receive a discharge flow of the working fluid from compression pockets. The intermediate injection chambers include a first intermediate injection chamber and a second intermediate injection chamber. The first intermediate injection chamber is configured to receive a first intermediate injection flow of the working fluid. The second intermediate injection chamber is configured to receive a second intermediate injection flow of the working fluid.
In an embodiment, the scroll compressor includes in the compression housing, a suction inlet, a discharge outlet, a first intermediate injection inlet, and a second intermediate injection inlet. The suction inlet is configured to direct the suction flow of the working fluid into the suction chamber. The suction chamber fluidly connects the suction inlet to an inlet of the compression pockets. The discharge outlet is configured to direct the discharge flow of the working fluid from the discharge chamber out of the compressor. The discharge chamber fluidly connects an outlet of the compression pockets to the discharge outlet. The first intermediate injection inlet is configured to direct the first intermediate injection flow of the working fluid into the first intermediate injection chamber. The first intermediate injection chamber fluidly connects the first intermediate injection inlet to the first intermediate injection port in the non-orbiting scroll member. The second intermediate inlet is configured to direct the second intermediate injection flow of the working fluid into the second intermediate injection chamber. The second intermediate injection chamber fluidly connects the second intermediate injection inlet to the second intermediate injection port in the non-orbiting scroll member.
In an embodiment, the intermediate injection chambers include a first intermediate injection chamber and a second intermediate injection chamber. The suction chamber is configured to receive a suction flow of the working fluid. The discharge chamber is configured to receive a discharge flow of the working fluid from compression pockets. The first intermediate injection chamber is configured to receive a first intermediate injection flow of the working fluid. The second intermediate injection chamber is configured to receive a second intermediate injection flow of the working fluid.
In an embodiment, a method is directed to making a scroll compressor. The method includes placing an upper portion of a compressor housing over a non-orbiting scroll member. The upper portion of the compressor housing surrounds the non-orbiting scroll member. At least three bands are disposed between the upper portion of the compressor housing and the non-orbiting scroll member. The method also includes interference fitting the upper portion of the compressor housing onto the non-orbiting scroll member via the at least three bands. The interference fitting forms intermediate injection chambers defined by pairs of the at least three bands, the upper portion of the compressor housing, and the non-orbiting scroll member. The intermediate injection chambers fluidly connect intermediate injection inlets in the compressor housing to intermediate injection ports in the non-orbiting scroll member.
In an embodiment, the method also includes heating of the upper portion of the compressor housing, prior to placing the upper portion of the compressor housing onto the non-orbiting scroll member. The interference fitting is a shrinking fitting that includes cooling of the upper portion of the compressor housing, which results in the upper portion of the compressor housing being shrink fit onto the non-orbiting scroll member via the at least three bands. The at least three bands are shrink bands.
In an embodiment, a scroll compressor includes a compressor housing, an orbiting scroll member, a non-orbiting scroll member, and bands disposed within the compressor housing. The compressor housing contains a suction chamber, a discharge chamber, and one or more intermediate injection chambers. The orbiting scroll member and the non-orbiting scroll member are intermeshed to form compression pockets within the compressor housing. The compression pockets are configured to suction from the suction chamber and discharge into the discharge chamber. The non-orbiting scroll member includes one or more intermediate injection ports that fluidly connect the one or more intermediate injection chambers to at least one of the compression pockets. Each of the bands extends between the non-orbiting scroll member and the compressor housing. The one or more intermediate injection chambers are defined by the bands.
Like numbers represent like features.
The refrigerant circuit 5 includes a compressor 10, a condenser 20, a first expansion device 30, a second expansion device 32, and an evaporator 50 that are fluidly connected. In an embodiment, the refrigerant circuit 5 can be modified to include additional components. For example, the refrigerant circuit 5 in an embodiment can include one or more flow control devices, a receiver tank, a dryer, a suction-liquid heat exchanger, or the like. The components of the refrigerant circuit 5 are fluidly connected. Dotted lines and dotted-dashed lines are provided in
The refrigerant circuit 5 can be configured as a cooling system (e.g., a fluid chiller of an HVACR, an air conditioning system, or the like) that can be operated in a cooling mode, and/or the refrigerant circuit 5 can be configured to operate as a heat pump system that can run in a cooling mode and a heating mode.
The refrigerant circuit 5 applies known principles of gas compression and heat transfer. The refrigerant circuit 5 can be configured to heat or cool a process fluid (e.g., water, air, chiller fluid, or the like). In an embodiment, the refrigerant circuit 5 may represent a chiller that cools a process fluid such as water or the like. In an embodiment, the refrigerant circuit 5 may represent an air conditioner and/or a heat pump that cools and/or heats a process fluid such as air, water, or the like.
During the operation of the refrigerant circuit 5, a working fluid (e.g., containing refrigerant, a refrigerant mixture, or the like) flows into the compressor 10 from the evaporator 50 in a gaseous state at a relatively lower pressure. The compressor 10 compresses the gaseous working fluid into a high pressure state, which also heats the gas. The compressor 10 includes a suction inlet 12, a discharge outlet 14, one or more intermediate injection inlets 16A, 16B, and a compression mechanism 18 configured to move within the compressor 10 to compress the gas into the high pressure state. The lower pressure gaseous working fluid flows from the evaporator 50 into the suction inlet 12 of the compressor 10 and is discharged from the discharge outlet 14 of the compressor 10 after being compressed by the compression mechanism 18. The working fluid flows from the suction inlet 12 into the compression mechanism 18 and then from the compression mechanism 18 to and out of the compressor 10 through the discharge outlet 14.
In an embodiment, the compressor 10 is a type that utilizes injection of intermediate pressure working fluid into the compression mechanism 18 (e.g., economizer injection or the like). In an embodiment, the compressor 10 is a scroll compressor and the compression mechanism 18 is a pair of intermeshed scroll members (e.g., intermediate pressure gaseous working fluid is injected into a formed intermediate compression pocket between the intermeshed scroll members). The intermediate pressure working fluid flows into the intermediate injection inlet(s) 16A, 16B of the compressor 10, and from the intermediate injection inlets 16A, 16B into the compression mechanism 18. The intermediate pressure working fluid mixes with the gaseous working fluid being compressed within the compression mechanism 18 (e.g., mixes with the gaseous working fluid already partially compressed within the compression mechanism 18), is further compressed within the compression mechanism 18, and is then discharged from the compression mechanism 18 to and out of the compressor 10 through the discharge outlet 14. After being compressed, the relatively higher pressure and higher temperature gaseous working fluid flows from the discharge outlet 14 of the compressor 10 to the condenser 20. The working fluid flows through the condenser 20. In addition to the working fluid flowing through the condenser 20, a first process fluid PF1 (e.g., external air, external water, cooling/heater water, glycol, combinations thereof, or the like) also separately flows through the condenser 20. The first process fluid PF1 absorbs heat from the working fluid as the first process fluid PF1 flows through the condenser 20, which cools the working fluid as the working fluid flows through the condenser 20. The working fluid condenses to liquid within the condenser 20. The liquid working fluid then flows from the condenser 20 to the expansion devices 30, 32.
A first portion of the relatively cooler, relatively higher pressure liquid working fluid discharged from the condenser 20 flows from the condenser 20 into the first expansion device 30. A second portion of the relatively cooler, relatively higher pressure liquid working fluid discharged from the condenser 20 flows into the second expansion device 32. As shown in
The first expansion device 30 allows the working fluid to expand, which converts the working fluid to a mixed vapor and liquid state. The expansion also causes further cooling of the working fluid. An “expansion device” as described herein may also be referred to as an expander. In an embodiment, the expander may be an expansion valve, expansion plate, expansion vessel, orifice, or the like, or other such types of expansion mechanisms. It should be appreciated that the expander may be any type of expansion device used in the field for expanding a working fluid to cause the gaseous working fluid to decrease in pressure and temperature. The first expander 30 and the second expander 32 may be the same type of expansion device or may be different types of expansion devices. In an embodiment, one or both of the expanders 30, 32 are an adjustable type of expansion device. For example, the expanders 30, 32 may each be an expansion valve. For example, one or both of the expanders 30, 32 may be adjusted to control the amount of the working fluid that will flow into the suction inlet 12 and the intermediate injection inlet 16A of the compressor.
The further relatively lower temperature, vapor/liquid working fluid then flows from the second expander 32 into the evaporator 50. A second process fluid PF2 (e.g., air, chiller liquid, water, glycol, combinations thereof, or the like) also flows through the evaporator 50. The working fluid absorbs heat from the second process fluid PF2 as it flows through the evaporator 50, which cools the second process fluid PF2 as it flows through the evaporator 50. As the working fluid absorbs heat, the working fluid evaporates to vapor. The gaseous/mostly gaseous working fluid then returns to the compressor 10 from the evaporator 50.
The second portion of the relatively cooler, relatively higher pressure liquid working fluid discharged from the condenser 20 flows to the second expander 32. The second expander 32 allows the working fluid to expand, which converts the working fluid to a vapor state. The expansion also causes further cooling of the working fluid. The relatively lower temperature, intermediate pressure gaseous working fluid then flows from the second expander 32 to the intermediate injection inlet 16A of the compressor 10.
In an embodiment, the compressor 10 may include multiple intermediate injection inlets 16A, 16B. As shown in
In an embodiment, the first intermediate injection inlet 16A can be a gaseous intermediate inlet configured to receive/inject the gaseous intermediate pressure working fluid, and the second intermediate injection inlet 16B can be liquid intermediate inlet configured to receive/inject liquid working fluid (e.g., at least partially liquid, mixed phase, at or about fully liquid, or the like). For example, as shown in
The above-described process continues while the refrigerant circuit 5 is operated, for example, in a cooling mode. In an embodiment, the HVACR system 1 may include a controller (not shown) that controls operation of the expanders 30, 32. The controller may control the expanders 30, 32 (e.g., the degree each expansion valve is open) so that the desired amount (e.g., percentage, or the like) of the working fluid discharged from the condenser flows through the first expander 30 and the second expander 32.
During the operation of the refrigerant circuit 5, the working fluid flows from the evaporator 50 into the suction inlet 12 of the compressor 10, is compressed and mixes with intermediate pressure working fluid within the compression mechanism 18, is discharged from the discharge outlet 14 of the compressor 10, and is then cooled/condensed within the condenser 20, as similarly discussed for the refrigerant circuit 5 in
The cooler, relatively higher pressure liquid working fluid discharged from the condenser 20 flows into the first expander 30′. The first expansion device 30′ causes/allows the working fluid to partially expand, which converts the working fluid to a mixed vapor and liquid state. The working fluid also cools as it expands. A first portion of the relatively lower temperature, intermediate pressure working fluid (e.g., a liquid portion or a mixed vapor and liquid portion of the relatively lower temperature intermediate pressure working fluid) flows form the first expander 30′ to the second expander 32′. A second portion of the relatively lower temperature, intermediate pressure working fluid (e.g., a gaseous portion of the relatively lower temperature intermediate pressure working fluid) flows from the first expander 30′ to the intermediate injection inlet 16A of the compressor 10.
As shown in
The first portion of intermediate pressure working fluid is further expanded by the expander 32′, which causes liquid in the first portion to become gaseous. This also causes further cooling of the working fluid. The further relatively lower temperature, vapor/liquid working fluid then flows from the second expander 32′ into the evaporator 50. As similarly discussed above for the refrigerant circuit 5 in
In an embodiment, the compressor 10 may include the multiple intermediate injection inlets 16A, 16B, as similarly discussed above. For example, as shown in
During the operation of the refrigerant circuit 5″, the working fluid flows from the evaporator 50 into the suction inlet 12 of the compressor 10, is compressed and mixes with intermediate pressure working fluid within the compression mechanism 18, is discharged from the discharge outlet 14 of the compressor 10, and is then cooled/condensed within the condenser 20, as similarly discussed for the refrigerant circuit 5 in
A first portion of the liquid working fluid discharged from the condenser 20 flows through the economizer 40″ to a first expander 30″. A second portion of the liquid working fluid discharged from the condenser 20 flows through a second expander 32″ and the economizer 40″ to the intermediate injection inlet 16A of the compressor 10. The first expansion device 30″ causes/allows the working fluid to partially expand, which converts the working fluid to a gas state or to a vapor and liquid mixed state. The relatively cooler, intermediate pressure working fluid then flows from the second expander 32″ to the economizer 40″.
In the illustrated embodiment, the economizer 40″ is a heat exchanger that allows the first portion of working fluid and the second portion of working fluid to exchange heat without physically mixing. As both portions of the working fluid flow through the economizer 40″, the relatively cooler, intermediate pressure working fluid (i.e., the second portion of the working fluid) absorbs heat from the first portion of the working fluid. In an embodiment, this may also convert liquid in the second portion into gaseous working fluid. The gaseous intermediate pressure working fluid (i.e., the second portion of the working fluid) then flows from the economizer 40″ to the intermediate injection inlet 16A of the compressor 10.
The first portion of working fluid is cooled within the economizer 40″ and then flows from the economizer 40″ to the first expander 30″. The cooled first portion of working fluid is then expanded by the expander 32″, which causes liquid in the first portion to become gaseous. This also causes further cooling of the working fluid. The further relatively lower temperature, vapor/liquid working fluid then flows from the first expander 30″ into the evaporator 50. As similarly discussed above for the refrigerant circuit 5 in
In an embodiment, the compressor 10 may include the multiple intermediate injection inlets 16A, 16B, as similarly discussed above. For example, as shown in
During the operation of the refrigerant circuit 5′″, the working fluid flows from the evaporator 50 into the suction inlet 12 of the compressor 10, is compressed and mixes with injected working fluid from the intermediate inlet 16A within the compression mechanism 18, is discharged from the discharge outlet 14 of the compressor 10, and is then cooled/condensed within the condenser 20, as similarly discussed for the refrigerant circuit 5 in
A first portion of the liquid working fluid condensed in the condenser 20 flows to the expander 30′″. The expander 30′″ causes/allows the working fluid to partially expand, which converts the working fluid to a gas state or to a vapor and liquid mixed state. The relatively lower temperature, vapor/liquid working fluid then flows from the expander 30′″ into the evaporator 50. As similarly discussed above for the refrigerant circuit 5 in
A second portion of the liquid working fluid flows from the condenser 20 to the intermediate injection inlet 16A of the compressor 10. As shown in
In
In an embodiment, the compressor 10 may include the multiple intermediate injection inlets 16A, 16B, as similarly discussed above. For example, as shown in
In some embodiments, the working fluid may include refrigerant and lubricant (e.g., oil or the like). In such embodiments, the intermediate liquid working fluid supplied to an intermediate injection inlet 16A, 16B can be liquid lubricant (e.g., includes liquid lubricant, a flow of working fluid that is a majority lubricant, or the like). For example, intermediate liquid lubricant may be supplied/injected through the first intermediate injection inlet 16A and intermediate refrigerant (e.g., gaseous refrigerant, liquid refrigerant, or mixed phase refrigerant; a flow of working fluid that is a majority refrigerant, or the like) may be supplied through the second intermediate injection inlet 16B. In an embodiment, the supplied intermediate lubricant may be at discharge pressure or at an intermediate pressure. For example, said intermediate lubricant may be supplied from a lubricant separator (not shown) in the refrigerant circuit 5 (e.g., lubricant separator disposed between the discharge outlet 14 of the compressor 14 and the condenser 20, or the like), from the evaporator 50 (e.g., from a bottom of the evaporator 50, or the like), or the like. For example, when supplied from the evaporator 50, a pump (not shown) may be used to supply the intermediate lubricant to the first intermediate injection inlet 16B (e.g., at an intermediate or higher pressure).
The compressor 100 includes a plurality of fluid ports that extend through the housing 102 for supplying working fluid into and discharging working fluid from the compressor 100. The working fluid enters and exits the compressor 100 by flowing through the fluid ports in the housing 102. The fluid ports include a suction inlet 104A, a discharge outlet 104B, and an intermediate injection inlet 104C. A suction flow fS of the working fluid to be compressed flows into the compressor 100 though the suction inlet 104A in the housing 102 at a relatively lower pressure (e.g., at a first pressure P1). A discharge flow fD of the compressed working fluid is discharged from the discharge outlet 104B of the compressor 100 at a relatively higher pressure (e.g., at a second pressure P2 greater than the first pressure P1). An intermediate flow fi of the working fluid flows into the compressor 100 through the intermediate injection inlet 104C in the housing 102. This flow fi can also be referred to as economizer injection, intermediate injection flow, or economizer injection flow. The intermediate injection working fluid in the flow fi may be a liquid working fluid at the relatively higher pressure or a working fluid at an intermediate pressure (e.g., at a third pressure P3 greater than the first pressure P1 and less than the second pressure P2). For example, the working fluid at the intermediate pressure can be a gaseous working fluid at the intermediate pressure or a mixed phase liquid and vapor working fluid at the intermediate pressure.
In one example, the intermediate injection working fluid is at the intermediate pressure. In an embodiment, the intermediate pressure working fluid is a gaseous working fluid. In an embodiment, the intermediate pressure working fluid may be a liquid working fluid or a mixed phase liquid and vapor working fluid. For example, the intermediate injection working fluid is an intermediate pressure working fluid supplied from an expander in the refrigerant circuit of the compressor 100 (e.g., from the second expander 32 in
In one example, the intermediate injection working fluid can be a liquid working fluid at the relatively higher pressure. For example, the liquid intermediate injection working fluid is a portion of the liquid working fluid provided from a condenser (e.g., directly from the condenser or as the liquid working fluid flows from the condenser to an expander) of the refrigerant circuit of the compressor 100 (e.g., from the condenser 20 in
The illustrated compressor 100 is a single-stage scroll compressor. More specifically, the illustrated compressor 100 is a single-stage vertical scroll compressor. It is to be appreciated that the principles described herein are not limited to single-stage scroll compressors and can be applied to multi-stage scroll compressors having two or more compression stages. The embodiments are described herein for a compressor with a vertical or a near vertical crankshaft (e.g., as shown in
The scroll compressor 100 includes a non-orbiting scroll member 112 and an orbiting scroll member 114. Applying known aspects of scroll compressor compression, the scroll compressor 100 utilizes the intermeshing of the two scroll members 112, 114 to form a plurality of compression pockets 116 in which gas is trapped and then compressed. The non-orbiting scroll 112 has a baseplate 113 and a spiral wrap 118 that projects from the baseplate 113 in a direction towards the orbiting scroll member 114. The orbiting scroll member 114 has a baseplate 115 and a spiral wrap 120 that projects from the baseplate 115 in a direction towards the non-orbiting scroll member 112. The spiral wrap 118 of the non-orbiting scroll 112 is intermeshed with the spiral wrap 120 of the orbiting scroll member 114 forming the compression pockets 116 there between. In an embodiment, the axial end of one or both of the spiral wraps 118, 120 may include a tip seal (not shown) to help encourage sealing between each spiral wraps 118, 120 and the opposing baseplate 113, 115.
The non-orbiting scroll member 112 is a scroll member that is in a fixed position within the compressor housing 102 and is not configured to be moved (e.g., orbited, rotated) relative to the compressor housing 102 during the operation of the scroll compressor 100. The non-orbiting scroll member 112 may be referred to as a non-orbiting scroll, a fixed scroll, a stationary scroll, a first scroll member, or the like. In an embodiment, the non-orbiting scroll 112 can be directly attached to the compressor housing 102 of the scroll compressor 100. For example, in the illustrated embodiment, the non-orbiting scroll 112 is interference fit into the compressor housing 102. This fit between the non-orbiting scroll 112 and the housing 102 is discussed in more detail below.
The orbiting scroll member 114 is a scroll member engaged with an end of a crankshaft 160. During operation of the scroll compressor 100, the orbiting scroll member 114 is moved (e.g., orbited, rotated) relative to the non-orbiting scroll member 112. The orbiting scroll member 114 is configured to be moved relative to the compressor housing 102 during operation of the compressor 100. The orbiting scroll member 114 may also be referred to as an orbiting scroll, a moving scroll, a second scroll member, or the like.
The orbiting scroll 114 is moved (e.g., orbited, rotated) by the crankshaft 160. As the orbiting scroll member 114 is engaged with the end of the crankshaft 160, rotation of the crankshaft 160 causes the moving of the orbiting scroll 114. The crankshaft 160 can be rotated by, for example, an electric motor 162. The electric motor 162 includes a rotor and a stator. The rotor and the crankshaft 160 are affixed together such that they rotate together (e.g., the rotor and the crankshaft 160 can be affixed together using an interference fit or other type of fit). The electric motor 162 may operate using known principles to rotate the crankshaft 160. In an embodiment, the crankshaft 160 may be rotated by other mechanisms other than the electric motor 162, such as, for example, an external electric motor, an external combustion engine, or other such mechanisms. Accordingly, such embodiments may not include the electric motor 162 as shown in
The compressor 100 includes a bearing support 134. The bearing support 134 can be affixed to the housing 102 and/or the non-orbiting scroll 112. The orbiting scroll 114 is disposed between the non-orbiting scroll 112 and the bearing support 134. The bearing support 134 can provide bearing(s)/bearing surface(s) for supporting the orbiting scroll 114 (e.g., a thrust bearing for axially supporting the orbiting scroll 114, or the like) and/or for supporting the crankshaft 160 (e.g., radial bearings for radially supporting the crankshaft 160, or the like).
The compressor housing 102 of the scroll compressor 100 includes an upper portion 108A and a lower portion 108B. As shown in
The compressor housing 102 contains an internal volume that includes a suction chamber 140, a discharge chamber 142, and an intermediate injection chamber 144 of the compressor 100. The discharge chamber 142, the suction chamber 140, and the intermediate injection chamber 144 are at different pressures. For example, the suction chamber 140 is at the suction pressure (e.g., the first pressure P1), the discharge chamber 142 is at the discharge pressure (e.g., the second pressure P2), and the intermediate injection chamber 144 is at the discharge pressure or the intermediate pressure (e.g., the third pressure P3). In an embodiment, the intermediate injection chamber 144 is at the intermediate pressure. The intermediate injection chamber 144 is discussed in more detail below with respect to
The discharge chamber 142 is disposed between the compressor housing 102 and the non-orbiting scroll member 112 (e.g., between the upper portion 108A of the compressor housing 102 and the non-orbiting scroll member 112). As shown in
The suction chamber 140 is disposed between the compressor housing 102 and the non-orbiting scroll member 112 (e.g., between the lower portion 108B of the compressor housing 102 and the non-orbiting scroll member 112). The suction chamber 140 is disposed opposite to the discharge chamber 142 with respect to the non-orbiting scroll 112. For example, the suction chamber 140 and the discharge chamber 142 are disposed on opposite sides of the non-orbiting scroll 112. As shown in the illustrated embodiment, the discharge chamber 142 and the suction chamber 140 are fluidly separated by the non-orbiting scroll 112. As shown in
As shown in
The intermeshed spiral wraps 118, 120 also have outlet 122. The outlet 122 is a port that allows the compressed gas to flow out from between the intermeshed spiral wraps 118, 120. As shown in the illustrated embodiment, the outlet 122 is formed in the baseplate 113 of the non-orbiting scroll. For example, the outlet 122 is located at or near the axial center of the intermeshed spiral wraps 118, 120 (e.g., at or near where the intermeshed spiral wraps 118, 120 end). The outlet 122 is fluidly connected to the discharge chamber 142 of the scroll compressor 100. The compressor 100 may include a valve (e.g., a check valve, a valve plate, or the like) (not shown) to regulate the flow of pressurized gas through the outlet 122.
The compressor 100 includes one or more intermediate injection ports 150 formed in the non-orbiting scroll 112 for injecting intermediate working fluid into the intermeshed scrolls 112, 114. The intermediate injection port(s) 150 fluidly connects the intermediate injection chamber 144 to one or more of the intermediate compression pockets 117 of the intermeshed scrolls 112, 114. The intermediate injection port(s) 150 are configured to inject/direct the intermediate working fluid (i.e., in flow fi) into the intermeshed scrolls 112, 114. An intermediate compression pocket 117 is one of the compression pockets 116 that is partially through the compression process (e.g., at a pressure between the inlet pressure P1 and the discharge pressure P2, has travelled part way and is disposed at an intermediate position between the inlet 124 and the outlet 122). The gaseous and/or liquid intermediate injection working fluid is added to the working fluid already within the intermediate compression pocket 117, which is then further compressed (e.g., to the discharge pressure P2). When the injection working fluid contains liquid working fluid, the liquid working can undergo a pressure drop as its injected into the intermediate compression pocket 117 (e.g., as it flows to the intermediate compression pocket 117, within the intermediate compression pocket 117 that is at relatively lower pressure). The pressure drop can cause evaporation of the working fluid, which provides cooling.
The specific location(s) of the intermediate inlet port(s) 150 with respect to the compression process can be varied. In an embodiment, a location of an intermediate injection port 150 can be located so that the pressure of the intermediate compression pocket 117 is relatively near the suction pressure (e.g., at a location in which compression is just beginning). In the illustrated embodiment, this is a location at a relatively outer extent of the intermeshed scrolls 112, 114 (e.g., relatively closer to the inlet 124, closer to the inlet 124 than the outlet 122). In an embodiment, a location of the intermediate injection port 150 can be selected so that the pressure in the intermediate compression pocket 117 is relatively near the discharge pressure (e.g., at a location near the discharge). In the illustrated embodiment, this is a location at a relatively inner extent of the intermeshed scrolls 112, 114 (e.g., relatively closer to the outlet 122, closer to the outlet 122 than the inlet 124).
For example, the selection of the location(s) of the intermediate inlet port(s) 150 may be selected based on balanced between providing cooling to the compressor 100, increasing capacity of the HVACR system of the compressor 100, and/or maintaining efficiency of the HVACR system of the compressor 100. Such location(s) may be selected based on, for example, modeling the anticipated efficiency and capacity changes, testing to determine the optimal location, or combinations thereof.
The working fluid is compressed by the intermeshed scrolls 112, 114 as the working fluid travels between the intermeshed scrolls 112, 114. The compressed working fluid flows out of the scroll compressor 100 by flowing from the outlet 122 of the intermeshed scrolls 112, 114 to and through the discharge outlet 104B. The working fluid enters the intermeshed scrolls 112, 114 at the relatively lower pressure (e.g., at suction pressure, at the first pressure P1), and is discharged from intermeshed scrolls 112, 114 at a relative higher pressure (e.g., at discharge pressure, at the second pressure P2). The intermediate working fluid at the relatively higher pressure or at the intermediate pressure (e.g., at a pressure between the suction pressure and the discharge pressure, at the third pressure P3) also flows into the intermeshed scrolls 112, 114.
The suction inlet 104A is fluidly connected to the inlet 124 of the intermeshed scrolls 112, 114. The suction flow fS of the working fluid flows from the suction inlet 104A into the inlet 124 of the intermeshed scrolls 112, 114. As shown in
The discharge outlet 104B is fluidly connected to the outlet 122 of the intermeshed scrolls 112, 114. The discharge flow fD of the compressed working fluid flows from outlet 122 of the intermeshed scrolls 112, 114 to and through the discharge outlet 104B of the compressor 100. As shown in
As shown in
As shown in
Each of the bands 180, 182 extends around a circumference of the non-orbiting scroll 112 (e.g., as shown in
The intermediate injection chamber 144 is disposed between the compressor housing 102 and the non-orbiting scroll member 112 (e.g., between the upper portion 108A of the compressor housing 102 and the non-orbiting scroll member 112). The intermediate injection chamber 144 is also disposed between the bands 180, 182. The intermediate injection chamber 144 is a volume defined by the compressor housing 102, the non-orbiting scroll member 112, the first band 180 and the second band 182 (e.g., defined by the upper portion 108A of the compressor housing 102, the non-orbiting scroll member 112, the first band 180, and the second band 182). The intermediate injection chamber 144 connects to the intermediate injection port 150 that extends through the non-orbiting scroll member 122 (e.g., intermediate injection port 150 being a passageway/port that extends all the way through the non-orbiting scroll).
The first band 180 forms a seal between the intermediate injection chamber 144 and the suction chamber 140. For example, the first band 180 prevents the working fluid from flowing between the intermediate injection chamber 144 and the suction chamber 140 (e.g., prevents working fluid from flowing directly between the intermediate injection chamber 144 and the suction, prevents the working fluid from flowing directly from the suction chamber 140 into the intermediate injection chamber 140). The first band 180 defines the suction chamber 140.
The second band 182 forms a seal between the intermediate injection chamber 144 and the discharge chamber 142. For example, the second band 182 prevents the working fluid from flowing between the intermediate injection chamber 144 and the discharge chamber 142 (e.g., prevents working fluid from flowing directly between the intermediate injection chamber 144 and discharge chamber 142, prevents the working fluid from flowing directly from the discharge chamber 142 into the intermediate injection chamber 144). The second band 182 defines the discharge chamber 142.
The upper portion 108A of the compressor housing 102 is interference fit onto the non-orbiting scroll 112 via the bands 180, 182. For example, interference fit refers to fit between features/components in which the friction between the components prevents movement of the features/components relative to each other. In an embodiment, the interference fit of the upper portion 108A onto the non-orbiting scroll 112 is a shrink fit (e.g., formed by shrink fitting). Shrink fitting is an example of one manner of forming the interference fit. The interference/friction fit is formed by shrink fitting the upper portion 108A of the compressor housing 102 onto the non-orbiting scroll 112 via the bands 180, 182. In such an embodiment, the bands 180, 182 are shrink bands. For example, the upper portion 108A is heated to fit onto/around the non-orbiting scroll 112 (e.g., the heated upper portion 108A is placed over/onto/around the non-orbiting scroll 112), and then is cooled (e.g., air cooled, cooled using cooled air/gas, or the like) causing shrinking of the upper portion 108A and onto the shrink bands 180, 182. The shrinking/cooling of the upper portion 108A causing an interference fit between the upper portion 108A of the compressor housing 102 and the non-orbiting scroll 112 via the shrink bands 180, 182. Shrink fitting can advantageously form the interference fit without generating debris (e.g., scraping of surfaces against each other generates debris) that can damage the compressor. Shrink fitting can also advantageously ensure a seal is formed at each of the bands 180, 182 between the upper portion 108A of the compressor housing 102 and the non-orbiting scroll 112.
In an embodiment, the interference fit of the upper portion 108A is a press fit onto the upper portion 108A onto the non-orbiting scroll 112. For example, press fitting may include the upper portion 108A being molded/deformed (e.g., radially inward) onto the non-orbiting scroll 112. The compressor 100 may also include fasteners (e.g., bolts, screws, or the like) (not shown) that help maintain the position of the upper portion 108A of compressor housing 102 (e.g., prevent axial movement, prevent upwards) on the non-orbiting scroll member 112.
As shown in
As shown in
The bands 180, 182 may each be included in the non-orbiting scroll 112, in the housing 102, or as a separate component. In the illustrated embodiment, the bands 180, 182 are portions of the non-orbiting scroll 112. For example, the bands 180, 182 are provided as extensions from the baseplate 113 of the non-orbiting scroll 112 (e.g., extend from the baseplate 113 of the non-orbiting scroll 112, the baseplate 113 of the non-orbiting scroll 112 is formed to include the bands 180, 182). The bands 180, 182 may be provided on/extend from an outer circumferential surface 126 of the non-orbiting scroll 112 (e.g., an outer circumferential surface 126 of the baseplate 113 of the non-orbiting scroll 112).
The bands 180, 182 can be made of any suitable material (e.g., able to be pressed to form the interference fit, able to withstand the temperatures used in shrink fitting, able to withstand the pressure and/or temperatures that occur during operation of the compressor, and the like). For example, a band 180, 182 may be a metal ring (e.g., a copper ring, or the like) that is fit onto the outer circumference of the non-orbiting scroll 112 (e.g., onto the outer circumference of the baseplate 113 of the non-orbiting scroll 112). For example, a band 180, 182 may be a metal ring that is fit on the inner surface/circumference of the upper portion 108A of the compressor housing 102. For example, a band may be a crush ring (e.g., metal crush ring) that is provided between the upper portion 108A of the compressor housing 102 and the non-orbiting scroll 112 and is crush fit into place. For example, a band may be made of a polymer material (e.g., modified polymer) that is capable of withstanding the fitting conditions/temperatures.
In an embodiment, one or both of the bands 180, 182 may be provided on an inner surface 110 of the housing 102 (see
The compressor 200 can have similar features as described for scroll compressor 100 in
In an embodiment, the scroll compressor 200 may be the compressor 10 in the refrigerant circuit 1
Referring to
The compressor housing 202 of the scroll compressor 200 includes upper portion 208A and lower portion 208B. As shown in
The compressor housing 202 contains an internal volume that includes the suction chamber 240, the discharge chamber 242, a plurality of intermediate injection chambers (e.g., a first intermediate injection chamber 244A, a second intermediate injection chamber 244B) of the compressor 200. The discharge chamber 242, the suction chamber 240, and the intermediate injection chambers 244A, 244B are at different pressures. For example, the suction chamber 240 is at a suction pressure (e.g., the first pressure P1*), the discharge chamber 242 is at the discharge pressure (e.g., the second pressure P2*), the first intermediate injection chamber 244A is at the discharge pressure or an intermediate pressure (e.g., the third pressure P3*), and the second intermediate injection chamber 244B is at the discharge pressure or an intermediate pressure (e.g., the fourth pressure P4*).
In an embodiment, the intermediate injection chambers 244A, 244B may be at different pressures (e.g., pressure P3* is different from pressure P4*). In an embodiment, the intermediate injection chambers 244A, 244B may each be at the same pressure (e.g., third pressure P3*=fourth pressure P4*) For example, the working fluid in the first intermediate injection chamber 244A and working fluid in the second intermediate injection chamber 244B can be at the same pressure while being at different temperatures, contain different phases (e.g., be gaseous, be liquid, be in a mixed gas/liquid phase) and/or having different compositions (e.g., being lubricant rich, being refrigerant rich, or the like). The intermediate injection chambers 244A, 244B are discussed in more detail below with respect to
The discharge chamber 242 is disposed between the compressor housing 202 and the non-orbiting scroll member 212 (e.g., between the upper portion 208A of the compressor housing 202 and the non-orbiting scroll member 212). As shown in
The suction chamber 240 is disposed between the compressor housing 202 and the non-orbiting scroll member 212 (e.g., between the lower portion 208B of the compressor housing 202 and the non-orbiting scroll member 212). The suction chamber 240 is disposed opposite to the discharge chamber 242 with respect to the non-orbiting scroll 212. For example, the suction chamber 240 and the discharge chamber 242 can be disposed on opposite sides of the non-orbiting scroll 212. As shown in the illustrated embodiment, the discharge chamber 242 and the suction chamber 240 are fluidly separated by the non-orbiting scroll 212. As shown in
As shown in
The compressor 200 includes intermediate injection ports 250A, 250B formed in the non-orbiting scroll 212 for injecting intermediate working fluid into the intermeshed scrolls 212, 214. The intermediate injection ports 250A, 250B fluidly connect the intermediate injection chambers 244A, 244B to one or more intermediate compression pockets 217 of the intermeshed scrolls 212, 214. Each of the intermediate injection ports 250A, 250B is a separate passageway extending through the non-orbiting scroll member 212 (e.g., separate passageways extending through the baseplate 213 of the non-orbiting scroll member 212). The intermediate injection ports 250A, 250B are configured to receive/supply flows of intermediate working fluid (i.e., in flow fi*-1 and in flow fi*-2) into the intermeshed scrolls 212, 214. The intermediate injection inlets 204C, 204D may be configured to supply stream(s) of liquid intermediate working fluid, stream(s) of gaseous intermediate working fluid, or a combination thereof.
The intermediate working fluid supplied via the intermediate injection inlets 204C, 204D may be stream(s) of intermediate refrigerant (e.g., intermediate working fluid containing a majority of refrigerant), stream(s) of intermediate lubricant (e.g., intermediate working fluid containing a majority of lubricant), or a combination thereof. The intermediate injection inlets 204C, 204D may be configured to supply intermediate lubricant (e.g., lubricant rich working fluid, working fluid that contains a majority of liquid lubricant, working fluid that is mostly or entirely liquid lubricant), to supply intermediate refrigerant (e.g., intermediate working fluid containing a majority of refrigerant), or to supply both a stream of intermediate lubricant and a stream of intermediate refrigerant. In an embodiment, intermediate refrigerant supplied by one or more of the intermediate injection inlets 204C, 204D may be in a gaseous state (e.g., mostly or entirely gaseous), liquid state (e.g., mostly or entirely liquid), or in a mixed state.
In an embodiment, the first intermediate injection inlet 204C can be a gaseous intermediate inlet configured to receive/supply gaseous intermediate working fluid (e.g., the working fluid/refrigerant in the flow fi*-1 is mostly gaseous, the working fluid/refrigerant in the flow fi*-1 is at or about entirely gaseous), and the second intermediate injection inlet 204D can be a liquid intermediate inlet configured to receive/supply liquid intermediate working fluid (e.g., the working fluid/refrigerant in the flow fi*-2 is in a mixed state, the working fluid/refrigerant in the flow fi*-2 is mostly liquid, the working fluid/refrigerant in the flow fi*-2 is at or about entirely liquid).
In an embodiment, one of the intermediate injection inlets 204D, 204C may be a liquid intermediate inlet configured to receive/supply lubricant (e.g., the working fluid in the flow fi*-2 contains liquid lubricant, a majority of the working fluid in the flow fi*-2 is lubricant). For example, injected lubricant may help provide sealing between tips of the wraps 218, 220 of the scrolls 212, 214 and/or provide cooling. In an embodiment, a first intermediate injection inlet 204C can be configured to receive/supply intermediate refrigerant and the second intermediate injection inlet 204D can be configured to receive/supply intermediate lubricant (e.g., lubricant at a pressure above suction pressure, lubricant at the discharge pressure).
An intermediate compression pocket 217 is one of the compression pockets 216 that is partially through the compression process (e.g., at a pressure between the inlet pressure P1* and the discharge pressure P2*, has travelled part way and is disposed at an intermediate position between the inlet 224 and the outlet 222). The gaseous and/or liquid intermediate working fluid is added to the working fluid already within the intermediate compression pocket 217, which is then further compressed (e.g., to the discharge pressure P2*). When the injected working fluid contains liquid working fluid, the liquid working can undergo a pressure drop while flowing into the intermediate compression pocket 217 (e.g., as it flows to the intermediate compression pocket 217, within the intermediate compression pocket 217 that is at relatively lower pressure). The pressure drop can cause evaporation of the working fluid, which provides cooling. The location of each of the outlets of the intermediate inlet ports 250A, 250B with respect to the compression process may vary, as similarly discussed herein with respect to the intermediate inlet port(s) 150 in the compressor 100 of
The working fluid is compressed by the intermeshed scrolls 212, 214 as the working fluid travels between the intermeshed scrolls 212, 214. The compressed working fluid flows out of the scroll compressor 200 by flowing from the outlet 222 of the intermeshed scrolls 212, 214 to and through the discharge outlet 204B. The working fluid enters the intermeshed scrolls 212, 214 at the relatively lower pressure (e.g., at suction pressure, at the first pressure P1*), and is discharged from intermeshed scrolls 212, 214 at a relative higher pressure (e.g., at discharge pressure, at the second pressure P2*). The intermediate working fluid is at the relatively higher pressure(s) or at the intermediate pressure(s) (e.g., at pressure(s) between the suction pressure and the discharge pressure, at or about the discharge pressure, at the third pressure P3*, at the fourth pressure P4*) also flows into the intermeshed scrolls 212, 214.
The suction inlet 204A is fluidly connected to the inlet 224 of the intermeshed scrolls 212, 214 (e.g., the suction chamber 240 fluidly connects the suction inlet 204A to the inlet 224 of the intermeshed scrolls 212, 214). The suction flow fS* of the working fluid flows from the suction inlet 204A into the inlet 224 of the intermeshed scrolls 212, 214 (e.g., through the suction chamber 240, the intermeshed scrolls 212, 214 suctioning working fluid from the suction chamber 240). In the illustrated embodiment, suction chamber 240 is at the suction/inlet pressure of the suction flow fS* (e.g., the working fluid within the is at the suction/inlet pressure of the suction flow fS*).
The discharge outlet 204B is fluidly connected to the outlet 222 of the intermeshed scrolls 212, 214 (e.g., the discharge chamber 242 fluidly connects the outlet 222 of the intermeshed scrolls 212, 214 to the discharge outlet 204B). The discharge flow fD* of the compressed working fluid flows from outlet 222 of the intermeshed scrolls 212, 214 to and through the discharge outlet 204B of the compressor 200 (e.g., through the discharge volume 242). The discharge chamber 242 is at the discharge pressure (e.g., the working fluid within the discharge chamber 242 is at the discharge pressure of the discharge flow fD*).
As shown in
The first intermediate injection inlet 204C fluidly connects to the first intermediate injection chamber 244A. A first injection flow fi*-1 (of intermediate working fluid) is directed from the first intermediate injection inlet 204C to and through the first intermediate injection port 250A into an intermediate compression pocket 217. The intermediate working fluid in first injection flow fi*-1 may be referred to as first intermediate working fluid.
As shown in
The second intermediate injection inlet 204D fluidly connects to the second intermediate injection chamber 244B. A second intermediate injection flow fi*-2 (of intermediate working fluid) is directed from the second intermediate injection inlet 204D to and through the second intermediate injection port 250B into an intermediate compression pocket 217. The intermediate working fluid in the second intermediate injection flow fi*-2 may be referred to as second intermediate working fluid. It should be appreciated that “first” intermediate working fluid and “second” intermediate working fluid does not refer to different types of working fluid (e.g., can refer to the same working fluid in the refrigerant circuit, having different properties, as discussed above).
As shown in
The first intermediate injection port 250A extends through the non-orbiting scroll member 212 to a location at which one or more intermediate compression pocket(s) 217 are formed. The first intermediate injection port 250A is a passageway that extends all the way through the non-orbiting scroll 212. The second intermediate injection port 250A extends through the non-orbiting scroll member 212 to a location at which intermediate compression pocket(s) 217 are formed. The second intermediate injection port 250B is a passageway that extends all the way through the non-orbiting scroll 212. The first and second intermediate injection ports 250A, 250B are different (i.e., fluidly separate) passageways in the non-orbiting scroll 212.
The first intermediate injection port 250A and the second intermediate injection port 250B may be configured to inject into different intermediate pockets 217 (e.g., do not simultaneously inject into the same intermediate pocket 217). In an embodiment, the first intermediate injection port 250A may be configured to inject into the same intermediate pocket 217 at different times. For example, the first intermediate injection port 250A injects into an intermediate pocket 217, and later in the compression cycle (e.g., after the intermediate pocket 217 is moved closer to the discharge 222), the second intermediate injection port 250B injects into the same intermediate pocket 217.
As shown in
Each of the bands 280, 282, 284 can have a similar location/configuration as discussed for the bands 180, 182 of the compressor 100 in
The first intermediate injection chamber 244A is formed by the gap between a first pair of the bands 280, 282. In the illustrated embodiment, the first intermediate injection chamber 244A is formed by the gap between the first band 280 and the second band 282. Said gap is also between the compressor housing 202 and the non-orbiting scroll 212 (e.g., the first intermediate injection chamber 244A is formed between the first and second bands 280, 282 and between the compressor housing 202 and the non-orbiting scroll 212). The first intermediate injection chamber 244A is a volume defined by the compressor housing 202, the non-orbiting scroll member 212, and the first pair of bands 280, 282 (e.g., the first band 280 and the second band 282). The first intermediate injection chamber 244A is defined by the first pair of bands 280, 282 (e.g., the first band 280 and the second band 282), the compressor housing 202 (e.g., the upper portion 208A of the compressor housing 202), and the non-orbiting scroll 212.
The second intermediate injection chamber 244B is formed by the gap between a second pair of the bands 282, 284 (i.e., different from the first pair of bands 280, 282). In the illustrated embodiment, the second intermediate injection chamber 244B is formed by the gap between the second band 282 and the third band 284. Said gap is also between the compressor housing 202 and the non-orbiting scroll 212 (e.g., the second intermediate injection chamber 244B is formed between the second and second third 282, 284 and between the compressor housing 202 and the non-orbiting scroll 212). The second intermediate injection chamber 244B is a volume defined by the compressor housing 202, the non-orbiting scroll member 212, and the second pair of bands 282, 284 (e.g., the second band 282 and the third band 284). The second intermediate injection chamber 244B is defined by the second pair of bands 282, 284 (e.g., the second band 282 and the third band 284), the compressor housing 202 (e.g., the upper portion 208A of the compressor housing 202), and the non-orbiting scroll 212.
The first intermediate injection chamber 244A connects to the first intermediate injection port 250A that extends through the non-orbiting scroll member 212 (e.g., the first intermediate injection port 250A extends from the first intermediate injection chamber 244A). The second intermediate injection chamber 244B connects to the second intermediate injection port 250B that extends through the non-orbiting scroll member 212 (e.g., second intermediate injection port 250B extends from the second intermediate injection chamber 244B).
The bands 280, 282, 284 can each form a seal between a respective pair of the suction chamber 240, the discharge chamber 242, the first intermediate injection chamber 244A, and the second intermediate injection chamber 244B. The first band 280 can form a seal between the first intermediate injection chamber 244A and the suction chamber 240. For example, the first band 280 prevents working fluid from flowing between the intermediate injection chamber 244 and the suction chamber 240 (e.g., prevents working fluid from flowing directly between the first intermediate injection chamber 244A and the suction chamber 240, and prevents working fluid from flowing directly from the first intermediate injection chamber 244A into the suction chamber 240). In the illustrated embodiment, the first band 280 also in part defines the suction chamber 240.
The second band 282 can form a seal between the first intermediate injection chamber 244A and the second intermediate chamber 244B. For example, the second band 282 prevents working fluid from flowing between the first and second intermediate injection chambers 244A, 244B (e.g., prevents working fluid from flowing directly between the first and second intermediate injection chambers 244A, 244B, prevents working fluid from flowing directly from the first intermediate injection chamber 244A into the second intermediate injection chambers 244B, and prevents working fluid from flowing directly from the second intermediate injection chamber 244B into the first intermediate injection chamber 244A). The second band 282 partially defines at least one of the first intermediate chamber 244A, 244B. In the illustrated embodiment, the second band 282 partially defines both the first intermediate chamber 244A and the second intermediate chamber 244B.
The third band 284 can form a seal between the second intermediate injection chamber 244B and the discharge chamber 242. For example, the third band 284 prevents the working fluid from flowing between the second intermediate injection chamber 244B and the discharge chamber 242 (e.g., prevents working fluid from flowing directly between the second intermediate injection chamber 244B and discharge chamber 242, and prevents the working fluid from flowing directly from the discharge chamber 242 into the second intermediate injection chamber 244B). In the illustrated embodiment, the third band 284 also defines the discharge chamber 242.
In the illustrated embodiment, the three bands 280, 282, 284 are used to form the two intermediate injection chambers 244A, 244B. It should be appreciated that in other embodiments a different number of bands 280, 282, 284 may be used to form a different number of intermediate injection chambers 244A, 244B. For example, compressor 200 in other embodiments may have four or more of the bands 280, 282, 284 that form two or more intermediate injection chambers 244A, 244B. In an embodiment, four bands may be used to form the two intermediate injection chambers (e.g., a first intermediate injection chamber formed by a first band and a second band, a second intermediate injection chamber formed by a third band and a fourth band, where none of the bands defining both intermediate injection chambers). In such an embodiment, an open or unused volume/chamber may be formed between the two intermediate injection chambers (e.g., by the gap between the second and third bands). It should also be appreciated that in some embodiments, one or more additional bands may be provided between the intermediate injection chambers 244A, 244B, between the intermediate injection chambers 244A, 244B and the suction chamber 240, and/or between the intermediate injection chambers 244A, 244B and the discharge chamber 242. For example, the additional band(s) may provide additional sealing between the chambers 240, 242, 244A, 244B.
The upper portion 208A of the compressor housing 202 is interference fit onto the non-orbiting scroll 212 via the bands 280, 282, 248. This interference fit of the upper portion 208A of the compressor housing 202 in the compressor 200 can be similar to the interference fit as discussed for the upper portion 108A of the compressor housing 102 in the compressor 100 in
Each intermediate injection chamber 244A, 244B in the compressor 200 may have a similar shape/configuration as discussed for the intermediate injection chamber 144 in the compressor 100 of
In the illustrated embodiment, each of the intermediate injection inlets 204C, 204D is radially aligned with its respective intermediate injection port 250A, 250B (e.g., first intermediate injection inlet 204C aligned with first intermediate injection port 250A, second intermediate injection inlet 204D aligned with second intermediate injection port 250B). In an embodiment, an intermediate injection inlet 204D, 204D may be radially offset from the intermediate injection port 250A, 250B to which it is fluidly connected.
In an embodiment, one or more of the intermediate injection chambers 244A, 244B may supply working fluid to a plurality of intermediate injection ports. For example, the non-orbiting scroll 212 may include multiple intermediate injection ports 250A fluidly connected to the first intermediate injection chamber 244A (e.g., a plurality of the first intermediate injection ports 250A fluidly connected to/extending from the first intermediate injection chamber 244A) and/or multiple intermediate injection ports 250B fluidly connected to the second intermediate injection chamber 244B (e.g., a plurality of the second intermediate injection ports 250B fluidly connected to/extending from the second intermediate injection chamber 144B). The first intermediate injection chamber 244A can fluidly connect the first injection inlet 204C to multiple (first) intermediate injection ports 250A and/or the second intermediate injection chamber 244B can fluidly connect the second injection inlet 204D to multiple (second) intermediate injection ports 250B.
The bands 280, 282, 284 in the compressor 200 may each have a similar shape/configuration as discussed for the bands 180, 182 in the compressor 100 of
The bands 280, 282, 284 may be included in the non-orbiting scroll 212, in the housing 202, and/or as a separate component, as similarly discussed for the bands 180, 182 of the compressor 100 in
As shown in
At 1010, an upper portion (e.g., upper portion 108A, upper portion 208A) of a compressor housing (e.g., compressor housing 102, compressor housing 202) is heated. The upper portion is heated at 1010 to a temperature above ambient temperature (e.g., above 70° F.). The heating 1010 causes the upper portion to expand. In particular, the heating 1010 causes an inner diameter of the upper portion to increase. The increased inner diameter of the upper portion is at least equal to a diameter of a non-orbiting scroll (e.g., non-orbiting scroll 112, non-orbiting scroll 212) and bands (e.g., bands 180, 182, bands 280, 282, 284) of the compressor. In an embodiment, the increased inner diameter of the upper portion is greater than the diameter of the non-orbiting scroll and the bands. The method 1000 then proceeds to 1020.
At 1020, the upper portion of the compressor housing is placed over the non-orbiting scroll, with the bands each being disposed between the upper portion of the compressor housing and the non-orbiting scroll. The upper portion of the compressor housing is placed over the non-orbiting scroll such that the upper portion of the compressor housing surrounds the non-orbiting scroll. For example, the non-orbiting scroll and the bands being disposed within the upper portion of the compressor housing. The method 1000 then proceeds to 1030.
At 1030, the upper portion of the compressor housing is interference fit onto the non-orbiting scroll member via the bands. The interference fitting at 1030 forms one or more intermediate injection chambers (e.g., intermediate injection chamber 144, first intermediate chamber 244A, second intermediate chamber 244B) within the compressor housing. The bands define the intermediate injection chamber(s). The interference fitting at 1030 can also form a discharge chamber (e.g., discharge chamber 142, discharge chamber 242) within the compressor housing. In an embodiment, the interference fitting also forms a suction chamber (e.g., suction chamber 140, suction chamber 240) within the compressor housing. For example, the bands also define the discharge chamber and/or the suction chamber within the compressor.
In an embodiment, the interference fitting at 1030 is shrink fitting 1032 of the upper portion of the compressor housing onto the non-orbiting scroll member 1032. In such an embodiment, the method 1000 can start at 1010. At 1032, the upper portion of the compressor housing is cooled to shrink fit the upper portion onto the non-orbiting scroll member 1032. The upper portion is cooled while containing the non-orbiting scroll and bands (e.g., while placed around/surrounding the non-orbiting scroll and bands). The cooling at 1030 results in the shrink fitting of the upper portion of the compressor housing onto the non-orbiting scroll via the bands. For example, the cooling of the relatively hot/heated upper portion at 1030 causes the upper portion to shrink, and said shrinking fits/affixes the upper portion onto non-orbiting scroll via the bands. Said shrinking results in an interference fit between the upper portion of the compressor housing and the non-orbiting scroll via each of the shrink bands.
In an embodiment, the interference fitting at 1030 is press fitting 1034 of the upper portion of the compressor housing onto the non-orbiting scroll member 1032. In such an embodiment, the method 1000 can start at 1020. At 1034, the upper portion of the compressor housing is pressed onto the upper portion onto the non-orbiting scroll member. For example, the upper portion of the compressor housing is molded/deformed onto the bands and the non-orbiting scroll member. For example, fasteners (e.g., bolts, screws, or the like) may be used to help with maintaining the upper portion of compressor housing affixed in place on the non-orbiting scroll member.
It should be appreciated that the method 1000 in an embodiment may be modified to include features as shown and/or as described above for the compressor 100 in
Any of Aspects 1-10 may be combined with any of Aspects 11-43, any of Aspects 11-16 maybe combined with any of Aspects 17-43, any of Aspects 20-31 may be combined with any of Aspects 32-43, any of Aspects 32-38 may be combined with any of Aspects 39-42, and any of Aspects 39-40 may be combined with any of Aspects 40-42.
The terminology used herein is intended to describe particular embodiments and is not intended to be limiting. The terms “a,” “an,” and “the” include the plural forms as well, unless clearly indicated otherwise. The terms “comprises” and/or “comprising,” when used in this Specification, specify the presence of the stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, and/or components. In an embodiment, “connected” and “connecting” as described herein can refer to being “directly connected” and “directly connecting”, and/or “contacts” and “contacting” as described herein can refer to “directly contacts” and “directly contacting”.
With regard to the preceding description, it is to be understood that changes may be made in detail, especially in matters of the construction materials employed and the shape, size, and arrangement of parts without departing from the scope of the present disclosure. This Specification and the embodiments described are exemplary only, with the true scope and spirit of the disclosure being indicated by the claims that follow.
Number | Date | Country | |
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Parent | 18175974 | Feb 2023 | US |
Child | 18582353 | US |