The present invention generally relates to a condenser assembly and, more specifically, to a compact wire on tube condenser assembly for a refrigerating appliance.
Known condensers are formed from a tubular conduit constructed into a serpentine shape with a wire frame attached around the tubular conduit. This type of condenser is often referred to as a wire on tube condenser, a wire and tube condenser, or a WoT condenser. These wire on tube condensers may have a planar lateral profile, a U-shaped lateral profile, a sawtooth lateral profile, or other profiles. A condenser with a lateral profile of a sawtooth are sometimes referred to as a sawtooth condenser, a zig-zag condenser, a wave condenser, or the like.
Currently, in order to increase the amount of heat exchanged from a wire on tube condenser via the method of increasing heat transfer surface area, the heat exchange surface area of at least one of the wires and of the tubular conduit may be increased. In order to increase the length of tubular conduit and retain the current bend radius of the tubular conduit, the overall dimensions of the condenser may increase. The increase in overall volume of the condenser with an increased heat exchange surface area may be unacceptable since the condenser may have to fit into an existing air passageway.
A modified manufacturing process or custom tooling may be needed in order to reduce the bend radius of the tubular conduit and form a condenser with a tighter wound tubular conduit. Using a custom manufacturing process to minimize the increase in dimensions of the condenser is typically not desired due to additional manufacturing or tooling costs.
One aspect of the present invention relates to a wire on tube condenser assembly that includes at least two separately and independently produced wire on tube condensers where each of the at least two wire on tube condensers has a condenser inlet and a condenser outlet. The at least two wire on tube condensers are at least substantially locked and positioned in a matingly engaged configuration forming a condenser assembly. The at least two wire on tube condensers are configured to be operationally connected in at least one of a parallel configuration, a series configuration, a selectable configuration, a split configuration, and a bypass configuration.
Another aspect of the present invention includes an appliance having a machine compartment that includes a housing with at least one airflow path and a fan configured to cause a flow of cooling air. An air passageway is operationally connected to the machine compartment and configured to allow airflow into the machine compartment. The air passageway contains a condenser assembly that includes at least two separately and independently produced wire on tube condensers that are at least substantially locked and positioned in a matingly engaged configuration and operationally connected in at least one of the following configurations: a parallel configuration, a series configuration, a selectable configuration, a split configuration, and a bypass configuration. The air passageway further contains an exhaust port for discharging heated air radiated from the at least two wire on tube condensers. Each of the at least two wire on tube condensers has a condenser inlet and a condenser outlet.
Yet another aspect of the present invention includes a method of assembling a compact wire on tube condenser assembly that includes the steps of providing at least two separately and independently produced wire on tube condensers, at least substantially locking the at least two condensers within an air passageway of an appliance in a matingly engaged configuration to form the condenser assembly that is typically configured to be used and entirely spaced within the air passageway.
These and other features, advantages and objects of the present invention will be further understood and appreciated by those skilled in the art by reference to the following specification, claims, and appended drawings.
The foregoing summary, as well as the following detailed description of the invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there are shown in the drawings, certain embodiments which are presently preferred. It should be understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown. Drawings are not necessary to scale. Certain features of the invention may be exaggerated in scale or shown in schematic form in the interest of clarity and conciseness.
Before the subject invention is described further, it is to be understood that the invention is not limited to the particular embodiments of the invention described below, as variations of the particular embodiments may be made and still fall within the scope of the appended claims. It is also to be understood that the terminology employed is for the purpose of describing particular embodiments, and is not intended to be limiting. Instead, the scope of the present invention will be established by the appended claims.
Where a range of values is provided, it is understood that each intervening value, to the tenth of the unit of the lower limit unless the context clearly dictates otherwise, between the upper and lower limit of that range, and any other stated or intervening value in that stated range, is encompassed within the invention. The upper and lower limits of these smaller ranges may independently be included in the smaller ranges, and are also encompassed within the invention, subject to any specifically excluded limit in the stated range. Where the stated range includes one or both of the limits, ranges excluding either or both of those included limits are also included in the invention.
In this specification and the appended claims, the singular forms “a,” “an” and “the” include plural reference unless the context clearly dictates otherwise.
For purposes of description herein the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the invention as oriented in
The present disclosure includes an appliance with a heating, cooling, dehumidifying, or refrigerating function having a heat exchange system, alternately referred to as a vapor compression system. Vapor compression systems of the present disclosure typically include at least one evaporator, at least one compressor, at least one expansion device, and a condenser assembly. The appliance may be any appliance incorporating a vapor compression system, including, but not limited to, a refrigerator, a freezer, a dishwasher, a laundry dryer, a combination laundry washer dryer, an air conditioner, an air heater, a water heater, a dehumidifier, and the like.
An evaporator of the present application is a heat exchanger where heat is absorbed into a working refrigerant within the evaporator and the working refrigerant is evaporated. A condenser is a heat exchanger where heat is rejected from the working refrigerant and the refrigerant is then condensed. The condenser assembly of the present application may be used as an evaporator assembly. The condenser assembly may function as an evaporator or a heat exchanger if configured as such in a vapor compression system and such systems are meant to be encompassed by the present application. The words “tube”, “tubing”, and the phrase “tubular conduit” are used interchangeably and refer to conduit configured to contain and capable of containing and communication of one or more refrigerants, typically fluid refrigerants through the conduit.
The inventions disclosed herein provide a method to assemble a compact condenser assembly while minimizing the increase in overall dimensions, or volume, of the condenser assembly and significantly and dramatically minimizing or eliminating the need for a custom manufacturing process or custom tooling all while also doing so in a manner that surprisingly also minimizes the decrease in airflow due to the increased heat exchange surface area.
Additionally, the condenser assembly includes at least two condenser inlets and at least two condenser outlets. The condenser assembly is operationally configured so that at least two portions of the condenser assembly tubular conduit may be operationally connected and provide a flow of refrigerant(s) or other fluids through the portions of the tubular conduit operationally connected in one or more of the following configurations: in parallel, in series, and/or selectively connected. Selectively connected (i.e. a selectable configuration) is defined as a configuration which allows the user and/or the appliance to selectively operate the sub-condensers in at least one of a parallel configuration, a series configuration, a bypassed configuration where at least one of the sub-condensers is bypassed, and/or a split configuration where at least one of the sub-condensers is operationally connected to a second separate heat exchange system from a first heat exchange system, typically based upon operational needs of the appliance. The appliance or the condenser assembly typically may have at least one or more valve and/or connector that are configured to change the connection between the individual condensers from a parallel configuration to a series configuration (and vice versa).
Alternatively, a portion of the condenser assembly tubular conduit may be operationally connected to a separate heat exchange system, may be selectively bypassed, connected or selectively connected to a heat storage or a heat recovery system, and/or selectively connected to more than one heat exchange circuit.
The direction of flow in a portion of the condenser assembly tubular conduit may be operationally controlled to be in the same direction or in an opposite direction than the flow in a second portion of the condenser assembly tubular conduit. The condenser assembly typically includes at least two separately and independently produced wire on tube condensers. The at least two wire on tube condensers are at least substantially locked or fully locked and positioned in a matingly engaged configuration. The at least two wire on tube condensers may be stacked, layered, spaced apart, or nested together to form a condenser assembly with two condenser inlets and two condenser outlets. When the condenser assembly includes two or more serpentine condensers in a zig-zag or sawtooth configuration, the valleys of the condensers are seated and nested within one another and the bottom facing surface of the upper condenser typically, but does not necessarily, directly engages the upper surface of the condenser below it. Multiple condensers may be stacked to form a condenser assembly. Two, three, four, or a plurality of condensers may be stacked or assembled into a multi-layer condenser assembly.
The stacking of the condensers offsets the tubular conduits to expose the tubular conduits to airflow. The spacing of the tubular conduits and wires minimizes the obstruction of airflow. The wires and/or the tubular conduit of the additional condenser may rest on top of, be spaced above, be spaced apart, and/or fit in the spaces between the wires and tubular conduit of the first condenser. Spacers may be used to position the at least two condensers with respect to each other. The spacers provide/produce a gap between the tubular conduits of each condenser. The spacers may be used to fasten the at least two condensers to each other, to accommodate dimensional differences between the condenser profiles, to improve airflow through the condensers, and/or to prevent movement between the at least two condensers. The spacers may alternatively be one or more of a spacer, a clip, a bracket, a brace, a clamp, a holder, a pad, an insert, a fastener, a screw, a shim, and/or a sheet of metal or plastic or any combination thereof. The spacers may alternatively fasten a first condenser to a surface in an air passageway and fasten a second condenser to a second surface in the air passageway such that the first and second condensers are spaced with a gap between the condensers.
There may be sufficient elasticity in the wire and tube condensers depending upon various factors of their construction to allow layering of at least two condensers to form a condenser assembly without using any spacers. The at least two condensers will typically have a substantially similar or identical lateral profile and may snugly fit together enough to prevent shifting, rubbing, or vibration without the need for any spacers between the two condensers of the condenser assembly.
Optionally, at least one fastener may be used to fasten the condenser assembly to a surface of an air passageway of the appliance or another portion of the appliance. Optionally, at least one fastener may be used to fasten the at least two condensers together to form a condenser assembly.
At least one of a valve and a connector may be assembled as part of or operably engaged with a condenser assembly of the present application. The condenser assembly may have only a single inlet and a single outlet since the connectors to the additional inlet and the additional outlet may be operably engaged in the condenser assembly. Conversely, at least one of a valve and a connector may be alternatively separate from the condenser assembly and assembled as part of the appliance instead.
The condenser assemblies, because they typically include two or more individual condensers that themselves can function as a single condenser, allow for a modular approach and permit the condenser assemblies to be used in multiple applications where more or less surface area of the condenser is needed or would be advantageous. A multiple layer condenser assembly may be used to reduce the space needed for the air passageway if an increase in overall heat exchange surface area is not needed.
Referring to
Referring to
The first condenser 146 typically includes a first condenser inlet 150, a first condenser outlet 160, and a tubular conduit 162 with a passageway therethrough and configured to carry one or more refrigerant(s). Typically, the tubular conduit 162 is a metal conduit, more typically a metal of high thermal conductivity such as steel, copper, aluminum, or the like. The refrigerant is typically a two-phase refrigerant and may be at least one of a fluid, a gas, or a liquid. At least a portion of the tubular conduit 162 is typically formed into a serpentine shape with the tubular conduit 162 having a plurality of U-shaped tube passes with each pass having at least two substantially straight tube sections 170, 171 joined by a U-shaped end cap section 172. The straight tube sections 170, 171 may be oriented across a width 173 of the condenser 146. The tubular conduit 162 has a flow path progressing from the first condenser inlet 150, through the plurality of U-shaped tube sections 171, 172, 174, 176, 178, making alternating back and forth passes in a direction along the width 173 of the condenser 146, progressing along a length 179 of the condenser 146, and progressing to the condenser outlet 160. The first condenser 146 further typically includes an extended heat transfer surface 180 arranged connected to the straight tube sections 170, 171 across the length 179 of the condenser 146. The extended heat transfer surface 180 may be a plurality of wires 182 wrapped around a length of the tubular conduit 162. A plurality of thermal transfer fins (not shown) may be in a thermally engaged relationship with the tubular conduits to facilitate heat dissipation to the air flowing past the tubular conduits, fins and the overall condenser or condenser assembly. The tubular conduit 162 (
The tubular conduit 162 (
The condenser 146 (
The contour of the individual U-shaped passes 171, the radius of the U-shaped end cap sections 172, the length of the individual substantially straight sections 170, the condenser width 173, the condenser length 179, the condenser height 183, and the tubular conduit 162 tube diameter 185 may be and typically are substantially similar or identical between the at least two condensers 146, 148, may be substantially different between the at least two condensers 146, 148, and optionally may vary within a specific condenser 146. Likewise, the placement, profile, wire diameter 187, wire material, and number of wires 180 may vary between the at least two condensers 146, 148. The tubular conduit 162 may be any suitable cross-sectional shape including: round, substantially oval, oval, oblong, parallelogram, or rectangular over at least a portion of the tubular conduit length. The tubular conduit 162 has a conduit diameter 185 and the wires 180 of the condenser having a wire diameter 187 (
Referring to
Referring to
The overall height 246 of the condenser assembly 130 (
The energy usage was measured on two refrigerators with a single condenser. The energy usage was measured after the refrigerators were fitted a condenser assembly with two condensers connected in series.
Exemplary energy usage is provided in Tables I and III from the two side by side refrigerators of the same model (WHIRLPOOL® GSS26C4XXW03) when tested in accordance with AHAM HRF-1-2007 (Section 8). Unit 1 and Unit 2 were fitted with a single condenser and evaluated for energy usage. Exemplary energy usage is provided in Tables II and IV from Unit 1 and Unit 2 fitted with two substantially similar condensers connected in series.
The freezer temperature and the cabinet temperature show the average freezer compartment air temperature and the average fresh food compartment air temperature, respectively, in degrees F. as measured per AHAM HRD-1-2007 (Section 8). The Energy Usage is the energy consumption in kW-hr/day as measured per AHAM HRD-1-2007. Comparing the energy usage at similar average compartment temperatures shows the condenser assembly connected in series used about 0.69% to about 4.3% less kw-hr/day during any given test. The average energy usage for a single condenser was 1.475 kW-hr/day. The average energy usage for a condenser assembly connected in series was 1.44 kW-hr/day. Based on this data, an average energy savings of about 2.3% was obtained by using a condenser assembly of the present disclosure employing two nested condensers over a single condenser.
This exemplary data shows that by using a condenser assembly of the present disclosure employing two nested condensers an overall reduction in energy usage was obtained. The overall width and length of the condenser assembly was substantially similar to the overall width and length of a single condenser. The overall height of the exemplary condenser assembly increased about 11 mm. Depending on the available clearance in an air passageway, the condenser assembly may fit within the air passageway with no changes to the air passageway.
As discussed above, the first condenser 146 and the second condenser 148 may be affixed to a surface of the air passageway 131 or machine compartment 122 or other surface of the appliance 100 using one or more fasteners 158 (
Referring to
As shown in
A condenser assembly 300 (
A condenser assembly 130 may be positioned in a variety of alternate locations in an appliance 100 (
The airflow path 400 through the condenser assembly 130 is shown in
The alignment of the at least two condensers 146, 148 in the condenser assembly 130 may be adjusted to minimize the air pressure drop. When the at least two condensers 146, 148 are at least substantially locked and positioned in a matingly engaged configuration where the at least two condensers 146, 148 are nested, stacked, spaced apart, or layered, the tubular conduit U-shaped passes are typically spaced in such a way that the airflow is distributed more evenly across the face area of the condenser assembly 130. The “face area of the condenser assembly” is the width 407 of the condenser assembly 130 multiplied by the height 246 of the condenser assembly 130 (
The contour of each condenser 146, 148 can be adjusted to optimally improve the airflow and heat transfer when at least two condensers 146, 148 are stacked, nested, layered, spaced apart, or assembled together to form the condenser assembly 130. The wire tips 408, 410 of the first condenser 146 are typically aligned with the wire tips 412, 414 of the second condenser 148. The wire frame 416 of the first condenser 146 rests on the wire frame 418 of the second condenser 148. The tubular straight sections 420 of the first condenser 146 are typically offset from the tubular straight sections 406 of the second condenser 148.
The first condenser 450 is operationally connected to a second condenser 452 in series in the schematic view of an appliance heat exchange circuit 454 shown in
The heat exchange circuit 550 of
The first condenser 644 and the second condenser 648 in a schematic view of an appliance heat exchange circuit 650 as shown in
An appliance utilizing a condenser assembly may be configured to operate each individual condenser of the condenser assembly independently. Depending on the needs of the application, the appliance may be configured to operationally connect the at least two condensers in parallel, in series, or in a selectable configuration using valves or conduit connectors. The pairs of inlets and outlets of the individual condensers may be operationally connected to different heat exchange circuits, to different ports on a compressor, typically a two-stage compressor, linear compressor, or a variable speed compressor, or connected together as discussed previously. Alternatively, the selectable configuration may operationally reverse the direction of refrigerant flow through at least one of the individual condensers, restrict the amount of refrigerant flow through at least one of the individual condensers, and/or block refrigerant flow through at least one of the individual condensers.
The appliance may have a controller that selectively controls the flow of refrigerant through the condensers. The appliance may have at least one sensor to monitor the ambient air temperature, the refrigerant air temperature, the refrigerator air temperature, the freezer air temperature, the refrigerant pressure, and/or ambient humidity and the like. The controller may selectively control the at least one valve or connector based on the sensed input and/or based on input from one or more sensors, a timing chart, a switch, an algorithm, a cycle profile, a user selected input or option, opening or closing a door, drawer, or other access to the appliance interior, temperature of an internal volume in the appliance, ambient temperate outside of the appliance, an signal from outside of the appliance, thermal loading of an internal volume in the appliance, temperature or pressure of the refrigerant, a defrost step, an ice making step, time of day, time of year, energy consumption of the appliance, and the like.
The first condenser 750 and the second condenser 752 of the schematic view of an appliance heat exchange circuit 754 of
As shown in
A condenser assembly increases the amount of heat transfer surface area while minimizing the increase in the overall dimensions of the condenser assembly. The condenser assembly can be assembled as a unit and then placed into an appliance as a unit. Alternatively, the condensers can be assembled into the appliance individually and then fastened to each other or fastened to one or more mounting surfaces. The individual condensers may be positioned in a matingly engaged configuration in the appliance without using fasteners or spacers.
The at least one of a valve or a connector between the inlets and outlets of the individual condensers in the condenser assembly, may be assembled into the condenser assembly prior to placement in an appliance. Alternatively, the at least one of a valve or a connector may be assembled as part of the appliance. The inlets and outlets of the condenser assembly may be connected to the at least one of a valve or a connector when the condenser assembly is located in the appliance or before the condenser assembly is placed into the appliance.
By using at least two separately and independently produced condensers to form a condenser assembly, the individual condensers may be used as a sole condenser in certain applications where less heat transfer surface area is needed, but also used as a modular system for multiple appliances or when greater heat transfer surface area is more beneficial based upon appliance configuration or energy efficiency or both.
The above description is considered that of the preferred embodiment only. Modifications of the invention will occur to those skilled in the art and to those who make or use the invention. Therefore, it is understood that the embodiments shown in the drawings and described above is merely for illustrative purposes and not intended to limit the scope of the invention, which is defined by the following claims as interpreted according to the principles of patent law, including the Doctrine of Equivalents.
This invention was made with government support under Award No. DE-EE0003910, awarded by the U.S. Department of Energy. The government has certain rights in the invention.
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Whirlpool Corp. Part No. W10276898 “Condenser—Formed, FD”, May 13, 2009. |