Some fabric treatment appliances, such as a washing machine, a clothes dryer, and a fabric refreshing or revitalizing machine, use steam generators for various reasons. The steam from the steam generator may be used to, for example, heat water, heat a load of fabric items and any water absorbed by the fabric items, dewrinkle fabric items, remove odors from fabric items, sanitize the fabric items, and sanitize components of the fabric treatment appliance.
Water from a water supply coupled with the steam generator typically provides water to the steam generator for conversion to steam. The water supply fills a steam generation chamber of the steam generator with water, and a heating element of the steam generator is activated to heat the water present in the steam generation chamber to generate steam. Steam generated in the steam generation chamber commonly flows from the steam generation chamber to a fabric treatment chamber via a steam supply conduit attached to the steam generator.
One problem associated with steam generators, especially in-line or flow-through steam generators, is that the heating element distributes heat in an inefficient manner. The heating element wraps around the steam generator in a manner providing, by conduction through the steam generator, substantially uniform thermal output into the steam generation chamber. For example, a standard in-line steam generator has a heating element formed from a resistive wire that is wrapped around the steam generation chamber. The steam generation chamber is often filled with an operating volume of water less than the total capacity of the steam generation chamber to provide for faster steam generation times and to provide room for expansion and boiling water. The operation volume of water results in an operational water level within the steam generation chamber. Air fills the steam generation chamber above the operational water level. However, the heating element is wrapped around the portion of the steam chamber containing both water and air. As the air is not a good conductor of heat, the portion of the heating element below the water level will more efficiently conduct heat into the water than the portion of the heating element above the water level.
In addition, inefficient heating of the steam generator can increase the buildup of scale inside the steam generation chamber. The temperature of the water in the steam generation chamber is limited, as it will eventually change phase to steam when it receives enough thermal output. The temperature of the steam, air, and vapor, however, is not limited. The upper portion of the steam generation chamber, therefore, has a tendency to reach higher temperatures. Higher temperatures convert soft calcium deposits in the steam generation chamber to hard calcium, which is not easily removed by the movement of water therein. If flow out of the steam generator or flow through the steam supply conduit becomes impaired due to the buildup of scale, the steam generator will malfunction and possibly damage the fabric treatment appliance.
A steam generator according to one embodiment of the invention includes a steam generation chamber for converting the water to steam, and a heating element thermally coupled with the steam generation chamber and having a first portion below an operational water level of the steam generation chamber and a second portion above the operational water level, with the first portion having a greater thermal output than the second portion.
In the drawings:
Referring now to the figures,
The tub 14 and/or the drum 16 may be considered a receptacle, and the receptacle may define a treatment chamber for receiving fabric items to be treated. While the illustrated washing machine 10 includes both the tub 14 and the drum 16, it is within the scope of the invention for the fabric treatment appliance to include only one receptacle, with the receptacle defining the treatment chamber for receiving the fabric items to be treated.
Washing machines are typically categorized as either a vertical axis washing machine or a horizontal axis washing machine. As used herein, the “vertical axis” washing machine refers to a washing machine having a rotatable drum that rotates about a generally vertical axis relative to a surface that supports the washing machine. Typically, the drum is perforate or imperforate and holds fabric items and a fabric moving element, such as an agitator, impeller, nutator, and the like, that induces movement of the fabric items to impart mechanical energy to the fabric articles for cleaning action. However, the rotational axis need not be vertical. The drum can rotate about an axis inclined relative to the vertical axis. As used herein, the “horizontal axis” washing machine refers to a washing machine having a rotatable drum that rotates about a generally horizontal axis relative to a surface that supports the washing machine. The drum may be perforated or imperforate, holds fabric items, and typically washes the fabric items by the fabric items rubbing against one another and/or hitting the surface of the drum as the drum rotates. In horizontal axis washing machines, the clothes are lifted by the rotating drum and then fall in response to gravity to form a tumbling action that imparts the mechanical energy to the fabric articles. In some horizontal axis washing machines, the drum rotates about a horizontal axis generally parallel to a surface that supports the washing machine. However, the rotational axis need not be horizontal. The drum can rotate about an axis inclined relative to the horizontal axis, with fifteen degrees of inclination being one example of inclination.
Vertical axis and horizontal axis machines are best differentiated by the manner in which they impart mechanical energy to the fabric articles. In vertical axis machines, the fabric moving element moves within a drum to impart mechanical energy directly to the clothes or indirectly through wash liquid in the drum. The clothes mover is typically moved in a reciprocating rotational movement. In horizontal axis machines mechanical energy is imparted to the clothes by the tumbling action formed by the repeated lifting and dropping of the clothes, which is typically implemented by the rotating drum. The illustrated exemplary washing machine of
With continued reference to
The washing machine 10 of
The exemplary washing machine 10 may further include a steam generation system. The steam generation system may include a steam generator 60 that may receive liquid from the water supply 29 through a second supply conduit 62, optionally via a reservoir 64. The inlet valve 34 may control flow of the liquid from the water supply 29 and through the second supply conduit 62 and the reservoir 64 to the steam generator 60. The inlet valve 34 may be positioned in any suitable location between the water supply 29 and the steam generator 60. A steam conduit 66 may fluidly couple the steam generator 60 to a steam inlet 68, which may introduce steam into the tub 14. The steam inlet 68 may couple with the tub 14 at any suitable location on the tub 14 and is shown as being coupled to a rear wall of the tub 14 in
An optional sump heater 52 may be located in the sump 38. The sump heater 52 may be any type of heater and is illustrated as a resistive heating element for exemplary purposes. The sump heater 52 may be used alone or in combination with the steam generator 60 to add heat to the chamber 15. Typically, the sump heater 52 adds heat to the chamber 15 by heating water in the sump 38. The tub 14 may further include a temperature sensor 54, which may be located in the sump 38 or in another suitable location in the tub 14. The temperature sensor 54 may sense the temperature of water in the sump 38, if the sump 38 contains water, or a general temperature of the tub 14 or interior of the tub 14. The tub 14 may alternatively or additionally have a temperature sensor 56 located outside the sump 38 to sense a general temperature of the tub or interior of the tub 14. The temperature sensors 54, 56 may be any type of temperature sensors, which are well-known to one skilled in the art. Exemplary temperature sensors for use as the temperature sensors 54, 56 include thermistors, such as a negative temperature coefficient (NTC) thermistor.
The washing machine 10 may further include an exhaust conduit (not shown) that may direct steam that leaves the tub 14 externally of the washing machine 10. The exhaust conduit may be configured to exhaust the steam directly to the exterior of the washing machine 10. Alternatively, the exhaust conduit may be configured to direct the steam through a condenser prior to leaving the washing machine 10. Examples of exhaust systems are disclosed in the following patent applications, which are incorporated herein by reference in their entirety: U.S. patent application Ser. No. 11/464,506, titled “Fabric Treating Appliance Utilizing Steam,” U.S. patent application Ser. No. 11/464,501, titled “A Steam Fabric Treatment Appliance with Exhaust,” U.S. patent application Ser. No. 11/464,521, titled “Steam Fabric Treatment Appliance with Anti-Siphoning,” and U.S. patent application Ser. No. 11/464,520, titled “Determining Fabric Temperature in a Fabric Treating Appliance,” all filed Aug. 15, 2006.
The steam generator 60 may be any type of device that converts the liquid to steam. For example, the steam generator 60 may be a tank-type steam generator that stores a volume of liquid and heats the volume of liquid to convert the liquid to steam. Alternatively, the steam generator 60 may be an in-line steam generator that converts the liquid to steam as the liquid flows through the steam generator 60. As another alternative, the steam generator 60 may utilize the sump heater 52 or other heating device located in the sump 38 to heat liquid in the sump 38. The steam generator 60 may produce pressurized or non-pressurized steam.
Exemplary steam generators are disclosed in U.S. patent application Ser. No. 11/464,528, titled “Removal of Scale and Sludge in a Steam Generator of a Fabric Treatment Appliance,” U.S. patent application Ser. No. 11/450,836, titled “Prevention of Scale and Sludge in a Steam Generator of a Fabric Treatment Appliance,” and U.S. patent application Ser. No. 11/450,714, titled “Draining Liquid From a Steam Generator of a Fabric Treatment Appliance,” all filed Jun. 9, 2006, in addition to U.S. patent application Ser. No. 11/464,509, titled “Water Supply Control for a Steam Generator of a Fabric Treatment Appliance,” U.S. patent application Ser. No. 11/464,514, titled “Water Supply Control for a Steam Generator of a Fabric Treatment Appliance Using a Weight Sensor,” and U.S. patent application Ser. No. 11/464,513, titled “Water Supply Control for a Steam Generator of a Fabric Treatment Appliance Using a Temperature Sensor,” all filed Aug. 15, 2006, which are incorporated herein by reference in their entirety.
In addition to producing steam, the steam generator 60, whether an in-line steam generator, a tank-type steam generator, or any other type of steam generator, may heat water to a temperature below a steam transformation temperature, whereby the steam generator 60 produces heated water. The heated water may be delivered to the tub 14 and/or drum 16 from the steam generator 60. The heated water may be used alone or may optionally mix with cold or warm water in the tub 14 and/or drum 16. Using the steam generator 60 to produce heated water may be useful when the steam generator 60 couples only with a cold water source of the water supply 29. Optionally, the steam generator 60 may be employed to simultaneously supply steam and heated water to the tub 14 and/or drum 16.
The liquid supply and recirculation system and the steam generation system may differ from the configuration shown in
Other alternatives for the liquid supply and recirculation system are disclosed in U.S. patent application Ser. No. 11/450,636, titled “Method of Operating a Washing Machine Using Steam;” U.S. patent application Ser. No. 11/450,529, titled “Steam Washing Machine Operation Method Having Dual Speed Spin Pre-Wash;” and U.S. patent application Ser. No. 11/450,620, titled “Steam Washing Machine Operation Method Having Dry Spin Pre-Wash,” all filed Jun. 9, 2006, which are incorporated herein by reference in their entirety.
Referring now to
Many known types of controllers may be used for the controller 70. The specific type of controller is not germane to the invention. It is contemplated that the controller is a microprocessor-based controller that implements control software and sends/receives one or more electrical signals to/from each of the various components (inlet valve 34, detergent dispenser 32, steam generator 60, pump 44, motor 22, control panel 80, and temperature sensors 54, 56) to effect the control software. As an example, proportional control (P), proportional integral control (PI), and proportional derivative control (PD), or a combination thereof, a proportional integral derivative control (PID control), may be used to control the various components.
The steam generator 160 comprises a tube 130 about a portion of which is wrapped a heating element 146, which is illustrated as an electrically resistive heating element that conducts heat to the tube 130. A cover 148 encloses most of the heating element 146. In the illustrated embodiment, the tube has a circular cross-section. Alternatively, the tube 130 may have a cross-section of a different shape, such as triangular, square, or polygonal, for example.
Due to the change in pitch between the first portion 152 and the second portion 154 of the variable pitch heating element 150, a greater total length of the wire forming the variable pitch heating element 150 may be located below the operational water level L in the first portion 152 than the total length of wire above the operational water level L. As the heat outputted by the heating element is the same for a given lineal portion of the wire, the greater the length of wire below the operational water level L results in the heating element 146 having a greater thermal output below the operation water level than above the water level L. Therefore, a greater portion of the total thermal output of the heating element 146 is directed to the portion of the steam generation chamber 136 below the water level L.
A numerical example may be helpful. Assuming the heating element is a 1000 watt heater when operating at design conditions, if 25% of the wire lies above the operational water level L and 75% of the wire lies below the operation water level L, then 250 watts of thermal output is directed into the tube 130 above the operational water level L and 750 watts of thermal output is directed into the tube below the operation water level L.
The variable pitch heating element 150 may be formed by winding a wire around a shaped former, such as a rod. The pitch may be changed by winding the wire with an increased spacing between adjacent coils along portions corresponding to the second portion 154 of the variable pitch heating element 150. Alternatively, the variable pitch heating element 150 may be formed by winding a wire around a shaped former to form a coil of uniform pitch and then slightly stretching the coiled wire along portions corresponding to the second portion 154 of the variable pitch heating element 150.
The stretched heating element 160 may be formed by beginning with a coiled wire having generally similar coils with the same pitch. A portion of the coils are then pulled or stretched along a longitudinal axis to form a stretched portion, which becomes the second portion above the operation water level L. The longitudinal axis may be a central axis extending through the centers of the coils. In the illustrated embodiment, the longitudinal axis wraps around the tube 130. More specifically, the stretched heating element 160 may be formed by winding the wire around a shaped former, such as a rod. The wire may be wound so as to have a uniform pitch, and the portions of the coiled wire corresponding to the second portion 164 may then be axially over-stretched so as to reduce the number of coils in the second portion.
The stretched coils tend to have a smaller effective diameter and a much greater pitch than the non-stretched coils, resulting in fewer coils per unit length along the longitudinal axis of the heating element 160, which can also be characterized as less wire per unit length along the longitudinal axis. The reduction in coils and/or wire in the second portion as compared to the first portion results in the second portion having less thermal output than the first portion. Therefore a greater portion of the thermal output is located below the operational water level than above the operational water level.
Due to the change in the cross-sectional area between the coils in the first portion 172 and the coils in the second portion 174, a greater total length of the wire forming the variable coil size heating element 170 is located below the operational water level L in the first portion 172. Therefore a greater portion of the thermal output is located below the operational water level than above the operational water level.
The variable cross-sectional area heating element 170 may be formed by winding a portion of the wire corresponding to the first portion 172 around a first shaped former, such as a rod, having a first cross-sectional area. A remaining portion of the wire corresponding to the second portion 174 may then be wound around a second shaped former, such as a rod, having a second cross-sectional area smaller than the first cross-sectional area. Alternatively, a single shaped former having a plurality of sections corresponding to each of the first portion 172 and the second portion 174 with different cross-sectional areas may be used to form the variable coil size heating element 170.
The partially coiled heating element 180 may be formed by winding a portion of the wire corresponding to the first portion 182 around a shaped former of a constant cross-sectional area, such as a rod, so that the coiled wire has a uniform pitch. The remaining wire corresponding to the second portion 184 is not coiled.
The variable wire size heating element 190 may be formed by stretching or rolling a wire of a constant cross-sectional area along portions of the wire that correspond to the second portion 194 of the variable wire size heating element 190. Stretching or rolling the sections of the wire corresponding to the second portion 194 will decrease the cross-sectional area of the wire in the second portion 194 as compared to the cross-sectional area of the wire in the first portion 192.
The serpentine heating element 200 may be formed by bending a wire so as to form a serpentine shape that curves around a portion of the steam generation chamber 136, as is illustrated in
The different approaches of the previously described embodiments can be combined to form a heating element where a greater portion of the thermal output is located below the operational water level than above the operational water level. For example, any of the embodiments of
While the variable thermal output heating element has been described up to this point as varying the output relative to the top and bottom of the steam generator, it can also be applied to vary the thermal output from end-to-end. For example, it may be beneficial to vary the thermal output from the inlet end to the outlet end. One such approach is illustrated in
Although the heating elements of the various embodiments described above are illustrated as being coiled around an exterior of the tube 130, the heating elements may alternatively be coiled within the steam generation chamber 136 along an interior of the tube 130.
The steam generator 60 may be employed for steam generation during operation of the washing machine 10, such as during a wash operation cycle, which may include prewash, wash, rinse, and spin steps, during a washing machine cleaning operation cycle to remove biofilm and other undesirable pests from the washing machine, during a refresh or dewrinkle operation cycle, or during any other type of operation cycle. The steam generator 60 may also be employed to clean the steam generator 60 itself. An exemplary operation of the steam generator 60 is provided below.
To operate the steam generator 60, water from the water supply 29 may be provided to the steam generator 60 via the valve 34, the second supply conduit 62, the water supply conduit 104, and the tank 90. Water that enters the tank 90 from the water supply conduit 104 fills the volume of the tank 90 between the steam generator inlet and the tank bottom 92 to thereby form the water plug. Once the water reaches the steam generator inlet at the first end 132 of the steam generator tube 130, the water flows into the steam generator tube 130 and begins to fill the steam generation chamber 136 and, depending on the configuration of the steam generator 60 and the steam conduit 66, possibly a portion of the steam conduit 66. In the exemplary embodiment, the water that initially enters the steam generation chamber 136 fills the steam generation chamber 136 and the steam conduit 66 to a level corresponding to the water plug without a coincident rise in the water level in the tank 90. Once the water fills the steam generation chamber 136 to the level corresponding to the water plug, further supply of water from the water supply conduit 104 causes the water levels in the tank 90 and the steam generation chamber 136 to rise together as a single water level. If the steam generation chamber 136 becomes completely filled with water, further supply of water from the water supply conduit 104 causes the water level in the tank 90 to further rise. Due to the pull of gravity, the water supplied to the steam generation chamber 136 will fill the steam generation chamber 136 from the bottom up.
Water may preferably be supplied to the operational water level L, which is typically less than a maximum water level corresponding to filling a total volume of the steam generation chamber 136. The operational water level L may correspond to a level of water present in the steam generation chamber 136 when the steam generation chamber is filled to a volume optimal for steam generation. Although the operational water level L is illustrated as a single level, the actual level of water present in the steam generation chamber 136 during operation of the steam generator 60 may vary. For example, the water is normally supplied to the steam generator based on time or to a sensed level. Steam is then created which lowers the water level. At some point the water level may drop low enough that water is re-supplied to prevent the steam generator from running out of water. Alternatively, the water may be re-supplied continuously or at discrete times to keep the water level within a desired range. In some in-line or flow through steam generators, the operational water level may vary from 5% to 50% of the total volume. In tank-type steam generators, the percentage may be much higher and very close to 100%. Moreover, when steam is being generated, the creating of bubbles in the water makes the water very turbulent and the water level may change quickly. Thus, the operational water level L may be thought of more as an expected, target, or effective water level and typically is machine and process dependent.
At any desired time, the heat source 138 may be activated to generate heat to convert the water in the steam generation chamber 136 to steam. For example, the heat source 138 may be activated prior to, during, or after the supply of water. Because a greater total portion of the heating element 150, 160, 170, 180, 190, 200 according to the invention is present in a first portion 152, 162, 172, 182, 192, 202 of the heating element positioned below the operational water level L, thermal output from the heating element is concentrated on the water present in the steam generation chamber 136. This is because the thermal output is uniform along the length of the wire, so allocating a greater total length of wire to the first portion 152, 162, 172, 182, 192, 202 provides greater thermal output to the first portion. Water may be converted to steam by the addition of heat, but steam will only increase in temperature by the addition of heat. By concentrating the thermal output to areas of the steam generator 60 that have the greatest effect on creating steam, namely the area below the operational water level L, steam is generated more efficiently, and less heat is lost to the areas surrounding the steam generator 60.
Additionally, the steam generator 60 is less likely to malfunction due to a buildup of scale or calcification by implementing the inventive heating element. When the thermal output from the heating element is concentrated towards the area below the operational water level L, steam, air, and vapor present in the steam generation chamber 136 above the operational water level L is cooler. Because higher temperatures convert soft calcium to hard calcium, which is more difficult to remove than soft calcium, the asymmetric thermal output provided by the inventive heating output reduces the amount of hard calcium buildup.
Steam generated in the steam generation chamber 136 flows from the steam generator tube 130 and through the steam conduit 66 to the treatment chamber. In some circumstances, such as, for example, excessive scale formation or formation of other blockage in the steam generator 60 or the steam conduit 66, the steam may attempt to flow upstream to the water supply 29 rather than to the treatment chamber. However, the water plug between the steam generator inlet and the outlet of the water supply conduit 104 blocks steam from flowing from the steam generation chamber 136 backwards into the water supply conduit 104 and to the water supply 29.
During the operation of the washing machine 10, the siphon break device may prevent water or other liquids from the tub 14 and/or the drum 16 from undesirably flowing to the water supply 29 via the steam generator 60. Any siphoned liquids may flow through the steam generator 60, into the reservoir 64, through the water supply conduit 104, and through the siphon break conduit 116 (
While the invention has been specifically described in connection with certain specific embodiments thereof, it is to be understood that this is by way of illustration and not of limitation, and the scope of the appended claims should be construed as broadly as the prior art will permit.
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435088 | Oct 1926 | DE |
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853433 | Oct 1952 | DE |
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1847016 | Feb 1962 | DE |
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2202345 | Aug 1973 | DE |
2226373 | Dec 1973 | DE |
2245532 | Mar 1974 | DE |
7340082 | May 1975 | DE |
2410107 | Sep 1975 | DE |
2533759 | Feb 1977 | DE |
3103529 | Aug 1982 | DE |
3139466 | Apr 1983 | DE |
3408136 | Sep 1985 | DE |
3501008 | Jul 1986 | DE |
3627988 | Apr 1987 | DE |
8703344 | Aug 1988 | DE |
4116673 | Nov 1992 | DE |
4225847 | Feb 1994 | DE |
4413213 | Oct 1995 | DE |
4443338 | Jun 1996 | DE |
29707168 | Jul 1997 | DE |
19730422 | Jan 1999 | DE |
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19742282 | Feb 1999 | DE |
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0284554 | Sep 1988 | EP |
0287990 | Oct 1988 | EP |
0302125 | Aug 1989 | EP |
363708 | Apr 1990 | EP |
0383327 | Aug 1990 | EP |
0404253 | Dec 1990 | EP |
0511525 | Nov 1992 | EP |
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0726349 | Aug 1996 | EP |
0768059 | Apr 1997 | EP |
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1505193 | Feb 2005 | EP |
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1529875 | May 2005 | EP |
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1865101 | Dec 2007 | EP |
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2525645 | Oct 1983 | FR |
2581442 | Nov 1986 | FR |
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799788 | Aug 1958 | GB |
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02161997 | Jun 1990 | JP |
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2242088 | Sep 1990 | JP |
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03025748 | Jun 1991 | JP |
3137401 | Jun 1991 | JP |
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4158896 | Jun 1992 | JP |
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05115672 | May 1993 | JP |
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06123360 | May 1994 | JP |
08261689 | Oct 1996 | JP |
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9307798 | Apr 1993 | WO |
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9715709 | May 1997 | WO |
9803175 | Jan 1998 | WO |
0111134 | Feb 2001 | WO |
0174129 | Oct 2001 | WO |
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