Front load washing machine with a single wash/single rinse cycle

Abstract

A method and device as disclosed for modifying the manufacturing of a front load washing machine with a single wash and a single rinse cycle. Conventional prior art washing machines use multiple wash/multiple rinse cycles. However, using a single wash and a single rinse cycle with, optionally, using less water, provides effective washing if the single wash and single rinse cycles are extended to run beyond the conventional single cycles of multiple cycle machines.

Description

This patent application is a continuation-in-part and claims priority from patent application Ser. No. 10/277,024, filed Oct. 21, 2002, which claims priority from provisional patent application Ser. No. 60/335,055 filed Oct. 19, 2001.

FIELD OF THE INVENTION

Washing machines, specifically front load washing machines with wash run cycles modified to include a single, longer than normal wash cycle with typically equal or more water than normal, and a single, longer than normal, with typically equal or more water than normal, rinse cycle and, typically, running the spin cycle longer than normal.

BACKGROUND OF THE INVENTION

An 18-pound front load washing machine typically uses 29 to 40 gallons of water in a standard wash run. At the 29 gallon limit, there are typically 3 “drain and fill” cycles used: 1 wash cycle and 2 rinse cycles per run. At the 40 to 48 gallon limit, there are typically 5 “drain and fill” cycles, typically 1 pre-wash, 1 wash cycle and 3 rinse cycles. Each “drain and fill” cycle in a typical 18 pound front load washing machine uses about 9.7 gallons, each wash cycle in the typical prior art front load 18 pound washing machine runs for about 4 minutes using about 9.7 gallons of water, with the rinse being about 3-4 minutes using about 9.7 gallons of total water. The total time for a wash run for most prior art, 18 pound front load washing machine are 20 to 22 minutes plus fill time. Time is typically measured from the moment the water level reaches “full” to begin the cycle, until the drain opens to begin to empty the tub at the end of the cycle.

SUMMARY OF THE INVENTION

Applicant provides for a modification to the cycles of a laundry run for a front load 18 pound washing machine, which is adaptable to other machines. Applicant modifies prior art methods and machines in providing only a single wash and a single rinse cycle (and 2 drain and fill cycles) per laundry run. Even though there are fewer cycles used, a single wash and a single rinse cycle (therefore only draining the machine twice per run), it has proven effective when the time for the wash cycle is extended typically to up to about 8 to 15 minutes and further when the amount of water used in the wash cycle and in a rinse cycle is increased from about 9.7 to about 11.0 gallons. Note that while more water may be used per cycle in the two cycles in Applicant's modified system, the total water is still less than either the 3 or 5 cycle prior art machines because there are less “drain an fill” cycles. Indeed, Applicant typically uses 22 gallons or less water, therefore, saving of between 30 and 50 percent water, while providing for effective washing. The use of more water gets rid of oversudsing quicker and may have a psychological effect on the consumer who sees more water and thinks they are getting a better wash.

Applicant has found, however, that it is not necessary to increase the amount of water to get clean laundry. Applicant's method may include tipping the entire front loading machine forward, up to about 10° or so. The purpose of this is to create an “illusion” that there is more water in the tub than there actually is. This may or may not affect the quality of the wash, but helps customer acceptance—they see through the window the water level higher than what it would be if flat, think there is more water in the machine and think they are getting a better wash. Raising the rear may be done with spacers or blocks or other suitable means. The void between the front and rear, created by raising the rear may be filled by grout, to help stabilize the machine, if needed. At least one manufacturer, Milner, tilts their machines rearward. This may lower water consumption and may relieve stress on the bearings. Some machines tilt forward to unload wash when the wash is completed, and then tilt back flat.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B illustrate side elevational cross sectional of views of a typical front load and washing machine that is titled forward (FIGS. 1A and 1B) compared with normal horizontal mounting illustrated in FIG. 1C.

FIGS. 2A, 2B and 2C illustrate modifications to a mechanical timer wherein relays are provided to rapidly advance through pre-existing wash and/or rinse cycles and time delays are used to extend a single wash and single rinse cycle.

FIGS. 3A and 3B illustrate one modification on a prior art (FIG. 3A) light board wash system, using relays to eliminate cycles and time delays to extend cycles resulting in a single wash and single rinse cycles. Time may be increased over typical wash or rinse cycles (again, with drain and fill cycles between the wash and rinse cycles).

FIG. 4 illustrates a front load wash machine modified according to Applicant's present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Applicants may extend by about 10 to 20 percent (typically, may be more or less) the total time for a laundry run as compared to a prior art 3 to 5 cycle wash run but use less total water. The trade off is important for conserving water. By using only a single wash and a single rinse cycle but increasing, typically (but not necessarily), the amount of water and typically the time, Applicant's have provided for an effective means of cleaning fabric while using less total water.

The method and system of reducing the cycles and, typically, increasing the water and time per wash and rinse cycle may be done with any mechanical, computer program, chip, palm pilot, PC board or fiber optic control or any other type of timing device known in the art. Programmable timers exist that may be utilized to reduce the number of cycles and increase wash and rinse time.

Household soap typically will break down in about 10 to 12 minutes of wash time. The prior art, by draining a wash cycle before the soap is broken down wastes water and decreases the effectiveness of the rinse cycle. Industrial strength, high caustic soap breaks down about 14 minutes, because Applicant fills the machines only twice, they can use more water and increase the turbulence in the tub. Furthermore, by increasing the amount of water used on the rinse cycle and increasing the time, greater turbulence is created.

Prior Art

Typical Prior Art 5 Cycle 18# Front Load

1. Pre-wash: 9.7 gal, 2.50 min.

2. Wash: 9.7 gal, 4.0 min

• • Spin (optional): 1.0 min

3. Rinse: 9.7 gal, 2.50 min

• • Spin: 1.0 min

4. Rinse: 9.7 gal, 2.5 min

• • Spin: 1.0 min

5. Rinse: 9.7 gal, 2.5 min

• • Spin: 4.0 min

Total 48.5 gal, 22.0 min+fill time

Typical Prior Art 3 Cycle 18# Front Load

1. Wash: 9.7 gal, 3.5 min.

• • Spin (optional): 1.0 min

2. Rinse: 9.7 gal, 2.0 min

• • Spin: 1.0 min

3. Rinse: 9.7 gal, 2.0 min

• • Spin: 4.0 min

Total 29.1 gal, 13.5 min+fill time

Example #1 of Applicant's Method

Applicant's 2 cycle method for 18# Front Load

• • Wash: 11.0 gal, 14.0 min
  • Spin: 3.0 min
  • Rinse: 11.0 gal, 6.0 min
  • Spin: 6.0 min
  • 22 gal 29.0 min+fill time

Example #2 of Applicant's Method

(Showing, typical ranges) #18 Front loader

Wash: 8-12 gal., 8-15 min

Spin: 2-4 min

Rinse: 8-12 gal., 4-8 min

Spin: 4-8 min

16-24 gal., 18-35 min+fill time

For application to larger capacity machines for water reduction scale water requirements about 80% of the multiple from 18#. For example, a 36# front loaded should be set to run a water increase for to 80% of 16-24 gal. wash range.

Thus Applicant provides a method for conserving water by the modification of the wash/rinse cycles of a typical prior art front load washing machine. These steps may comprise: (a) eliminating all wash cycles except a single wash cycle; (b) increasing the amount of water in said single wash cycle as compared to the unmodified wash cycles; (c) increasing the run time of said single wash cycle as compared to the unmodified wash cycles; (d) eliminating all rinse cycles except a single rinse cycle; (e) increasing the water in said single rinse cycle as compared to the unmodified rinse cycles; (f) increasing the run time of said single rinse cycle as compared to the unmodified rinse cycles; and (g) eliminating all other cycles except the single wash cycle and single rinse cycle.

In an alternate preferred embodiment, as set forth above, a single wash and a single rinse can be used without increasing the amount of water typically used, in the 3 or 5 cycle run That is, Applicant could run its novel single wash/single rinse with 9.7 gallons for the wash and 9.7 gallons for the rinse (see typical prior art 3 and 5 cycle 18 lb. front load, fill and wash cycle requirements input), but still get an effective wash by extending the wash time. Either embodiments may use the tilt to forward provision of Applicant's invention (which gives the illusion of more water being used) and can even be used with conventional machines using conventional wash/rinse cycles.

FIGS. 1A through 1C illustrate a manner of tilting a front loading washing machine (10) having a drum (12), a front door (14) with glass therein. Typically a washing machine is mounted so it is level to a floor (FL) (see FIG. 1C) or other horizontal mounting surface such as a pair of rails. However, Applicant provides a device and method for mounting the front loading washing machine (10) so it is tilted forward as in FIGS. 1A and 1B. The purpose of this is to satisfy a psychological need for the consumer—seeing a higher water level in the machine. Not only does the consumer see the water level in the machine, but sees it higher than it would ordinarily be if the machine were level with the same amount of water. There also may be an advantage to tilting it in that the forward tilt may generate more turbulence and thus better washing action than in a horizontal machine. However, a principle function of the forward tilt is to raise the “apparent” water level of the machine. If the water level is higher, the consumer thinks there is more water working on the clothes that the clothes will get cleaner.

FIG. 1A illustrates the manner in which Applicant's tilt forward, done typically in the range of 1°-10°, 3°-4° preferred, may be provided with a modified drain line (60). Compared to a conventional drain line, which typically is horizontal, when the machine is tilted forward, drain line (60) is provided that either maintains horizontal attitude or drops slightly, so as to ensure proper drainage. If the machine is tilted forward and the drain line is not provided with a downward trend or at least flat, then water may be trapped in the drain line. FIG. 1A also illustrates fresh hot water and fresh cold water entrance lines as are typically on a conventional washing machine. See FIG. 1C prior art for hot water/cold water intakes and conventional drain line. When modifying an existing machine, Applicant would relocate the drain line so that it is horizontal or draining slightly downward, typically making an angle of 1°-2°, with a longitudinal axis. When building a new machine, Applicant would provide for a drain line making an angle typically of 1°-10°, with the horizontal axis. The angle of tilt of the washing machine is typically between 3-4°, but may be in the range of 1-10°. The drain line should be either flat or angled 1-2° downward.

When the customer sees more water in the door glass, less water may be used, but it would appear to the customer that the water level is high, or at least ordinarily where it should be.

A number of devices may achieve Applicant's purpose. For example, in FIG. 1A, a support wedge (16) or grout is provided to substantially fill the void created by tilting the rear of the machine. The support wedge may then be attached to the floor and the rear of the machine may be attached to the angled portion of the support wedge as illustrated.

FIG. 1B illustrates the simple expedient of raising a screw jack or other adjustable mounting bolt (18), typically a pair at the rear corners of a rectangular machine so as to provide a forward tilt to the machine. Blocks or other means may also be used to raise the rear of the machine.

There are a number ways that pre-existing machines may be modified for cycling through some cycles and delaying others so as to achieve Applicant's single wash, single rinse cycle. For example, if the prior art machine is a 5-cycle machine (pre-wash, wash and 3 rinses), one may wish to set the machine to cycle through a pre-wash, delay the wash time and to cycle through two out of three of the rinses and delay the time for a third rinse cycle. One such way to achieve that is illustrated in FIGS. 2A through 2C. FIGS. 2A through 2C illustrate atypically mechanical timer (20) having a timer motor (22). A pair of timer delays (24) is provided. The timer typically would have a timer dial (26) to which one or more rapid advance relays (with magnetic switches) are provided. For example, in FIG. 2B, there are two time delay mechanisms wired to delay a wash cycle and a rinse cycle and, on the dial, Applicant provides for three rapid advance relays (with magnetic switches), to cycle through one of the wash cycles and two of the rinse cycles.

FIGS. 3A and 3B illustrate a manner of wiring a light board machine, (such as a Dexter Commercial Washer) illustrated in FIG. 3A, to achieve the same results that are achieved with the timer and relays illustrated in FIGS. 2A through 2C. FIG. 3B shows modifications to a standard five-cycle circuit illustrated in FIG. 3A. A terminal block (32) is provided that may be energized from a source of energy such as a 24 volt or 110 volt or 220 volt AC circuit. A timer (34) is provided that includes a master motor (36) (which controls valves for drain and fill, water levels, the motor driving the drum, etc.) and a slave motor or “rapid advance motor” (38) for driving the timer. A spin control safety device (40) may be provided that functions to keep the drum from spinning if the water lever1 to high.

A to F are lights on the light board and include on/off light A, pre-wash light B, wash light C, rinse light D (for first and second rinses), final rinse E and spin light F. As is seen in FIG. 3B, a time delay is provided such that pre-wash and wash lights will go on and generate a single wash cycle that will run (time delayed) to run beyond a time of the wash cycle. Relays and time delay mechanisms will also run extend time of a final rinse cycle and the spin cycle. Adding additional water to the tub is simply a matter of recalibrating water level control for more water.

FIG. 4 illustrates a typical front load wash machine 50 having a drum 12, front door 14, typically including glass therein. The drum is driven by a typical timer and control circuit 52 and is filled with water and, typically a soap solution (those soap may be added through the front door or a soap chute) through use of a typical fluid system 54. However, simple modifications by those skilled in art may provide the fluid systems and the timer and control circuits modified to deliver only to single wash and single rinse cycle (with a drain and fill cycle and, optionally a short spin cycle there between).

            Range
Washer Size (Per 2 fill cycle) (In Gallons)
(Pounds)    Min-Max
10#         6-14
18#         8-30
25#         10-42
35#         12-50
40#         14-62
50#         18-80
60#         19-98
75#         20-120
80#         22-150
90#         25-180
00#         27-200

Review of the above table indicates water range, min-max, of an alternate preferred embodiment when compared with earlier set forth ranges. An examination of the table will indicate that, in some cases, for example, 18# washer, when compared with a standard 3 cycle, will actually be within a range that may increase the water usage slightly. That is, at its most basic level, Applicant uses an extended single wash and extended single rinse cycle. This can be done with decreased water usages that still prove effective or, will prove effective when using the same or even slightly more water than traditional wash and rinse cycles. Further, the tilt forward feature can be used with or without the single wash/single rinse cycle and when the fill cycle is any amount. That said, the tilt forward feature is especially helpful when less water is used, providing, as it does, the illusion that more water is being used.

Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limited sense. Various modifications of the disclosed embodiments, as well as alternative embodiments of the inventions will become apparent to persons skilled in the art upon the reference to the description of the invention. It is, therefore, contemplated that the appended claims will cover such modifications that fall within the scope of the invention.

Claims

1. A method for conserving water by modifying the cycles of a conventional front load washing machine having wash and rinse cycles, the method comprising the steps of:

eliminating all wash cycles except a single wash cycle;

increasing the water in said single wash cycle as compared to the unmodified wash cycles;

increasing the run time of said wash cycle as compared to the unmodified wash cycles;

eliminating all rinse cycles except a single rinse cycle;

increasing the water in said single rinse cycle as compared to the unmodified rinse cycles; and

increasing the run time of the single rinse cycle as compared to the unmodified rinse cycles.

2. The method of claim 1 wherein the run time of said wash cycle is increased to a maximum run time of 15 min.

3. The method of claim 1 wherein the run time of said rinse cycle is increased to a maximum rinse time of 8 minutes.

4. The method of claim 1 wherein the run time of said wash cycle is increased to a maximum run time of 15 min. and the run time of said rinse cycle is increased to a maximum run time of 8-15 minutes.

5. The method of claim 1 wherein the increase in water in said single wash cycle is to a maximum of 12 gallons for 18# washer.

6. The method of claim 1 wherein the increase in water in said single rinse cycle is to a maximum of 12 gallons for 18# washer.

7. A front load washing machine, comprising:

a tub for receiving fabric and fluids therein;

a motor for driving the tub;

a fluid system for providing fluids to the tub and removing fluids therefrom;

a timer and control circuit for controlling the motor and the fluid systems;

wherein the timer and control circuit is set to provide a single wash cycle and a single rinse cycle.

8. The washing machine of claim 7 wherein the timer and control circuit is set to fill the tub of the wash cycle to between 8 and 12 gallons of fluid and to run the single wash cycle from 8-15.

9. The washing machine of claim 7 wherein the fluid system is capable of providing a water level in the tub of up to 12 gallons for 18# washer.

10. The washing machine of claim 7 wherein the tub is dimensioned to receive 18 pounds of fabric.

11. A method of operating a front load washing machine, the method comprising the steps of providing:

a tub for receiving soiled fabric and fluids therein;

a motor for driving the tub;

a fluid system for providing fluids to the tub and removing fluids therefrom;

a timer and control circuit for controlling the motor and the fluid systems;

wherein the timer and control circuit is set to provide a single wash cycle and a single rinse cycle;

load soiled fabric into the tub;

running the machine through a single wash cycle and single rinse cycle; and

removing the clean fabric from the machine.

12. A method of installing a front loading washing machine including the step of:

raising the rear of the washing machine such that the washing machine is tilted forward.

13. The method of claim 12 wherein the raising of the rear is sufficient to allow the water in the machine to be seen through the front door of the machine.