United StatesPatent 1 1 Kaftan 1 1 MAGNETIC WINDOW CLEANING APPARATUS WITH IMPROVED CLEANING MATERIAL [76] Inventor: John A. Kaftan, 324 N. Roosevelt,
Green Bay, Wis. 54301 [22] Filed: July 23, I973 [21] Appl. No.: 381,539
Related US. Application Data [60] Division of Ser. No. 90900, Nov. 19, 1970, Pat. No. 3,751,750, which is a continuation-in-part of Ser. No. 807,524, March 17, 1969, Pat. Nov 3,609,793.
[52] US. Cl. 15/220 A; 161/89 [51] Int. Cl. A47L l/08 [58] Field of Search 15/220, 218, 219, 220 A, 15/104.93;161/89,113; 117/21 [56] References Cited UNITED STATES PATENTS 2,908,028 10/1959 Runton 15/245 3,444,579 5/1969 Thomford 161/39 FOREIGN PATENTS OR APPLICATIONS 888,344 l/l962 United Kingdom 15/220 A ram lasts Primary Examinerllarvey C. Hornsby Assistant ExaminerJames A. Niegowski [57] ABSTRACT Master and slave units are provided and each has a one-piece, plural-polarized permanent magnet. A 10- cator is provided for holding the slave unit in position until the master unit can be brought in position opposite the slave unit. The locator is formed of magnetically-attracted material and has a suction cup for tem' porary mounting on the window. The cleaning material is formed from a layer of absorbent paper having a discontinuous layer of polyethylene thereon. By being discontinuous, portions of the paper are exposed so that it can perform its absorption function. The plastic also reduces the friction between the cleaning material and window, while each magnet has a rubber surface to provide maximum friction between it and the cleaning material. In this manner the cleaning material stays in place without an external fastener.
The cleaning material is made by spreading polyethylene chips on absorbent paper, heating the paper and chips to soften the chips, and passing the paper and chips between two rollers to press the chips into the paper to provide a discontinuous surface of plastic on the paper.
6 Claims, 12Drawing Figures Shet 1 of 3 3,922,747
U.S. Patent Dec. 2, 1975 US. Patent Dec. 2, 1975shw 2 of3 3,922,747
Sheet 3 of3 3,922,747
U.S. Patent Dec. 2, 1975 MAGNETIC WINDOW CLEANING APPARATUS WITH IMPROVED CLEANING MATERIAL CROSS-REFERENCE This is a division of application Ser. No. 90,900, filed Nov. 19, 1970; now US. Pat. No. 3,751,750; which, in turn, was a continuation-impart application of application Ser. No. 807,524, filed Mar. 17, 1969, and now US. Pat. No. 3,609,793.
BACKGROUND The invention pertains to window-cleaners and more particularly to a window cleaner which utilizes magnetic attraction.
Apparatus of this general type is useful for cleaning hard to-reach portions of a window and is particularly handy in cleaning the outside of a window from the inside. Various devices of this general type have been previously suggested; for example see US. Pat. No. 3,296,645, issued Jan. 10, 1967 to Melvin Shore. In general, prior devices have included a pair of units positioned on opposite sides of a window, and having a magnetic member in each unit to provide a magnetic circuit to hold the units contiguous to the window. In theory, the master unit could be moved over the window and the slave unit would follow.
The prior art has recognized the desirability to reduce the area of contact between the units and the win dow to reduce friction. In doing so, many moved the magnets away from the window and thereby reduced their effectiveness. It is desirable to have the magnets as close to the window as possible and still reduce the area of contact between the window and the cleaning material.
SUMMARY The present invention relates generally to cleaning apparatus, and more particularly to a magnetic window cleaning apparatus.
It is an object of the present invention to provide a magnetic window cleaning apparatus in which the cleaning material is held in position without any fastener.
Another object is to provide a magnetic window cleaning apparatus which utilizes friction to hold the cleaning material in position.
Still another object is to provide a magnetic window cleaning apparatus which includes means for reducing the friction between the cleaning material and the window.
Yet another object is to provide a magnetic window cleaning apparatus having a new cleaning material including a layer of absorbent paper and a discontinuous layer of plastic.
It is another object to provide a method of making a cleaning material as set forth in the foregoing object.
It is another object to provide a magnetic window cleaning apparatus with improved tracking characteristics.
These and other objects and advantages of the present invention will become apparent as the same becomes better understood from the following detailed description when taken in conjunction with the accompanying drawings.
DRAWING FIG. 1 is a partially exploded perspective view of a preferred embodiment of the present invention with the master unit being illustrated in its operating position adjacent one surface of the window, and the slave unit being shown on the other side of the window and generally opposite the master unit, but positioned away from the window for better illustration of its structure;
FIG. 2 is a vertical sectional view through the apparatus of FIG. 1 and illustrating the master and slave units in operative position on opposite sides of a window;
FIG. 3 is a vertical sectional view through the master and slave units and the locator and illustrating the locator temporarily holding the slave unit in position with the master being moved into operative position;
FIG. 4 is an elevation of 'the locator as seen from the window-facing side;
FIG. 5 is a bottom view of the locator;
FIG. 6 is a generally diagrammatic view of the magnetic members and illustrating the pattern of the polar- "y;
FIGS. 7 and 7A are small scale views of one magnetic member of two different embodiments and indicating the direction of tests of the tracking strength of each;
FIGS. 8 and 8A are small scale views of one magnetic member of two different embodiments and indicating the direction of tests of the tracking strength of each;
FIG. 9 is a diagrammatic view of one apparatus for making the cleaning material; and
FIG. 10 is a diagrammatic, cross-sectional view on a greatly enlarged scale through the cleaning material.
DESCRIPTION Reference is now made more particularly to the drawings wherein similar reference characters indicate the same parts throughout the several views.
The magnetic window cleaning apparatus includes a master unit, generally designated 10, and a slave unit, generally designated 12. These units are adapted to be positioned on either side of awindow 14 opposite one another.
Themaster unit 10 includes a one-piecemagnetic member 20 which is polarized in a plurality of regions as hereinafter more particularly set forth. Themagnetic member 20 is disposed in ahousing 22 to which is affixed ahandle 24 by means of a reducedneck 26. The handle, neck, and housing are advantageously molded of plastic in one or two pieces. Thehandle 24 may have alabel 27 for advertising or the like.
As thus far described, the elements of themaster unit 10 find counterparts in theslave unit 12 and the counterparts are indicated by the same numeral followed by the postscript prime Accordingly, a general description of the slave unit is deemed unnecessary. Differences, however, will be noted. First, there is no handle on the slave unit but rather the housing 22' is provided with aneye 23 through which a chain or string can be passed as a safety measure in utilizing the slave unit. Secondly, themaster unit 10 preferably has a shuntingplate 28 at the rear side ofmagnetic member 20. Thirdly, the master unit has a thin layer ofrubber 29 on its window-facing side. Its purpose will hereafter be explained. Lastly, it will be noted that the polarity of the magnetic members is generally opposite, but of identical patterns as will now be explained.
Referring to FIG. 6, there is diagrammatically illustrated themagnetic members 20 and 20'. Preferably,
these members are one-piece and are made of ferrite material. As shown in FIGS. 2 and 3, themagnetic member 20 is made of barium ferrite. Themagnetic member 20 of the slave unit can be similarly constructed and with a rubber cover, or it can be made of a rubber impregnated magnetic material. It is to be understood that these are equivalents. These materials can be permanently polarized and, as indicated, it is possible to polarize a single large sheet of material in a plurality of regions on its face to provide the preferred structure. In operation, the one-piece construction is generally self-shunting at the side away from the window and no shunting plate is required; however, the shuntingplate 28 can be used to increase the strength of the magnetic elements by eliminating stray field at the back side. One suitable commercially available material is an oriented ferrite sold under the trademark Indox 5 by Indiana General Corporation. This material may be magnetized in a magnetizing jig suitably arranged to provide the multiple polarity in the alternating pattern shown in FIG. 6. It can be seen that there are eight poles of equal size on the window-facing side of each member and 20. In this manner, the number of north and south poles are equal and this balance makes the magnet more elflcient. It can also be seen that the pattern at the window-facing side ofmagnetic member 20 is identical to that at the window-facing side of member 20f. Production is thereby simplified as only one pattern is required and one magnetizing jig can be utilized for both members. It can also be seen thatmagnetic members 20 and 20 are arranged with the eight poles in a generally triangular shape. This shape presents lines of opposite polarity along the diagonals of the members and results in improved tracking ability.
Referring now to FIGS. 7 and 7A, there will be described tests which illustrate this improved result. The tests were performed on a clean, dry, glass window of one-eighth inch thickness. The rectangular arrangement (FIG. 7A) and the triangular arrangement (FIG. 7) are identical except for the pattern of the polarity. Both sets of magnetic members are formed of oriented ceramic material 3 X 4 inches X inch in size, with /s inch polyether foam on the window-facing side thereof. A cleaning paper was used along with the fasteners described in the above-mentioned parent application. Shunting plates, of 20-gauge material, were used in both arrangements of these tests.
A master unit and slave unit of each arrangement was placed on the window with a spring gauge attached to the slave unit. The master unit was moved in each direction indicated by arrows x, y, and z, with the spring gauge on the slave unit resisting the movement. These directions represent the width, length and diagonal, respectively, of the magnetic members. Readings were taken on the spring gauge at the maximum tension when the units separated with the following results:
It can be seen that the triangular pattern (8 pole) was superior in all tests. It is believed that the balance of north and south poles aids in this result. Also, where the corners of several poles meet, there is effectively no magnetism. The rectangular pattern has four such areas, while the triangular pattern has only one such area.
In the diagonal direction z, the triangular pattern is more efficient because there are more direct lines of opposing force. In other words, there are edges of poles lying crosswise of the direction of movement. This is advantageous when the master unit is moved in a circular pattern the way windows are often cleaned.
Square units also have improved tracking ability over circular units. Referring now to FIGS. 8 and 8A, there will be described tests which illustrate this. The tests utilized A inch thick ferrite magnetic material. Two circular units were made having a 3 inch outer diameter and a /2 inch opening at the center as in FIG. 8A. Two units were made as in FIG. 8 with a dimension of 3 X 3 inches and provided with a /2 inch opening at the center to make the units as close as possible to the circular units disclosed in the above-mentioned US. Pat. No. 3,296,645. All four units were magnetized by the same fixture or jig so that they had the same pattern. All four units were provided with back plates made from 18 gauge cold rolled steel. The test was performed on a 0.090 inch thick piece of plate glass, with one magnetic member on each side of the glass. A sheet of cleaning Direction Triangular Pattern Circular Pattern x r 3.6 2.7 Y 3 .6 2.7# 2 4.2 2.7#
The triangular pattern is superior in all tests; however, in the X and Y direction the improvement appears to result directly from the greater area of material in the triangular pattern. In the Z direction, however, the triangular pattern is over more effective than the circular pattern and it is believed that the improvement results from greater efficiency of the tracking forces in the comers. The use of the triangular pattern in a rectangular unit thus gives more efficient utilization of the face area of the unit, increases the strength in the X and Y direction due to the increase in area, and increases the strength in the Z direction due to the increased tracking force along the diagonals.
This application is also particularly directed to a locator 50 (see FIGS. 3-5), a new cleaning material (best shown in FIG. 10), a method of making the cleaning material as by the apparatus of FIG. 9, and structure of the units which allows the cleaning material to be used without any fastener.
Thelocator 50 allows placement of theslave unit 12 on thewindow 14 without themaster unit 10 holding the slave unit in place. This allows use of the apparatus on windows that do not open or at the front panel of a showcase, for example.
As shown in FIGS. 3-5, thelocator 50 includes abody portion 51, and a laterally offsetneck portion 52 connected thereto by anintermediate portion 53. These portions are made of magnetically attracted material, such as steel. A plurality ofribs 54 extend outwardly from the master unit facing side of thebody 51 to prevent the master unit from coming in full contact with thebody 51. Asuction cup 55 is mounted on theneck 52 for attaching the locator to the window as shown in FIG. 3. Reinforcingribs 56 are provided on theneck 52 to stiffen the same and prevent bending when thesuction cup 55 is removed from the window.
In use, thelocator 50 is attached to awindow 14 adjacent a lower frame 14a thereof. Theslave unit 12 is positioned directly opposite the locator and preferably rests on the frame 14a. The slave unit will attract the locator and be held in position by the attraction. Themaster unit 10 is brought into position as shown in FIG. 3 directly opposite the slave unit. Thesuction cup 55 is detached and the locator slid upwardly from between the two units while the master unit assumes the position of FIG. 2. The procedure is reversed for removal of the units.
Thenew cleaning material 60 comprises a layer of absorbent paper 62 and a discontinuous layer of plastic 64 (see FIG. 10). The paper is paper toweling purchased from Scott Paper Co., Marinette, Wisconsin. The paper is about 0.005 inch thick. The plastic is preferably polyethylene chips of 35 mesh size. This works best for reducing friction at the window. One suitable type is PEP 750 sold by Union Carbide Co., Chicago, lliinois. The layer of plastic rises about 0.005 inch above the surface of the paper.
FIG. 9 illustrates one suitable apparatus for making the new cleaning material. A sheet of paper 71 is taken from a roll 72. The sheet passes overrollers 73 and 74 and then under a spreader 75 where the chips are spread on the paper at a rate of about twice the weight of the paper. This gives a coverage of about half of the surface of the paper, but when the manufacturing process is complete, somewhat less than half of the area is exposed. A visual inspection shows about three-quarter coverage by the discontinuous layer of plastic 64. The sheet 71 is then passed through an infrared oven 76 having six 1000watt units 77 therein. This melts the plastic chips. As the hot paper and plastic emerges from the oven, the plastic chips are pressed into the paper by means of rolls '78, 79 which are spaced 0.01 inch apart.Roll 78 should be allowed to get hot for this operation and the heat from the heated paper and plastic is sufficient. The cleaning material is passed over idle rollers 8i-83 for cooling and then betweenfeed rollers 84, 85. A rotary cutter 86 cuts the cleaning material to size.
As indicated above, the plastic 64 is discontinuous and this allows the paper 62 to perform its absorbent function. The plastic also reduces the friction at the window-facing side and thereby aids in the tracking function. There is also some scouring performed by the plastic chips.
Although the friction is reduced at the Window-facing side, there is no reduction at the side facing the magnetic element. Preferably the magnetic element presents a continuous face for contacting the cleaning material. Also there is either arubber layer 29 or the magnetic element is rubber impregnated as described above. This increases the friction between it and the back side of the cleaning material and thereby causes 6 the cleaning material to stay in position without any external fastener.
In the specific embodiment illustrated,housing 22 of theslave unit 12 is made of steel and also serves as a shunting plate.
It is now deemed obvious that there has been disclosed a magnetic window cleaning apparatus with an improved paper and locator.
I claim:
1. A magnetic window cleaning apparatus of the type having a pair of units adapted to be positioned on either side of a window opposite each other, each unit having a window-facing side and magnet means for attracting the opposite unit,- one unit being a master unit adapted to be moved over one side of the window, and the other unit being a slave unit adapted to follow the master unit, wherein the improvement comprises: the windowfacing side of each unit being substantially flat over its entire area; a sheet of cleaning material overlying the window-facing side of each unit and comprising a layer of absorbent paper of preselected thickness having polyethylene chips of 35 mesh size on only the windowfacing side of the paper; the polyethylene being about 0.005 inch thick and in a discontinuous layer so that about 50% of the area of the paper is exposed for its absorption function; the polyethylene providing a reduced friction between the cleaning material and the window; and the window-facing side of each unit being formed at least partly of rubber to provide a high-friction surface for engaging the paper at the back side of the cleaning material so that the cleaning material will adhere to the rubber surface without additional fastening means as the unit is moved over the window.
2. The combination ofclaim 1 wherein the thickness of the polyethylene is approximately the thickness of the paper, and the polyethylene chips have a weight about twice the weight of the paper alone.
3. A magnetic window cleaning apparatus including: a pair of units adapted to be positioned on either side of a window opposite each other; each unit having a window-facing side which is substantially planar over at least a major portion of its area; each unit having magnet means for attracting the opposite unit; one unit being a master unit adapted to be moved over one side of the window, and the other unit being a slave unit adapted to follow the master unit; a sheet of cleaning material overlying the window-facing side of each unit and comprising a layer of absorbent paper having plastic material only on the window-facing side of the paper; the plastic material being a discontinuous layer of polyethylene chips arranged so that about 50% of the area of the paper is exposed for its absorption function; and the polyethylene chips rising above the surface of the paper a distance approximating the thickness of the paper and providing a reduced friction between the cleaning material and the window.
4. The combination of claim 3 wherein the polyethylene chips have a weight about twice the weight of the paper alone.
5. The combination ofclaim 4 wherein the polyethylene chips are about a 35 mesh size.
6. The combination of claim 5 wherein the paper is about 0.005 inch thick, and the polyethylene chips rise about 0.005 inch above the surface of the paper.