Abstract:
A magnetizing fluid dispenser that allows the beverage to flow through a magnetic field in order to change the tastes or textures of the wine, spirit, and other beverages is provided. The magnetizing dispenser includes a spout and a magnet. The spout is sized and shaped to allow fluid inside the container to be poured out through a predefined path in the spout. The magnet is capable of generating a magnetic field. When the fluid is poured out, it passes through the magnetic field. The relative position of the spout and the magnet is adjustable.

Description:
CROSS REFERENCE TO RELATED APPLICATION 
       [0001]    This application claims priority from U.S. Provisional Application Ser. No. 60/623,225, filed Nov. 1, 2004, which is herein incorporated by reference. 
     
    
     FIELD OF THE INVENTION 
       [0002]    The present invention relates to a magnetizing device. In particular, the present invention relates to a magnetizing dispenser for wine, spirit or beverage containers, such as bottles, pots, etc. 
       BACKGROUND OF THE INVENTION 
       [0003]    It is known that many alcoholic beverages are aged in wood barrels or have wood or wood chips added to the product for a time to allow the characteristics of the wood to enhance the organoleptic properties of the beverage including flavor and odor. 
         [0004]    Tannins are the harsh, bitter, astringent, dry tasting substances, imparted by grape skins, seeds, stems and or the use of wood barrels, strips or chips, which allow wines to age and or impart a variety of different taste characteristics to wines and other alcoholic beverages. In wine these tannins will dissipate over the years and thus in general an older wine will have a softer, smoother and fruitier taste than it did as a young wine. In spirits, tannins are generally derived from a variety of new and used wood barrels, in which the spirits are allowed to aged for a period of time, in order to impart the finished product with a variety of taste finishes. 
         [0005]    When these alcoholic products are released to the public they generally have not been given enough time to age and reach their full maturity and flavor, through the use of climate controlled wine and spirits cellars, before they are released to the public. The additional expense to the manufacturer of cellaring a product for additional years, until it reached its optimum maturity, would add considerable cost to the finished product. The general public generally consumes these products before they are at their best. 
         [0006]    The use of magnets minimizes the effect of acids and tannins. Exposing alcoholic beverages to a magnetic field of a particular orientation at the time of serving the beverages is therefore desired. 
         [0007]    In coffee, tea and some fruit juices, such exposure to a magnetic field can reduce the perceived taste of acidity. 
       SUMMARY OF THE INVENTION 
       [0008]    A magnetizing fluid dispenser that allows the beverage to flow through a magnetic field in order to change the tastes or textures of the wine, spirit, and other beverages is provided. In one aspect, the magnetizing dispenser includes a spout and a magnet. The spout is sized and shaped to allow fluid inside the container to be poured out through a predefined path in the spout. The magnet is capable of generating a magnetic field. When the fluid is poured out, it passes through the magnetic field. The relative position of the, spout and the magnet is adjustable. When pouring the fluid out of the container, the magnetic field can cut through an interface between the fluid being poured out and air at an adjustable angle. The dispenser can therefore change the original flavor of the beverage to different flavors. 
         [0009]    In one embodiment, the magnet and the spout are rotatable with respect to each other. The magnet can have a donut shape with a cavity. When the fluid is poured out, the fluid passes through the cavity of the magnet. 
         [0010]    A base mount can be included in the magnetizing dispenser. The magnet can be fixedly embedded in the base mount. The relative position of the base mount and the spout is therefore adjustable. The base mount can have an end adapted to engage with the mouth of the container. The base mount can include a dial surface with a plurality of indicia provided thereon and the spout can be provided with a pointer pointing at one of said plurality of indicia. The dial surface on the base mount can be a clock style. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0011]      FIG. 1  is a view of an embodiment of a bottle and a magnetizing dispenser with an adjustable spout. 
           [0012]      FIG. 2   a  is an exploded view of the magnetizing dispenser of  FIG. 1 . 
           [0013]      FIG. 2   b  is a perspective view a magnet in the magnetizing dispenser of  FIG. 2   a.    
           [0014]      FIG. 3   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing at 9 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0015]      FIG. 3   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 3   a.    
           [0016]      FIG. 3   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 3   a  showing fluid being poured out. 
           [0017]      FIG. 3   d  is a top view of the magnet of  FIG. 3   b.    
           [0018]      FIG. 3   e  is a top view of the magnet of  FIG. 3   b  showing a level of the fluid when being poured out. 
           [0019]      FIG. 4   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing between 9 and 12 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0020]      FIG. 4   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 4   a.    
           [0021]      FIG. 4   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 4   a  showing fluid being poured out. 
           [0022]      FIG. 4   d  is a top view of the magnet of  FIG. 4   b.    
           [0023]      FIG. 4   e  is a top view of the magnet of  FIG. 4   b  showing a level of the fluid when being poured out. 
           [0024]      FIG. 5   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing at 12 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0025]      FIG. 5   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 5   a.    
           [0026]      FIG. 5   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 5   a  showing fluid being poured out. 
           [0027]      FIG. 5   d  is a top view of the magnet of  FIG. 5   b.    
           [0028]      FIG. 5   e  is a top view of the magnet of  FIG. 5   b  showing a level of the fluid when being poured out. 
           [0029]      FIG. 6   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing between 12 and 3 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0030]      FIG. 6   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 4   a.    
           [0031]      FIG. 6   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 5   a  showing fluid being poured out. 
           [0032]      FIG. 6   d  is a top view of the magnet of  FIG. 6   b.    
           [0033]      FIG. 6   e  is a top view of the magnet of  FIG. 6   b  showing a level of the fluid when being poured out. 
           [0034]      FIG. 7   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing at 3 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0035]      FIG. 7   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 7   a.    
           [0036]      FIG. 7   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 7   a  showing fluid being poured out. 
           [0037]      FIG. 7   d  is a top view of the magnet of  FIG. 7   b.    
           [0038]      FIG. 7   e  is a top view of the magnet of  FIG. 7   b  showing a level of the fluid when being poured out. 
           [0039]      FIG. 8   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing between 3 and 6 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0040]      FIG. 8   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 8   a.    
           [0041]      FIG. 8   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 8   a  showing fluid being poured out. 
           [0042]      FIG. 8   d  is a top view of the magnet of  FIG. 8   b.    
           [0043]      FIG. 8   e  is a top view of the magnet of  FIG. 8   b  showing a level of the fluid when being poured out. 
           [0044]      FIG. 9   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing at 6 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0045]      FIG. 9   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 9   a.    
           [0046]      FIG. 9   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 9   a  showing fluid being poured out. 
           [0047]      FIG. 9   d  is a top view of the magnet of  FIG. 9   b.    
           [0048]      FIG. 9   e  is a top view of the magnet of  FIG. 9   b  showing a level of the fluid when being poured out. 
           [0049]      FIG. 10   a  is a view of the magnetizing dispenser of  FIG. 2   a  with its pointer pointing between 6 and 9 O&#39;clock of its scale and positioning upward when pouring the fluid out of the bottle. 
           [0050]      FIG. 10   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 10   a.    
           [0051]      FIG. 10   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 10   a  showing fluid being poured out. 
           [0052]      FIG. 10   d  is a top view of the magnet of  FIG. 10   b.    
           [0053]      FIG. 10   e  is a top view of the magnet of  FIG. 10   b  showing a level of the fluid when being poured out. 
           [0054]      FIG. 11   a  is a view of another embodiment of a magnetizing dispenser with an adjustable spout. 
           [0055]      FIG. 11   b  is a perspective view of the magnets of the magnetizing dispenser of  FIG. 11   a.    
           [0056]      FIG. 12   a  is a view of the magnetizing dispenser of  FIG. 11   a  with its pointer pointing at 12 O&#39;clock position of its scale. 
           [0057]      FIG. 12   b  is a perspective view of the magnets in the magnetizing dispenser of  FIG. 12   b.    
           [0058]      FIG. 13   a  is a front/cross-sectional view of a magnetizing dispenser of  FIG. 3   a.    
           [0059]      FIG. 13   b  is a perspective view of the magnet of the magnetizing dispenser of  FIG. 13   a.    
           [0060]      FIG. 14   a  is a front/cross-sectional view of a magnetizing dispenser of  FIG. 11   a.    
           [0061]      FIG. 14   b  is a perspective view of the magnet of the magnetizing dispenser of  FIG. 14   a.    
           [0062]      FIG. 15  is a view of another embodiment of a bottle and a magnetizing dispenser with a fixed spout. 
           [0063]      FIG. 16   a  is a view of the magnetizing dispenser of  FIG. 15  with the scale&#39;s 9 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0064]      FIG. 16   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 16   a.    
           [0065]      FIG. 16   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 16   a  showing fluid being poured out. 
           [0066]      FIG. 16   d  is a top view of the magnet of  FIG. 16   b.    
           [0067]      FIG. 16   e  is a top view of the magnet of  FIG. 16   b  showing a level of the fluid when being poured out. 
           [0068]      FIG. 17   a  is a view of the magnetizing dispenser of  FIG. 15  with a point of the scale between the 9 and 12 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0069]      FIG. 17   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 17   a.    
           [0070]      FIG. 17   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 17   a  showing fluid being poured out. 
           [0071]      FIG. 17   d  is a top view of the magnet of  FIG. 17   b.    
           [0072]      FIG. 17   e  is a top view of the magnet of  FIG. 17   b  showing a level of the fluid when being poured out. 
           [0073]      FIG. 18   a  is a view of the magnetizing dispenser of  FIG. 15  with the scale&#39;s 12 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0074]      FIG. 18   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 18   a.    
           [0075]      FIG. 18   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 18   a  showing fluid being poured out. 
           [0076]      FIG. 18   d  is a top view of the magnet of  FIG. 18   b.    
           [0077]      FIG. 18   e  is a top view of the magnet of  FIG. 18   b  showing a level of the fluid when being poured out. 
           [0078]      FIG. 19   a  is a view of the magnetizing dispenser of  FIG. 15  with a point of the scale between the 12 and 3 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0079]      FIG. 19   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 19   a.    
           [0080]      FIG. 19   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 19   a  showing fluid being poured out. 
           [0081]      FIG. 19   d  is a top view of the magnet of  FIG. 19   b.    
           [0082]      FIG. 19   e  is a top view of the magnet of  FIG. 19   b  showing a level of the fluid when being poured out. 
           [0083]      FIG. 20   a  is a view of the magnetizing dispenser of  FIG. 15  with the scale&#39;s 3 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0084]      FIG. 20   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 20   a.    
           [0085]      FIG. 20   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 20   a  showing fluid being poured out. 
           [0086]      FIG. 20   d  is a top view of the magnet of  FIG. 20   b.    
           [0087]      FIG. 20   e  is a top view of the magnet of  FIG. 20   b  showing a level of the fluid when being poured out. 
           [0088]      FIG. 21   a  is a view of the magnetizing dispenser of  FIG. 15  with a point of the scale between the 3 and 6 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0089]      FIG. 21   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 21   a.    
           [0090]      FIG. 21   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 21   a  showing fluid being poured out. 
           [0091]      FIG. 21   d  is a top view of the magnet of  FIG. 21   b.    
           [0092]      FIG. 21   e  is a top view of the magnet of  FIG. 21   b  showing a level of the fluid when being poured out. 
           [0093]      FIG. 22   a  is a view of the magnetizing dispenser of  FIG. 15  with the scale&#39;s 6 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0094]      FIG. 22   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 22   a.    
           [0095]      FIG. 22   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 22   a  showing fluid being poured out. 
           [0096]      FIG. 22   d  is a top view of the magnet of  FIG. 22   b.    
           [0097]      FIG. 22   e  is a top view of the magnet of  FIG. 22   b  showing a level of the fluid when being poured out. 
           [0098]      FIG. 23   a  is a view of the magnetizing dispenser of  FIG. 15  with a point of the scale between the 6 and 9 O&#39;clock positioned upward when pouring the fluid out of the bottle. 
           [0099]      FIG. 23   b  is a perspective view of the magnet in the magnetizing dispenser of  FIG. 23   a.    
           [0100]      FIG. 23   c  is a cross-sectional view of the magnetizing dispenser of  FIG. 23   a  showing fluid being poured out. 
           [0101]      FIG. 23   d  is a top view of the magnet of  FIG. 23   b.    
           [0102]      FIG. 23   e  is a top view of the magnet of  FIG. 23   b  showing a level of the fluid when being poured out. 
           [0103]      FIG. 24  is a diagram showing the position of beverage in the magnetizing dispenser of  FIG. 15  at different clock position. 
           [0104]      FIG. 25   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser  FIG. 25   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 25   a.    
           [0105]      FIG. 26   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0106]      FIG. 26   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 26   a.    
           [0107]      FIG. 27   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0108]      FIG. 27   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 27   a.    
           [0109]      FIG. 28   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0110]      FIG. 28   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 28   a.    
           [0111]      FIG. 29   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0112]      FIG. 29   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 29   a.    
           [0113]      FIG. 30   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0114]      FIG. 30   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 30   a.    
           [0115]      FIG. 31   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0116]      FIG. 31   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 31   a.    
           [0117]      FIG. 32   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0118]      FIG. 32   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 32   a.    
           [0119]      FIG. 33   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0120]      FIG. 33   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 33   a.    
           [0121]      FIG. 34   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0122]      FIG. 34   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 34   a.    
           [0123]      FIG. 35   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0124]      FIG. 35   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 35   a.    
           [0125]      FIG. 36   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0126]      FIG. 36   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 36   a.    
           [0127]      FIG. 37   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0128]      FIG. 37   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 37   a.    
           [0129]      FIG. 38   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0130]      FIG. 38   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 38   a.    
           [0131]      FIG. 39   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0132]      FIG. 39   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 39   a.    
           [0133]      FIG. 40   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0134]      FIG. 40   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 40   a.    
           [0135]      FIG. 41   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0136]      FIG. 41   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 41   a.    
           [0137]      FIG. 42   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0138]      FIG. 42   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 42   a.    
           [0139]      FIG. 43   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0140]      FIG. 43   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 43   a.    
           [0141]      FIG. 44   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0142]      FIG. 44   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 44   a.    
           [0143]      FIG. 45   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0144]      FIG. 45   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 45   a.    
           [0145]      FIG. 46   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. 
           [0146]      FIG. 46   b  is an exploded view of a magnet assembly in the magnetizing dispenser of  FIG. 46   a.    
           [0147]      FIG. 47  is a longitudinal sectional view of another embodiment of the magnetizing dispenser; 
           [0148]      FIG. 48  is a longitudinal sectional view of another embodiment of the magnetizing dispenser; and 
           [0149]      FIG. 49  is a longitudinal sectional view of another embodiment of the magnetizing dispenser. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0150]    For illustration purposes, the terms “upper”, “lower”, “right”, “left”, “vertical”, “horizontal”, “top”, “bottom” appeared hereinafter relate to the invention as it is oriented in the drawings. It is understood that the invention may assume various positions, except where expressly specified to the contrary. Furthermore, it is understood that the specific devices shown in the drawings, and described in the following description, are simply exemplary embodiments of the invention. Hence, specific dimensions and other physical characteristics related to the embodiments disclosed hereinafter are not to be considered as limiting. 
         [0151]    Referring now to the drawings, in which like reference numerals represent like parts throughout the drawings,  FIG. 1  shows a bottle and a magnetizing dispenser with an end cap. The magnetizing dispenser is adapted to engage with the mouth of the bottle. The end cap is adapted to cover the opening end of the magnetizing dispenser. 
         [0152]    For illustration purposes, the bottle is of a particular shape for a particular kind of beverage. However, it is appreciated that the magnetizing dispenser of can be used in association with many other kinds of containers for a large variety of beverages, such as wine, spirit, beer, coffee, tea, fruit juice, water, etc. 
         [0153]    In the illustrated embodiment, the dispenser includes an adjustable spout with a pointer, a base mount with scale on the shoulder of the base mount and a bottle insert. The insert preferably includes a rubber seal. The dispenser can be plugged into to the mouth of the bottle. Preferably, the base mount is in a rotatable relationship with respect to the spout. 
         [0154]      FIG. 2   a  shows an explode view of the magnetizing dispenser of  FIG. 1 , which includes an adjustable spout with a pointer and an insert mounted on a base mount. The base mount has a scale on its shoulder and an embedded magnet assembly. The scale in the illustrated embodiment is a clock style with 12 scales. It is to be understood that the scale can be other styles more or less than 12 scales. 
         [0155]    Upon pouring beverage, the beverage flows through the hollow tube at the center of the dispenser. The adjustable spout can be rotated clockwise or anti-clockwise so that the orientation of the magnetic field cuts through the interface between the outgoing fluid and the incoming air flowing through the tube at different angles corresponding to different positions of the pointer on the scale. 
         [0156]      FIG. 2   b  shows the perspective view of the embedded magnet in the magnetizing dispenser. In the illustrated embodiment, the magnetic field aligns between 12 o&#39;clock and 6 o&#39;clock position of the dispenser, which can be plugged into the mouth of the bottle. It is to be understood that the magnetic field may align between any other two positions, for example, between 1 o&#39;clock and 7 o&#39;clock or between 5 o&#39;clock and 11 o&#39;clock. 
         [0157]    Referring to  FIGS. 3   a - 3   e,  the adjustable spout  34  with the pointer  36  pointing at 9 o&#39;clock position of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at zero degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The spout can be adjusted clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0158]    Referring to  FIGS. 4   a - 4   e,  the adjustable spout  34  with the pointer  36  pointing between 9 and 12 o&#39;clock positions of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 45 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The spout can be rotated clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0159]    Referring to  FIGS. 5   a - 5   e,  the adjustable spout  34  with the pointer  36  pointing at 12 o&#39;clock position of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 90 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The spout can be rotated clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0160]    Referring to  FIGS. 6   a - 6   e,  the adjustable spout  34  with the pointer  36  pointing between 12 and 3 o&#39;clock positions of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 135 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The spout can be rotated clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0161]    Referring to  FIGS. 7   a - 7   e,  the adjustable spout  34  with the pointer  36  pointing at 3 o&#39;clock position of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 180 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The dispenser can be adjusted clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0162]    Referring to  FIGS. 8   a - 8   e,  the adjustable spout  34  with the pointer  36  pointing between 3 and 6 o&#39;clock positions of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 225 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The dispenser can be rotated clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0163]    Referring to  FIGS. 9   a - 9   e,  the adjustable spout  34  with the pointer  36  pointing at 6 o&#39;clock position of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 270 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The spout can be rotated clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0164]    Referring to  FIGS. 10   a - 10   e,  the adjustable spout  34  with the pointer  36  pointing between 6 and 9 o&#39;clock positions of the scale  6  and positioning upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  42  and the incoming air  46  flowing through the inner tubular cavity of the magnetizing dispenser at 315 degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. The spout can be rotated clockwise  35  or anti-clockwise with respect to the direction of flow  32  of the fluid upon pouring. 
         [0165]    Although the pointer  36  of the adjustable spout  34  points to only certain positions on the dial as shown in  FIGS. 3-10 , it is to be understood that the pointer  36  can point to any position on the dial to change the original flavor of the beverage to different flavors. 
         [0166]      FIGS. 11   a  and  12   a  are front views of another embodiment of a magnetizing dispenser with an adjustable spout. The spout can be rotated clockwise  65  or anti-clockwise with respect to the direction of flow  62  of the fluid upon pouring. The base mount of the dispenser  70  can be embedded with one or more magnets. 
         [0167]      FIGS. 11   b  and  12   b  are perspective views of the magnets of the magnetizing dispenser of  FIGS. 11   a  and  12   a,  respectively. In the illustrated embodiment, the magnetic field F 4 , F 5  cut through the interface between the outgoing fluid  72  and the incoming air  74  flowing through the inner tubular cavity of the magnetizing dispenser at a certain degree upon pouring of the fluid from the bottle. Additional magnets  80  can be embedded into the base mount of the dispenser. 
         [0168]      FIG. 13   a  is a front/cross-sectional view of a magnetizing dispenser of  FIG. 3   a  showing the internal structure of the dispenser.  FIG. 13   b  is a perspective view of the magnet of the magnetizing dispenser of  FIG. 13   a .  FIG. 14   a  is a front/cross-sectional view of a magnetizing dispenser of  FIG. 11   a  showing the internal structure of the dispenser.  FIG. 14   b  is a perspective view of the magnet of the magnetizing dispenser of  FIG. 14   a . The dispensers of  FIGS. 13   a  and  14   a  each include a cap. 
         [0169]      FIG. 15  is a view of a bottle and a magnetizing dispenser with a fixed spout in accordance with another embodiment. In the present embodiment, the magnetic field F 37  aligns between 12 o&#39;clock and 6 o&#39;clock positions of the dispenser, which can be plugged into the mouth of the bottle. It is to be understood that the magnetic field F 37  may align between any other two positions, for example, between 1 o&#39;clock and 7 o&#39;clock or between 5 o&#39;clock and 11 o&#39;clock. The scale in the illustrated embodiment is a clock style with 12 scales. It is to be understood that the scale can be other styles more or less than 12 scales. 
         [0170]    Referring to  FIGS. 16   a - 16   e,  the point at the 9 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at zero degree upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0171]    Referring to  FIGS. 17   a - 17   e,  the center point between 9 o&#39;clock and 12 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 45 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0172]    Referring to  FIGS. 18   a - 18   e,  the point at the 12 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 90 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0173]    Referring to  FIGS. 19   a - 19   e,  the center point between 12 o&#39;clock and 3 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 135 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0174]    Referring to  FIGS. 20   a - 20   e,  the point at the 3 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 180 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0175]    Referring to  FIGS. 21   a - 21   e,  the center point between 3 o&#39;clock and 6 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 225 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0176]    Referring to  FIGS. 22   a - 22   e,  the point at the 6 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 270 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0177]    Referring to  FIGS. 23   a - 23   e,  the center point between 6 o&#39;clock and 9 o&#39;clock of the fixed spout  254  is positioned upward when pouring the fluid out of the bottle. The magnetic field F 2  cuts through the interface between the outgoing fluid  262  and the incoming air  266  flowing through the inner tubular cavity of the magnetizing dispenser at 315 degrees upon pouring of the fluid from the bottle. When pouring the fluid at this position, the dispenser can change the original flavor of the beverage to a different flavor. 
         [0178]      FIG. 24  shows the orientation of the magnetic field rotating with the bottle with different scale readings pointing upward upon pouring. The magnetic field cuts the interface of the outgoing fluid  270  and incoming air  274  at different angles with respect to corresponding readings pointing upwards upon pouring. Although  FIGS. 16-23  only show eight positions of the fixed spout  254  when pouring the liquid from the bottle, it is to be understood that the fixed spout  254  can be placed at any other positions to pour the liquid to change the original flavor of the beverage to different flavors. 
         [0179]      FIG. 25   a  is a longitudinal sectional view of another embodiment of a magnetizing dispenser. The magnetizing dispenser  102  includes a generally tubular body generally represented by reference numeral  110 . The tubular body or conduit  110  defines therein a flow through opening or chamber  108 , and a central longitudinal axis X. The tubular body  110  has an upper portion  106  and a lower portion  128 . The upper portion  106  of the tubular body  110  has a slanted opening end  104 . 
         [0180]    The lower portion  128  of the tubular body  110  defines a bottle insert  126  which is adapted to be inserted into the mouth of the bottle. A generally cylindrical seal  120  may be affixed on the outer circumference of the bottle insert  126  for frictional engagement with the mouth of the bottle when the bottle insert  126  is inserted therein. The outer surface of the seal  120  may be slightly tapered towards the bottom end of the bottle insert  126  to facilitate the insertion of the bottle insert  126  into the mouth of the bottle and the sealing of the bottle. Preferably, the seal  120  can be made of rubber or any other suitable materials. 
         [0181]    A compartment, preferably an annular compartment, generally designated by reference numeral  118 , is provided on the outer circumference of the tubular body  110  proximate to the lower portion  126  thereof. According to the present embodiment, the compartment  118  is located adjacent to and above the bottle insert  126 . The compartment  118  may have a shoulder  144  and a skirt  122 . The shoulder  114  and the skirt  122  together define a cavity or recess  124  for receiving therein magnets which will be described below in detail. 
         [0182]    The tubular body  110  and the compartment  118  can be made of non-magnetic shielding material such as plastics, aluminum, copper, or any other suitable materials. 
         [0183]    According to another embodiment, the magnet assembly includes at least one magnet, namely a first magnet  112 . A second magnet  116  and additional plurality of magnets  130  can be added. Each of the two magnets  112 ,  116  is in the form of a dipole ring magnet, as depicted in  FIG. 25   b . The two ring magnets  112 ,  116  can be of the same dimensions. The two dipole ring magnets  112 ,  116  may be embedded and secured in the annular recess  124 . The two dipole ring magnets  112 ,  116  are positioned one on top of the other in such a manner that the north magnetic pole of the first magnet  112  is directly opposite to the south magnetic pole of the second magnet  116 , and that the south magnetic pole of the first magnet  112  is directly opposite to the north magnetic pole of the second magnet  116 , as best shown in  FIG. 25   a.    
         [0184]    It is instructive to note that, when the two dipole ring magnets  112 ,  116  are polarized and arranged in this fashion, the two magnets  112 ,  116  are held together due to their magnetic forces of attraction, as is well known. 
         [0185]    In the illustrated embodiment, when the two dipole ring magnets  112 ,  116  are embedded in the annular recess  124 , the inner cylindrical surfaces of the two ring magnets  112 ,  116  may be substantially flush with the inner cylindrical surface of the magnetizing dispenser. The outer cylindrical surfaces of the two ring magnets  112 ,  116  may abut against the inner cylindrical surface of the annular compartment  118 . The top surface of the top ring magnet  112  may abut against the bottom surface of the annular shoulder  114 . The bottom surface of the bottom ring magnet  116  may abut against the top end of the bottle insert  126 . 
         [0186]    The two dipole ring magnets  112 ,  116  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. The directions of the magnetic fields within the dispenser are conventionally expressed by wavy and horizontal flux paths or lines F 9 , as depicted in  FIG. 25   a.    
         [0187]    Although it has been shown that there are two dipole ring magnets  112 ,  116  in the magnetizing dispenser, it is appreciated the number and size of the ring magnets may be increased to produce a stronger magnetic field, if desired. 
         [0188]      FIGS. 26   a  and  26   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may include at least two magnets, namely a first magnet  115  and a second magnet  117 . A third magnet or more magnets may be added. Each of the two magnets  115 ,  117  takes the form of a multipole ring magnet. The two multipole ring magnets  115 ,  117  are disposed one on top of the other in such a manner that the two north magnetic poles of the first magnet  115  are directly opposite to the two south magnetic poles of the second magnet  117  respectively, and that the two south magnetic poles of the first magnet  115  are directly opposite to the two north magnetic poles of the second magnet  117  respectively. 
         [0189]    When the two multipole ring magnets  115 ,  117  are embedded in the annular recess  124 , the inner cylindrical surfaces of the two ring magnets  115 ,  117  may be substantially flush with the inner cylindrical surface of the magnetizing dispenser. 
         [0190]    The two multipole ring magnets  115 ,  117  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. The directions of the magnetic fields within the dispenser are represented by flux lines F 10 , as depicted in  FIG. 26   a.    
         [0191]      FIGS. 27   a  and  27   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may include at least two magnets, namely a first magnet  132  and a second magnet  134 . A third magnet  139  or more magnets may be added. 
         [0192]      FIGS. 28   a  and  28   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may include at least two magnets, namely a first magnet  136  and a second magnet  138 . A third magnet  140  or more magnets may be added. 
         [0193]      FIGS. 29   a  and  29   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly includes at least two magnets, namely a first magnet  142  and a second magnet  144 . A third magnet  146  or more magnets may be added. The first magnet  142  may have radial polarity with an inner south magnetic pole and a concentric outer north magnetic pole. The second magnet  144  may have radial polarity with an inner north magnetic pole and a concentric outer south magnetic pole. 
         [0194]    In use, the first ring magnet  142  may be disposed on top of the second ring magnet  144  in such a manner that the outer north magnetic pole of the first magnet  142  is directly opposite to the outer south magnetic pole of the second magnet  144 , and that the inner south magnetic pole of the first magnet  142  may be directly opposite to the inner north magnetic pole of the second magnet  144 , as best shown in  FIG. 29   a.    
         [0195]    When the two ring magnets  142 ,  144  are embedded in the annular recess  124 , the inner cylindrical surfaces of the two ring magnets  142 ,  144  may be substantially flush with the inner cylindrical surface of the magnetizing dispenser. 
         [0196]    The two ring magnets  142 ,  144  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. Wavy flux lines F 17 , as depicted in  FIG. 29   a,  express the directions of the magnetic fields within the magnetizing dispenser. 
         [0197]      FIGS. 30   a  and  30   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly includes at least two magnets, namely a first magnet  144  and a second magnet  142 . A third magnet  148  or more magnets may be added. The first magnet  144 , which is the same magnet  144  in  FIGS. 29   a  and  29   b,  has radial polarity with inner north magnetic pole and outer south magnetic pole. The second magnet  144 , which is the same magnet  142  in  FIGS. 29   a  and  29   b,  has radial polarity with inner south magnetic pole and outer north magnetic pole. 
         [0198]    The first ring magnet  144  may be disposed on top of the second ring magnet  142  in such a manner that the inner north magnetic pole of the first magnet  144  is directly opposite to the inner south magnetic pole of the second magnet  142 , and that the outer south magnetic pole of the first magnet  144  may be directly opposite to the outer north magnetic pole of the second magnet  142 , as best shown in  FIG. 30   a.    
         [0199]    When the two ring magnets  144 ,  142  are embedded in the annular recess  124 , the inner cylindrical surfaces of the two ring magnets  144 ,  142  may be substantially flush with the inner cylindrical surface of the magnetizing dispenser. 
         [0200]    The two ring magnets  144 ,  142  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. The directions of the magnetic fields within the dispenser are illustrated by flux lines F 28 , as depicted in  FIG. 30   a.    
         [0201]      FIGS. 31   a  and  31   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly includes at least two magnets, namely a first magnet  150  and a second magnet  152 . The first magnet  150  may be in the form of a rectangular dipole magnet having upper north magnetic pole and lower south magnetic pole. The second magnet  152  may be in the form of a rectangular dipole magnet having upper south magnetic pole and lower north magnetic pole. 
         [0202]    The first and second magnets  150 ,  152  having the same dimensions, may be disposed one opposite to the other within the annular recess  124  in such a manner that the upper north magnetic pole of the first magnet  150  is opposite to the upper south magnetic pole of the second magnet  152 , and that the lower south magnetic pole of the first magnet  150  is opposite to the lower north magnetic pole of the second magnet  152 , as best shown in  FIG. 31   a . The distance d between the two opposite magnets  150 ,  152  may equal to the diameter of the flow through opening  108  of the magnetizing dispenser. 
         [0203]    The two rectangular magnets  150 ,  152  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. The wavy and horizontal flux lines F 29 , as depicted in  FIG. 31   a,  express the directions of the magnetic fields within the magnetizing dispenser. 
         [0204]      FIGS. 32   a  and  32   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly includes at least two magnets, namely a first magnet  154  and a second magnet  156 . The first magnet  154  may be in the form of a rectangular dipole magnet having inner north magnetic pole and outer south magnetic pole. The second magnet  156  is in the form of a rectangular dipole magnet having inner south magnetic pole and outer north magnetic pole. 
         [0205]    The first and second magnets  154 ,  156  maybe disposed one opposite to the other within the annular recess  124  in such a manner that the inner north magnetic pole of the first magnet  154  is opposite to the inner south magnetic pole of the second magnet  156 , as best shown in  FIG. 32   a.    
         [0206]    The two magnets  154 ,  156  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. The direction of the magnetic field within the magnetizing dispenser is only horizontal and is expressed by flux lines F 20 , as depicted in  FIG. 32   a.    
         [0207]      FIGS. 33   a  and  33   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may include two cylindrical dipole magnet  170  having south magnetic pole facing the inner cavity of the conduit and a cylindrical dipole magnets  171  having north magnetic pole facing the inner cavity of the conduit. The three dipole magnets  170  and  171  may be disposed around the outer circumference of the inner cylindrical wall  172  of the conduit generally equally spaced intervals of 120 degrees. 
         [0208]    When the cylindrical magnet assembly  170  and  171  is embedded in the recess  124 , the inner cylindrical wall  172  of the conduit may be substantially flush with the inner cylindrical surface of the magnetizing dispenser. 
         [0209]    The cylindrical magnets  170  and  171  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. A plurality of wavy flux lines F 23 , as depicted in  FIG. 33   a,  represents the directions of the magnetic fields within the magnetizing dispenser. 
         [0210]      FIGS. 34   a  and  34   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may include two cylindrical dipole magnet  174  having north magnetic pole facing the inner cavity of the conduit and a cylindrical dipole magnets  175  having south magnetic pole facing the inner cavity of the conduit. The three dipole magnets  174  and  175  may be disposed around the outer circumference of the inner cylindrical wall  176  of the conduit generally equally spaced intervals of 120 degrees. 
         [0211]    When the cylindrical magnet assembly  174  and  175  are embedded in the annular recess  124 , the inner cylindrical wall  176  of the conduit may be substantially flush with the inner cylindrical surface of the magnetizing dispenser. 
         [0212]    The cylindrical magnets  174  and  175  impart magnetic fields which extend into the flow through opening  108  of the magnetizing dispenser. A plurality of wavy flux lines F 24 , as depicted in  FIG. 34   a,  represents the directions of the magnetic fields within the magnetizing dispenser. 
         [0213]    Although it has been described in the twenty third and the twenty fourth embodiments that each of the cylindrical magnets  170 ,  171 ,  174  and  175  are disposed at equally spaced intervals of 120 degrees, it is understood that each of the cylindrical magnets  170 ,  171 ,  174  and  175  may be provided with any suitable number of magnets. For example, the cylindrical magnet  170  and  171  or  174  and  175  may be provided with two circumferentially spaced magnets disposed at equally spaced intervals of 180 degrees; or the cylindrical magnets  170  and  171  or  174  and  175  may provided with four circumferentially spaced magnets disposed at equally spaced intervals of 90 degrees. 
         [0214]      FIGS. 35   a  and  35   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may be in the form of a semi-cylindrical column dipole magnet  180 , of semi-circular cross section, having south magnetic pole at the upper half thereof and north magnetic pole at the lower half thereof. 
         [0215]    The semi-cylindrical surface  182  of the semi-cylindrical magnet  180  may be abutted against and affixed to the inner cylindrical surface of the magnetizing dispenser. According to the present embodiment, the magnet  180  extends along the entire length of the annular compartment  118  and along the entire length of the bottle insert  126  in such a manner that the upper half of the magnet  180  is adjacent to the annular recess  124  and the lower half of the magnet  180  is adjacent to the bottle insert  126 . Flux lines F 25 , as depicted in  FIG. 35   a,  denote the directions of the magnetic field within the magnetizing dispenser. 
         [0216]      FIGS. 36   a  and  36   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly is the same semi-cylindrical column dipole magnet  180  in  FIGS. 35   a  and  35   b  but up side down such that the north magnetic pole is located at the upper half thereof and the south magnetic pole is located at the lower half thereof. 
         [0217]    Similarly, the semi-cylindrical surface  182  of the semi-cylindrical magnet  180  may be abutted against and affixed to the inner cylindrical surface of the magnetizing dispenser. The direction of the magnetic field within the magnetizing dispenser is denoted by flux lines F 26 , as depicted in  FIG. 36   a.    
         [0218]      FIGS. 37   a  and  37   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly can be in the form of a semi-cylindrical column multipole magnet  190 . The multipole magnet  190  has alternating polarity configurations of S-N-S, i.e. south magnetic poles at opposite ends of the magnet and a north magnetic pole between the two south magnetic poles. The total number of magnetic poles in the magnet  190  can be an odd number, i.e. three, five, and so on. 
         [0219]    The semi-cylindrical surface  192  of the semi-cylindrical magnet  190  can be abutted against and affixed to the inner cylindrical surface of the magnetizing dispenser. Flux lines F 27 , as depicted in  FIG. 37   a,  express the directions of the magnetic fields within the magnetizing dispenser. 
         [0220]      FIGS. 38   a  and  38   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly can be in the form of a semi-cylindrical column multipole magnet  190 . The multipole magnet  190  has alternating polarity configurations of N-S-N, i.e. north magnetic poles at opposite ends of the magnet and a south magnetic pole between the two north magnetic poles. The total number of magnetic poles in the magnet  190  can be an odd number, i.e. three, five, and so on. 
         [0221]    Similarly, the semi-cylindrical surface  192  of the semi-cylindrical magnet  190  can be abutted against and affixed to the inner cylindrical surface of the dispenser. The directions of the magnetic fields within the magnetizing dispenser are expressed by flux lines F 28 , as depicted in  FIG. 38   a.    
         [0222]      FIGS. 39   a  and  39   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may in the form of a semi-cylindrical column multipole magnet  200  having alternating polarity configurations S-N-S-N, as counted from top to bottom. The total number of magnetic poles in the magnet  200  may be an even number, i.e. four, six, and so on. 
         [0223]    The semi-cylindrical surface  202  of the semi-cylindrical magnet  200  may be abutted against and affixed to the inner cylindrical surface of the magnetizing dispenser. Flux lines F 29 , as depicted in  FIG. 39   a,  represent the directions of the magnetic fields within the magnetizing dispenser. 
         [0224]      FIGS. 40   a  and  40   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly is the same semi-cylindrical column multipole magnet  200  as illustrated in  FIGS. 39   a  and  39   b,  but oriented up side down with alternating polarity configurations N-S-N-S, as counted from top to bottom. Again, the total number of magnetic poles in the magnet  200  may be an even number. 
         [0225]    Similarly, the semi-cylindrical surface  202  of the semi-cylindrical magnet  200  may be abutted against and affixed to the inner cylindrical surface of the dispenser. The directions of the magnetic fields within the magnetizing dispenser are represented by flux lines F 30 , as depicted in  FIG. 40   a.    
         [0226]      FIGS. 41   a  and  41   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may be in the form of a rectangular or bar-type dipole magnet  210  having the south magnetic pole at the upper half thereof and the north magnetic pole at the lower half thereof. 
         [0227]    The magnet  210  extends along the flow through opening  108  of the magnetizing dispenser in the middle thereof. Flux lines F 31 , as depicted in  FIG. 41   a,  denote the directions of the magnetic fields within the magnetizing dispenser. 
         [0228]      FIGS. 42   a  and  42   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly is the same rectangular or bar-type dipole magnet  210  as shown in  FIGS. 41   a  and  41   b  but oriented up side down with the north magnetic pole at the upper half thereof and the south magnetic pole at the lower half thereof. 
         [0229]    Again, the magnet  210  extends along the flow through opening  108  of the magnetizing dispenser in the middle thereof. The directions of the magnetic fields within the magnetizing dispenser are conventionally expressed by flux lines F 32 . 
         [0230]      FIGS. 43   a  and  43   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may be in the form of a rectangular or bar-type multipole magnet  220  having south magnetic poles at opposite ends thereof and a north magnetic pole between the two south magnetic poles. The magnetic poles arrangement is S-N-S. The total number of magnetic poles in the magnet  220  may be an odd number, i.e. three, five, and so on. 
         [0231]    The magnet  220  extends along the flow through opening  108  of the magnetizing dispenser in the middle thereof. Flux lines F 33 , as depicted in  FIG. 43   a,  represent the directions of the magnetic fields within the magnetizing dispenser. 
         [0232]      FIGS. 44   a  and  44   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly may be in the form of a rectangular or bar-type multipole magnet  222  having north magnetic poles at opposite ends thereof and a south magnetic pole between the two north magnetic poles. The magnetic poles arrangement is N-S-N. The total number of magnetic poles in the magnet  222  may be an odd number. 
         [0233]    The magnet  222  extends along the flow through opening  108  of the magnetizing dispenser in the middle thereof. The directions of the magnetic fields within the magnetizing dispenser are expressed by flux lines F 34 . 
         [0234]      FIGS. 45   a  and  45   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly can be in the form of a rectangular or bar-type multipole magnet  230  having magnetic poles arrangement N-S-N-S, as counted from top to bottom. The total number of magnetic poles in the magnet  230  can be an even number, e.g. four, six, etc. 
         [0235]    The magnet  230  extends along the flow through opening  108  of the magnetizing dispenser as illustrated in  FIG. 45   a . Flux lines F 35  express the directions of the magnetic fields within the magnetizing dispenser. 
         [0236]      FIGS. 46   a  and  46   b  show another embodiment of the magnet assembly of the magnetizing dispenser. According to this embodiment, the magnet assembly can be the same rectangular or bar-type multipole magnet  230  as shown in  FIGS. 45   a  and  45   b  but turned up side down with magnetic poles arrangement S-N-S-N, as counted from top to bottom. Again, the total number of magnetic poles in the magnet  230  can be an even number. 
         [0237]    The magnet  230  is disposed within the flow through opening  108  of the magnetizing dispenser as illustrated in  FIG. 46   a . The directions of the magnetic fields within the magnetizing dispenser are conventionally expressed by flux lines F 36 . 
         [0238]      FIGS. 47 ,  48  and  49  are three different embodiments of the magnetizing dispenser. 
         [0239]    According to the embodiment in  FIG. 47 , the magnetizing dispenser  306  includes a tubular member  306  defining therein a flow through opening  302 . The tubular member  306  has an upper portion  280  and a lower portion  290 . The lower portion  290  of the tubular member  306  defines a bottle insert  292  which is adapted to be inserted into the mouth  249  of the bottle  250 . A generally cylindrical seal  294  is affixed on the outer circumference of the bottle insert  292  for frictional engagement with the mouth  249  of the bottle  250  when the bottle insert  292  is inserted therein. The outer circumference of the seal  294  may be slightly tapered towards the bottom end of the bottle insert  292  to facilitate the insertion of the bottle insert  292  into the mouth  249  of the bottle  250 . Preferably, the seal  294  may be made of rubber or any other suitable materials. 
         [0240]    A cap-shaped member, generally designated by reference numeral  284 , is provided on the tubular member  306  at the upper portion  280  thereof According to the present embodiment, the cap-shaped member  284  may be located adjacent to and above the bottle insert  292 . The cap-shaped member  284  may include a shoulder  300 , a skirt  286 , and a support  288 . The shoulder  300 , the skirt  286 , and the support  288  define a space  282  for receiving therein the dipole ring magnets  112 ,  116 . The support  288  is adapted to support the ring magnets  112 ,  116 . 
         [0241]    Although it has been shown that the magnetizing dispenser  246  is provided with dipole ring magnets  112 ,  116 , it is understood that the magnetizing dispenser  246  can be provided with any other magnet assembly described hereinbefore. 
         [0242]    According to the embodiment in  FIG. 48 , the magnetizing dispenser  334  includes a tubular member  330  defining therein a flow through opening  328 . The tubular member  330  has an upper portion  310  and a lower portion  318 . The lower portion  318  of the tubular member  330  defines a bottle insert  320  which is adapted to be inserted into the mouth  249  of the bottle  250 . A generally cylindrical seal  322  may be affixed on the outer circumference of the bottle insert  320  for frictional engagement with the mouth  249  of the bottle  250  when the bottle insert  320  is inserted therein. The outer circumference of the seal  322  may be slightly tapered towards the bottom end of the bottle insert  320  to facilitate the insertion of the bottle insert  320  into the mouth  249  of the bottle  250 . Preferably, the seal  322  is made of rubber or any other suitable materials. 
         [0243]    An enclosed compartment, generally designated by reference numeral  314 , maybe provided on the tubular member  330  at the upper portion  310  thereof According to the present embodiment, the enclosed compartment  314  may be located adjacent to and above the bottle insert  320 . The enclosed compartment  314  may define a space  312  for receiving therein the ring magnets  112 ,  116 . The ring magnets  112 ,  116  may be disposed in the enclosed compartment  314 . A flange  332 , identical to the flange  304  in  FIG. 47 , is provided on the magnetizing dispenser  334 . 
         [0244]    Although it has been shown that the magnetizing dispenser  334  is provided with dipole ring magnets  112 ,  116 , it is understood that the magnetizing dispenser  334  can be provided with any other magnet assembly described hereinbefore. 
         [0245]    According to the embodiment in  FIG. 49 , the magnetizing dispenser  362  may include a tubular member  358  defining therein a flow through opening  356 . The tubular member  358  has an upper portion  340  and a lower portion  346 . The lower portion  346  of the tubular member  358  defines a bottle insert  348  which is adapted to be inserted into the mouth  249  of the bottle  250 . A generally cylindrical seal  350  may be affixed on the outer circumference of the bottle insert  348  for frictional engagement with the mouth  249  of the bottle  250  when the bottle insert  348  is inserted therein. The outer circumference of the seal  350  may be slightly tapered towards the bottom end of the bottle insert  348  to facilitate the insertion of the bottle insert  348  into the mouth  249  of the bottle  250 . Preferably, the seal  350  is made of rubber or any other suitable materials. 
         [0246]    An enclosed compartment, generally designated by reference numeral  344 , may be provided on the tubular member  358  at an upper portion  340  thereof. According to the present embodiment, the enclosed compartment  344  may be located adjacent to and above the bottle insert  348 . The enclosed compartment  344  may define a space  342  for receiving therein the ring magnets  112 ,  116 . 
         [0247]    In the illustrated embodiment, the upper portion  340  of the tubular member  358  protrudes upwards from the compartment  340 . A slanted opening end  360  may be provided at the upper end of the tubular member  358 . 
         [0248]    Although it has been shown that the magnetizing dispenser  362  is provided with dipole ring magnets  112 ,  116 , it is understood that the magnetizing dispenser  362  can be provided with any other magnet assembly described above. 
         [0249]    While the present invention has been shown and described with particular references to a number of preferred embodiments thereof, it should be noted that various other changes or modifications may be made without departing from the scope of the present invention.