Ferrofluid sealing device

Information

  • Patent Grant
  • 6305694
  • Patent Number
    6,305,694
  • Date Filed
    Monday, November 22, 1999
    25 years ago
  • Date Issued
    Tuesday, October 23, 2001
    23 years ago
Abstract
A ferrofluid sealing device retaining a ferrofluid between a shaft and a pair of inner and outer pole pieces rotating in opposite directions, in which grooves are formed on a shaft surface that faces the inner diameter surfaces of pole pieces. In the sealing device, one of the pole pieces may be made thicker than the other and further a projection portion can be formed on the shaft surface facing the inner peripheral faces of the pole pieces. The sealing device can prevent, even when the ferrofluid seal is operated at a higher rotation speed, splashing of ferrofluid over the surroundings, thereby avoiding staining the surroundings as well as prolonging its lifetime.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to improvement of a ferrofluid sealing device for use in, e.g., a spindle motor that drives a magnetic recording medium utilized in the information industry.




2. Description of the Prior Art




A conventional ferrofluid sealing device is constructed as shown in FIG.


7


. That is, a pair of pole pieces


1


,


2


made of magnetic bodies, each having a shape of a doughnut-like disk, sandwiched between their inner surfaces is a magnet


3


shaped into a doughnut-like disk and having an inner diameter larger than that of either of the pole pieces; the outer peripheral faces thereof are fixed to a housing


6


; a shaft


7


made of a magnetic body is inserted to the center holes of the doughnut-like pole pieces; and a ferrofluid (a magnetic fluid)


5


is retained, by a magnetic circuit formed by the magnet


3


, in a gap between this shaft


7


and a front end surface


4


of the outer pole piece


1


facing the shaft and located on the side where the ferrofluid is retained. Reference numeral


8


denotes a ball bearing.




In the ferrofluid sealing device described above, not all of the magnetic flux generated by the magnet


3


can flow from the pole pieces


1


,


2


to the shaft


7


. Some of the magnetic flux leaks when it flows from the vicinity of the inner diameters of the pole pieces


1


,


2


to the shaft


7


, causing the ferrofluid


5


, which is injected to and retained in the gap between the shaft and the pole pieces


1


,


2


, to have a shape bulging axially from the shaft toward the pole piece


1


. The bulging ferrofluid splashes outward upon high-speed rotation of the seal device, which brings about inconveniences such as shortened lifetime due to reduction in amount of the ferrofluid


5


, or stained surroundings due to the ferrofluid


5


flowing out onto the outer surface of the pole piece


1


.




SUMMARY OF THE INVENTION




The present invention solves such problems encountered in the prior art, and provides a high-speed rotation ferrofluid sealing device that can prevent, even when the ferrofluid seal is operated at a higher rotation speed, splashing of ferrofluid over the surroundings, thereby avoiding staining the surroundings as well as prolonging its lifetime.




A first aspect of the present invention is a ferrofluid sealing device retaining a ferrofluid between a shaft and inner and outer pole pieces rotating in opposite directions, wherein grooves are formed on a shaft surface that faces inner diameter surfaces of the pole pieces.




In the above sealing device, the grooves are preferably formed at an outer position shortly from a front end of the outer pole piece on the side where the ferrofluid is retained, and at an inner position shortly from the front end of the outer pole piece; and a projection portion wider than the thickness of an end surface of the outer pole piece is formed between the grooves. More specifically, the grooves formed on the shaft surface are effective when located at a position about 0.05 mm high from the upper surface of the outer pole piece and at a position about 0.05 mm below the lower surface of the outer pole piece. Providing these grooves can cut down the leakage of magnetic flux toward the outer surface side of the outer pole piece, as well as heighten the density of the magnetic flux in a gap between the shaft and the pole piece. Therefore, the ferrofluid does not splash even in high-speed rotation, showing enough sealing effect.




A second aspect of the present invention is a ferrofluid sealing device retaining a ferrofluid between a shaft and inner and outer pole pieces rotating in opposite directions, wherein the outer pole piece on the side where the ferrofluid is retained is 1.5 to 18.0 times as thick as the opposite inner pole piece.




The outer pole piece may be thicker than the opposite inner pole piece along its full length, or only at the inner circumferential portion beyond a stepped portion for supporting a magnet. The stepped portion may be formed on both the inside and outside the outer pole piece or only on the inside.




Thus, making the outer pole piece thicker can increase the magnetic flux and suppress the leakage of magnetic flux toward the outer surface side, presenting an effect equal to that of the formation of the grooves describedabove. The range between 1.5 times and 18.0 times is determined as a result of many tests. Also, the contact area between the ferrofluid and the pole piece is increased, so that the resistance value is lowered improving ground effect for grounding static electricity.




A third aspect of the present invention is a ferrofluid sealing device retaining a ferrofluid between a shaft and inner and outer pole pieces rotating in opposite directions, wherein grooves are formed on a shaft surface that faces inner diameter surfaces of the pole pieces, and the outer pole piece on the side where the ferrofluid is retained is 1.5 to 18.0 times as thick as the opposite inner pole piece.




Employing together the structures of the first and second aspects above makes it possible to further cut down the leakage of magnetic flux and, accordingly, show the above effect.




A fourth aspect of the present invention is a ferrofluid sealing device retaining a ferrofluid between a shaft and inner and outer pole pieces rotating in opposite directions, wherein the outer pole piece on the side where the ferrofluid is retained is 1.5 to 18.0 times as thick as the inner pole piece, and a projection portion with a width narrower than the thickness of the outer pole piece on the side where the ferrofluid side is retained is formed on a shaft surface that faces an inner diameter surface of the outer pole piece.




The magnetic flux density in a gap between the pole pieces and the shaft can be heightened also with such a structure. Thus, the ferrofluid does not splash even in high-speed rotation, showing enough sealing effect.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a sectional view of the main part according to Embodiment


1


of the present invention.





FIG. 2

is a sectional view of the main part according to Embodiment


2


of the present invention.





FIG. 3

is a sectional view of the main part according to Embodiment


3


of the present invention.





FIG. 4

is a sectional view of the main part according to embodiment


4


of the present invention.





FIG. 5

is a sectional view of the main part according to embodiment


5


of the present invention.





FIG. 6

is a sectional view of the main part according to embodiment


6


of the present invention.





FIG. 7

is a sectional view of the main part according to a conventional example.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




Embodiment modes of the present invention are described with reference to the drawings.





FIG. 1

shows an example of the invention the basic structure of which is the same as the one in

FIG. 7

described in the Prior Art. Therefore, parts having the same names as in

FIG. 7

are denoted by the same reference numerals. Two grooves


9


,


9


each having a depth of about 0.05 mm are formed on a surface of a shaft


7


which faces an outer pole piece


1


and an inner pole piece


2


: one is at a position about 0.05 mm high from the upper surface of the outer pole piece


1


, and the other is about 0.05 mm below the lower surface of the outer pole piece


1


. This can cut down the leakage of magnetic flux upward the outer pole piece


1


in the drawing, as well as heighten the magnetic flux density in a gap between the outer pole piece


1


and the shaft


7


.




In

FIGS. 2 and 3

, the thickness of the outer pole piece


1


on the upper side in the drawing is thicker than that of the inner pole piece


2


on the lower side. For instance, the outer pole piece has a thickness of 0.15 to 1.8 mm while the inner pole piece thickness is 0.1 mm. In the case of

FIG. 2

, the thickness is increased throughout the entire length of the pole piece


1


. On the other hand, in the case of

FIG. 3

, the thickness is increased only at the front end portion beyond a stepped portion for supporting a magnet


3


. The leakage of magnetic flux upward in the drawing can be cut down in either case.




In

FIGS. 4 and 5

, the structures of

FIGS. 2 and 3

are employed, respectively, together with the grooves


9


in FIG.


1


.




In

FIG. 6

, a projection portion


10


with a width narrower than the thickness of a front end portion


4


of the outer pole piece


1


is formed on the shaft side. The leakage of magnetic flux upward in the drawing can be cut down in either case.




By forming the grooves in the shaft, according to the above-mentioned first aspect, or by making one of the pole pieces thicker than the other, according to the second aspect, or by combining the structures in the first aspect and the second aspect, according to the third aspect, or by forming the projection portion. On the shaft, according to the fourth aspect, the magnetic flux generated by the magnet can be controlled. This prevents the leakage of magnetic flux, diminishes the axial bulging of the ferrofluid, and avoids outward splashing of the fluid to show enough sealing effect, preventing staining the surroundings and prolonging the lifetime. In addition, the contact area between the ferrofluid and the pole pieces is increased to improve ground effect for grounding static electricity.



Claims
  • 1. A ferrofluid sealing device retaining a ferrofluid between a shaft and inner and outer pole pieces rotating in opposite directions, wherein grooves are formed on a shaft surface that faces inner diameter surfaces of the pole pieces, and the outer pole piece on the side where the ferrofluid is retained is 1.5 to 18.0 times as thick as the inner pole piece, wherein the grooves are formed at an outer position adjacent a front end of the outer pole piece on a side where the ferrofluid is retained and an inner position adjacent the front end of the outer pole piece and a projection portion, which is wider than the thickness of an end surface of the outer pole piece, is formed between the grooves.
  • 2. A ferrofluid sealing device which retains a ferrofluid between a shaft and inner and outer pole pieces rotating in opposite direction, wherein grooves are formed on a shaft surface that faces inner diameter surfaces of the pole pieces at an outer position adjacent a front end of the outer pole piece on a side where the ferrofluid is retained and an inner position adjacent front end of the outer pole piece and a projection portion, which is wider than the thickness of an end surface of the outer pole piece, is formed between the grooves.
Priority Claims (1)
Number Date Country Kind
10-009341 Nov 1998 JP
US Referenced Citations (9)
Number Name Date Kind
4357022 Raj Nov 1982
4357024 Raj Nov 1982
4386784 Banks Jun 1983
4407518 Moskowitz et al. Oct 1983
4445696 Raj et al. May 1984
4630943 Stahl et al. Dec 1986
5108198 Nii et al. Apr 1992
5165701 Koba Nov 1992
5876037 Ishizaki et al. Mar 1999
Foreign Referenced Citations (5)
Number Date Country
2087988 Jun 1982 GB
1-220777 Sep 1989 JP
7-310746 Nov 1995 JP
10-89490 Apr 1998 JP
63-180774 Jul 1998 JP