Device for disengaging a suction mechanism from a lens

A device for disengaging a suction mechanism from a lens. A housing is provided that has an upper supporting rim for a lens. The device also has a gripping member that is adapted to grasp the base of the suction mechanism in a forceps-like manner. The gripping member is accommodated in the housing in such a way as to be axially movable therein. When the gripping member moves out of a starting position and away from the supporting rim, the lens is drawn against the latter and can be diengaged from the suction mechanism.

BACKGROUND OF THE INVENTION 
The present invention relates to a device for releasing or disengaging a 
suction mechanism from a lens, such as a spectacle lens. 
To hold lenses in position so that their edges can be ground, these lenses 
are held between two coaxial, rotating shaft halves. One of the two shaft 
ends is provided with an engaging piece, on or relative to which is 
mounted the base of a suction mechanism, with the aid of which one side of 
the lens is held so that the lens can be rotated via the shaft half. When 
the suction mechanism is placed upon the lens, a vacuum is generated 
within the suction mechanism so that the lens can withstand the radial 
grinding pressure. The release or disengagement of the suction mechanism 
that adheres or clings to the lens, i.e., the elimination of the vacuum of 
the suction mechanism, is cumbersome, time consuming, and is frequently 
carried out in an incompetent manner, resulting in damage to the suction 
mechanism and/or to the lens. 
It is therefore an object of the present invention to provide a device of 
the aforementioned general type that is structurally straightforward and 
can be operated without difficulty, whereby the suction mechanism and 
above all that surface of the lens upon which the suction mechanism is 
placed, remain undamaged. In addition, the device should require little 
space, and should eliminate the danger of injury or harm.

SUMMARY OF THE INVENTION 
The inventive device is characterized primarily by a housing that has an 
upper supporting rim for a lens, and by a gripping member that is adapted 
to grasp the base of the suction mechanism in a forceps-like manner, with 
the gripping member being accommodated in the housing in such a way as to 
be axially movable therein, whereby when the gripping member moves out of 
a starting position and away from the supporting rim, the lens is drawn 
against the latter and can be disengaged from the suction mechanism. 
With the inventive device, after a forceps-like displacement of the two 
half shells, a slight deformation of the resilient base of the suction 
mechanism, is effected, such base preferably being made of rubber. As a 
result of this deformation, a comparative interlocking of the base of the 
suction mechanism is achieved via a vertical pulling component of the 
device, thereby effecting the ultimate disengagement of the suction 
mechanism from the lens. This disengagement begins when the surface of the 
lens rests upon the rim of the housing, and is concluded during the 
further axial downward movement of the half shells that securely hold the 
base of the suction mechanism. All this occurs without the lens surface 
suffering damage or the suction mechanism becoming unusable. 
Further specific features of the present invention will be described in 
detail subsequently. 
DESCRIPTION OF PREFERRED EMBODIMENTS 
Referring now to the drawings in detail, the inventive device has a 
ring-like base 1 that is provided at the side with a support arm or 
bracket 2 that imparts the necessary stability to the device during its 
operation. The ring 1 has a central hole 3 with an inner surface 4. The 
ring-like base part 1 is connected via screws 5 with the wider lower 
portion 6 of a bushing or sleeve 7 that is surrounded by a cylindrical 
housing 8. The upper portion 8a of the housing extends over the upper end 
of the sleeve 7, and the lower portion of the housing 8 is provided with a 
slot 38. 
The upper rim of the housing 8 can be provided with a flexible ring 9 upon 
which the outer surface O of the lens B rests, as will be described 
subsequently. 
The sleeve 7, different views of which are illustrated in FIGS. 3 and 4, is 
provided with two vertical, coaxial slots 10, as well as two coaxial 
transverse bores 11 that are disposed in the lower part of the sleeve 7 
below the slots 10. Finally, one side of the sleeve 7 is provided with a 
wide elongated slot 13 that begins approximately at the level of the 
middle of the slots 10 and extends to the bottom 12 of the sleeve. 
The sleeve 7 accommodates the two half shells 14, 15, with the periphery 
14a of the half shell 14, as well as the periphery 15a of the other half 
shell 15, both forming an incomplete semicircle. As can be seen from FIG. 
9, in their starting position the two half shells 14, 15 allow a clearance 
Z of a magnitude of "a" to be formed, with the magnitude of this clearance 
being reduced upon actuation of the movable parts of the device, as will 
be described subsequently. In this starting position, the two faces 14b 
and 15b of the half shells 14, 15 are spaced from one another by the 
magnitude "a" and together form a cylinder, with the outer peripheries 
14a, 15a resting against the inner wall 16 of the upper portion 8a of the 
housing 8. 
The two half shells 14, 15 form a forceps-like gripping member for the base 
17 of the resiliently deformable suction mechanism S, which sticks or 
adheres to the surface O of the lens B. The base 17 of the suction 
mechanism S has a cylindrical configuration and is provided with an 
annular circumferential surface 18. In their starting position, the two 
half shells 14, 15 are opened in such a way that the base 17 of the 
suction mechanism S can be inserted into the two upper recessed portions 
19, 20 of the two half shells 14, 15. Each of these recessed portions 19, 
20 has an inclined wall 21 and a horizontal bottom 22. As a result, 
between the peripheral surface 18 of the base 17 and the inclined walls 21 
of the two half shells 14, 15 there is formed a space 23 that widens 
toward the bottom and that has a triangular cross-sectional shape. When 
the two half shells 14, 15 are pressed together, accompanied by reduction 
of the clearance Z between the two faces 14b, 15b of the half shells, the 
base 17 of the suction mechanism S deforms conically in the space 23 (see 
FIG. 10), as a result of which a coupling and interlocking of the base 17 
in the recessed portions 19, 20 of the half shells is achieved. 
The half shell 14 is provided with two extensions 27 that proceed from the 
faces 14b of the half shell and have coaxial holes 28. the extensions 27 
are curved and are disposed in the continuation of the curved surface of 
the half shell 14. The other half shell 15 is provided with two lower, 
tang-like extensions 29 that are offset inwardly relatively to the wall of 
the half shell 14, i.e. toward the central axis M of the device (see FIGS. 
6 and 9). The extensions 29 of the half shell 15 are embodied in such a 
way that they can be embraced by the two extensions 27 of the half shell 
14. In this way, it is possible to insert a pivot pin 30 through the holes 
28 of the extensions 27 and through the holes 31 of the extensions 29. The 
ends of the pivot bolt 30 can slide and be guided upwardly and downwardly, 
in the direction of the arrow P, in the two slots 10 of the sleeve 7. 
The pivot pin or bolt 30 also passes through the hole 32 of a link member 
33 that is pivotably mounted on the pin 30 between the tang-like 
extensions 29 of the half shell 15; the link member 33 is also provided 
with a lower hole 34. 
The movable parts of the inventive device are adjusted via a lever 36 that 
can be moved about a pin 37 in the direction of the arrow K (FIG. 9) in 
the elongated slot 13 of the sleeve 7 and in the slot 38 of the housing 8, 
with the slots 38 and 13 being aligned with one another. The lever 36 is 
provided with a prong-like end portion 39 that has holes 40 in both prong 
parts, with the pin 37 extending through these holes 40; the ends of the 
pin 37 are held in the coaxial bores 11 of the sleeve 7. The prong parts 
of the portion 39 of the actuating lever 36 are furthermore provided with 
coaxial holes 41 through which is inserted a further pivot pin 42, the 
length of which corresponds to the width of the portion 39, in which the 
pin 42 ends. The link member 33 extends between the two prong parts of the 
lever 36 and is pivotably connected by the pin 42 to the lever 36 in the 
manner of a knee lever joint. 
In order to hold the actuating lever 36 in the starting position that is 
illustrated in FIG. 9, a spring 43 is looped around the pin 37 between the 
two prong parts of the end portion 39. One end 44 of the spring 43 rests 
against the inner wall 4 of the hole 3 of the ring-like base or bracket 2, 
while the other end 45 of the spring 43 rests in a transverse recess 46 of 
the end portion 39 of the lever 36. As a result, a force is exerted upon 
the actuating lever 36 in the direction of the arrow L, and the two half 
shells 14, 15 are pressed upwardly via the link member 33 into the 
position illustrated in FIG. 9, so that the base 17 of the suction 
mechanism S is introduced into or removed from the recessed portions 19, 
20 of the two half shells 14, 15. 
If the actuating lever 36 is pivoted in the direction of the arrow K about 
the pin 37, the ends of which are mounted in the bores 11 of the 
stationary sleeve 7, the end portion 39 of the lever 36 pulls the link 
member 33 downwardly into a position that is more inclined than is the 
starting position. In so doing, the center line F of the link member 33 
now forms an angle .beta. with the horizontal (see FIG. 10). This angle 
.beta. is less than the angle .alpha. that the center line F forms with 
the horizontal in the starting position of the components as illustrated 
in FIG. 9. Since the link member 33 is securely connected with the second 
half shell 15, the latter pivots about the pin 30 into the inclined 
position 15' shown in FIG. 10. In so doing, the clearance Z is reduced 
and, as indicated, the base 17 of the suction mechanism S is deformed and 
tightly held. However, along with the movement of the link member 33 via 
actuation of the lever 36, the pivot pin 30 is also pulled downwardly out 
of the position shown in FIG. 9 into the position 30' shown in FIG. 10, 
with the ends of the pivot pin 30 being guided in the slot 10. As a 
result, a vertical downward movement of the two half shell members 14, 15 
into their position 14', 15' occurs, with the two half shells securely 
encircling the base 17 of the suction mechanism S and deforming this base 
17 in the space 23. During this downward movement of the two half shells 
14, 15, the surface O of the lens B comes to rest against the ring 9 that 
is disposed on the upper rim of the housing 8. If the pivot lever 36 is 
pressed down still further, a pulling force is exerted in the direction of 
the arrow W (FIG. 10), as a result of which the already deformed suction 
mechanism S is pulled from the surface O of the lens B without either the 
suction mechanism itself or the surface O of the lens B suffering any 
damage. If the suction mechanism S is disengaged from the lens B in this 
manner, the lever 36 can be released and the spring 43 will take care of 
returning the movable parts of the device to the starting position. 
Since the inventive device can also be used for suction mechanism where the 
base is not deformable in the manner described in connection with the base 
17 of the suction mechanism S, but rather is, for example, completely or 
predominantly made of metal, the pivotable half shell 15 is connected in a 
special way to the lever 36. This lever 36 must also be capable of being 
pivoted downwardly in the direction of the arrow K even when the half 
shell 15 approximately maintains its starting position, i.e. can be 
pivoted only to such an extent that the upper rim 21a of the inclined wall 
21 of the recessed portion 20 (see FIGS. 5 and 9) rests snugly and 
securely against the nondeformable base of the suction mechanism. 
Thereafter, the lever 36 must be capable of being pivoted further in order 
to effect the downward movement of the two half shells 14, 15. For this 
purpose, the pivotable half shell 15 is connected to the link member 33 
via a spring 50, the one end 51 of which extends into the two holes 52 of 
the half shell 15, while the other spring end 51a is disposed about the 
pivot pin 42 (FIG. 9). The spring 50, which preferably comprises two 
parallel pieces, is of such a strength that at first the aforementioned 
pressure of the half shell 15 against the rigid base of the suction 
mechanism results, prior to the downward movement of the half shells 14, 
15 being initiated. 
The walls 21 of the recessed portions 19, 20 of the half shells 14, 15 can 
also be provided with grooving or similar means, either alone or in 
conjunction with the described inclination, in order to reliably take 
along the base 17 of the suction mechanism S when the half shells 14, 15, 
and hence the base 17, are pulled downwardly. 
The housing 8 and the sleeve 7 are interconnected via a screw connection 54 
(see FIGS. 9 and 10). 
The present invention is, of course, in no way restricted to the specific 
disclosure of the specification and drawings, but also encompasses any 
modifications within the scope of the appended claims.