Classifications

• • G—PHYSICS
  • G02—OPTICS
  • G02C—SPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
  • G02C7/00—Optical parts
  • G02C7/02—Lenses; Lens systems ; Methods of designing lenses
  • G02C7/08—Auxiliary lenses; Arrangements for varying focal length
  • G02C7/081—Ophthalmic lenses with variable focal length
• • G—PHYSICS
  • G02—OPTICS
  • G02C—SPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
  • G02C7/00—Optical parts
  • G02C7/02—Lenses; Lens systems ; Methods of designing lenses
  • G02C7/08—Auxiliary lenses; Arrangements for varying focal length
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B3/00—Simple or compound lenses

Definitions

• the invention relates generally to the field of spectacles.
• the invention relates to spectacles provided with a frame and a pair of combined lenses arranged to have an adjustable focal length.
• Spectacles also called glasses or eyeglasses, are commonly in the form of a frame bearing lenses. They are worn in front of the eyes and supported on the nose and over the ears, although other designs are well-known as well. Spectacles are normally used for vision correction, eye protection, or for protection from UV rays.
• Refractive errors of the eye can be alleviated with corrective lenses, which modify the effective focal length.
• a lens defines a specific focal length depending on its characteristics (e.g. thickness, convexity/concavity).
• an ophthalmologist or optometrist In order to correct the vision of patients with refractive errors and supply them with the proper lenses, an ophthalmologist or optometrist must make a prescription of lenses according to each eye of each patient.
• WO 2006/098618 discloses spectacles provided with combined lenses where the wearer can adjust the focal length by a mechanism that moves the lenses across each other. By moving both lens elements an equal amount, the optical axis of the lens remains in the same position with respect to the spectacles frame.
• the mechanism disclosed requires at least one cam element that can interact with at least one of the lenses by direct and permanent coupling of a notch with a groove of the lens.
• This document teaches a mechanism that moves the lens elements with respect to one another but the design of the mechanism makes no provision for showing a fashionable or discrete design of spectacles to wear.
• the mechanism is also relatively big and outstanding in the design of the spectacles, making it more susceptible for dirt or particles to enter in or around the mechanism and its openings and clog certain areas in or around the mechanism. This would seriously impede the workings of the mechanism and thus the functionality of the spectacles.
• the adjustment mechanism also does not provide in more precise adjusting of the focal length of the lenses, only direct adjustment by hand motion.
• the present invention and its embodiments give a solution to one or more of the before mentioned shortcomings.
• a pair of spectacles provided with a frame and a pair of combined lenses carried by the frame, each combined lens having an adjustable focal length and comprising two lens elements arranged one behind the other along an optical axis of the combined lens, and an adjustment mechanism arranged to move the two lens elements laterally relative to one another to vary the focal length, each lens element being movable in a direction opposite to the other lens element and transverse to the optical axis of the lens elements whereby the optical axis remains substantially fixed relative to the frame.
• the adjustment mechanism comprises at least one frame-connected rotatable element engaging at least one lens element for urging a lateral movement of the at least one lens element.
• the adjustment mechanism further comprises at least one control lever pivotally connected within the frame of the spectacles for transferring a lateral movement of one lens element of the combined lens to a lateral movement of the other lens element in the opposite direction.
• the control lever may be connected to an outer edge of each lens element of a combined lens.
• the rotatable element is preferably circular, for example substantially shaped as a wheel, with an edge of the wheel engaging an edge of at least one lens element.
• a central axis of the rotatable element may be connected to the frame of the spectacles to permit rotation.
• the edge of the wheel may engage the outer edge of the lens element by friction between the touching surfaces.
• the manner in which the friction is realised can be different, for example smooth or roughened surfaces touching each other to generate sufficient friction to cause lateral movement of the lens element when the rotatable element is rotated.
• the rotatable element may include a toothed wheel which engages an edge of at least one lens element having corresponding teeth. Other rotatable elements are also possible, like a sliding element engaging the lens element at its outer edge.
• the rotatable element may comprise at least a first portion and a second portion, wherein the first portion engages the lens element and the second portion has an adjustment portion adjacent to an edge of the frame for manual adjustment of one of the combined lens.
• the second portion is used for adjustment of the leneses by hand, by turning the rotatable element.
• the first portion is used for transferring the rotation of the rotatable element to the lens element.
• the rotatable element is preferably at least partially enclosed by the frame of the spectacles.
• the rotatable element is preferably positioned within the frame so that it is virtually out of sight when looking at the spectacles from the front. This improves the appearance of the spectacles, reduces the chances that it will be unintentionally moved when no adjustment of the spectacles is intended, and protects the mechanism from dirt and moisture.
• the rotatable element is preferably positioned so that at least 75% of the rotatable element is hidden inside the frame.
• the rotatable element for each combined lens may be positioned at a bottom edge of the frame below the combined lens. This places the adjustment mechanism where it can be conveiently adjusted, for example using a thumb to rotate one or both of the rotatle elements to adjust the combined lenses.
• the control lever is preferably pivotable at its centre about a fixed point within the frame and connects with the two lens elements adjacent to its respective ends.
• the two lenses of each combined lens may be moved by equal amounts in opposite directions when adjusted. This configuraiton assists in achieving adjustment of the focal length of the lenses while maintaining the focal axis of the lenses in a stationary position with respect to the frame.
• At least one stud is placed within the frame of the spectacles surrounding the at least two lens elements for support and guidance for lateral movement of the lens elements.
• the small studs or beams may extend in a direction substantially perpendicular to the plane of the lens, parallel to the optic axis.
• the studs do not impede lateral movement of the lens elements, but can aid in guiding the lateral movement and providing structural support for the spectacles.
• the lens elements may have planar surfaces that face one another in an abutting relationship.
• adjustable focal length lenses have been known in which each lens has a planar surface and a curved surface and where the curved surfaces have been arranged facing one another.
• the lens that performs selective refraction is effectively an air gap of variable shape between the two lenses.
• the presently proposed arrangement places the planar surfaces of the lenses together whereby the selective refraction of the light takes place primarily at the two outer surfaces. During adjustment, the planar surfaces may slide against one another.
• the lens elements may be separated by a film of liquid or gel, preferably a high viscosity liquid or gel, e.g. a silicone oil or gel.
• the close spacing of the lenses is believed to be advantageous in preventing the entry of dirt and particles in between the lenses.
• the high viscosity liquid assists to lubricate the interface between the lens elements and provide a stick slip effect to keep the position of the lens elements fixed against unintended adjustment of the lens.
• the liquid also assists in preventing dust from entering between the lens elements, and may be selected to reduce the changes in refractive index as light passes through the lens elements and the gap between them and improve light transmission between the lens elements.
• One or more guide rails may be provided which connect the two lens elements together and guide their lateral movement.
• a guide rail as part of the combined lens an improved guiding structure may be achieved which may be independent of the shape of the frame.
• the lenses may be more easily joined together prior to insertion in the frame and may be held more firmly together as a unit.
• the guide rail is moveable with respect to the frame and can move together with one or both of the lens elements.
• a guide rail is intended to include any structure that serves to guide one lens element with respect to the other in a lateral direction. In general the guide rail will be straight, although curved or angled guide rails are not excluded.
• At least part of the guide rail may be carried by one of the lens elements and may have a channel cross-section which receives a complementary protrusion or protrusions carried by the other lens element.
• the complementary protrusion may also be in the form of a rail which fits into the channel.
• the protrusion may be in the form of one or more pegs or followers of appropriate size to be guided by the channel.
• the guide rail may be formed to connect the lens elements as a click connection.
• the guide rail is a channel arranged on a first lens element, it may have a C- shaped section that links with a mushroom shaped protrusion or rail on the other element in a snap-fit arrangement.
• Joining the lens elements together may thus be relatively simple. It will be understood that as an alternative to a click connection, the two lens elements may be joined by sliding a follower laterally onto the guide rail. This manner of connection may be used for a dove-tail like embodiment.
• the rails may be provided adjacent to upper and lower edges of the lenses.
• the rails are arranged parallel to one another and ensure both improved guiding and also better retention of the lenses.
• the top and bottom guide rails may be identical.
• one of the rails may be for guiding while the other additionally provides for connection of the elements e.g. by incorporating a click connection as described above.
• the adjustment mechanism may comprise at least one movable actuator external to the frame.
• the moveable actuator may be gripped by a user and moved until a desired focal length is achieved.
• the actuator passes through the frame in a manner in which the entry of dust and dirt is prevented, e.g. through a seal.
• the actuator may be relatively discreet such that it is not seen during use and also such that it is not easily disturbed, whereby the focus would be upset.
• the actuator may be arranged for removal after initial setting such that the focus is then fixed and cannot further be adjusted.
• a lever which is pivotable at its centre about a fixed point on the frame and connects adjacent its respective ends with the two lens elements.
• the lever can then rotate about its pivot to cause respective movement of the two lens elements in opposite lateral directions. If each lens element is correctly shaped, this will lead to the optical axis remaining in the same relative position with respect to the frame.
• a moveable actuator may be located at any position within the lens- lever mechanism, a preferred location for the actuator is at one end of the lever. This may thus protrude outwardly through the frame and may be provided with a knob or grip for manual actuation.
• the adjustment mechanism can preferably be blocked by a blocking arrangement to prevent unintentional changes to the lens positions.
• the blocking arrangement may comprise interlocking teeth located on the frame, preferably on an internal surface thereof.
• the locking teeth may interact with further teeth located on the adjustment mechanism.
• the skilled person will understand that although reference is given to teeth, at least on one of the interacting parts, a single tooth may be provided.
• This arrangement may also comprise a spring loaded element arranged to engage and disengage with the interlocking teeth.
• This spring loaded element is preferably provided on the adjustment mechanism.
• FIG. 1 is a perspective view of a pair of spectacles according to a first embodiment of the invention with moveable actuators;
• FIG. 2 is a plan view of one combined lens from the spectacles of FIG. 1;
• FIG. 3 is a section through the combined lens of FIG. 2 along line 3-3;
• FIG. 4 is a perspective view of the combined lens of one of the lenses of FIG. 1;
• FIGS 5-7 are cut-away views of the spectacles of FIG. 1 showing operation of the combined lens
• FIG. 8 is a plan view of part of the frame of FIG. 1 ;
• FIG. 9 is a perspective view of a pair of spectacles according to a second embodiment of the invention with a rotatable element
• FIG. 10 is a cut-away view of half of the spectacles of FIG. 9 showing the rotatable element and the control lever;
• FIG. 11 is a perspective view of the connection of the control lever with the two lens elements in more detail
• FIG. 12 is a cut-away view of the rotatable element showing in more detail the connection to the different diameters and the connection to one of the lens elements;
• FIG. 13 is a cut-away view of the spectacles of FIG. 9 showing the interaction of two rotating elements with the combined lens;
• FIG. 1 there is shown a pair of spectacles 1 according to a first embodiment of the invention.
• Spectacles 1 include a frame 2 having arms 4 pivotally attached thereto at hinges 6 in a conventional manner.
• the frame 2 carries combined lenses 8 A and 8B.
• Combined lenses 8 A, 8B are of adjustable focal length as will be described here below. Adjustment of the focal length takes place using moveable actuator 10A, 10B located on an upper edge of the frame 2.
• the actuator is shown to be relatively large, although the skilled person will understand that in actual practice it may be significantly smaller as it needs only be used infrequently. Furthermore, although shown externally to the frame 2, the actuator may be located within the frame 2 and may be actuated using a suitable tool.
• the combined lenses have optical axes 12A, 12B. During adjustment of the focal length as will be described below, the relative positions of the lens axes 12A and 12B remain substantially constant. This is important, since for correct vision, the optical axis should align substantially with the distance between a wearer's eye centres.
• FIG. 2 shows a plan view of a possible embodiment for the combined lens 8A of FIG. 1.
• the lens comprises two lens elements 14, 16 located one in front of the other.
• Each lens element 14, 16 has a graduated surface 18 and a planar surface 20.
• the planar surfaces 20 abut against one another in a face-to-face relation.
• a thin film 22 a high viscosity liquid may be used between the two lens elements. This liquid may assist to lubricate the interface between the lens elements and provide a stick slip effect to keep the position of the lens elements fixed against small knocks causing unintended adjustment of the lens.
• Adjustment mechanism 24 comprising lever 40 and pivot 42, is attached to lens elements 14, 16 by lugs 44, 46. As will be further described below, displacement of the adjustment mechanism 24 causes lens element 14 to move in direction X and lens element 16 to move an equal distance in direction Y, and vice versa.
• a combined lens 8A may also be made with the lens elements having a curved surface in a face-to-face relation rather than a planar surface, or lens elements with both surfaces having a graduated surface.
• FIG. 3 is a cross-sectional view through combined lens 8A along the line 3-3 of FIG. 2 where the lens includes a guide element.
• the lens element 16 has a guide channel 28 adjacent to an upper edge 30 of the lens 8A.
• the guide channel 28 receives a complementary protrusion 32 on lens element 14.
• the guide channel 28 is C-shaped in cross-section and the protrusion 32 has a slightly mushroom shape. Both the channel 28 and protrusion 32 extend over substantially the full lateral width of their respective lens element 14, 16 and function as a guide rail. Additionally, due to the C-shaped cross section, the guide channel 28 also serves to hold the lens elements 14 and 16 together.
• both lens elements Adjacent a lower edge 34 of the combined lens 8A, both lens elements are provided with interfacing guide rails 36, 38.
• Guide rails 36, 38 are of partially dove-tailed cross-section and also extend over the full width of the lens. The skilled person will recognize that there is no necessity for each rail, channel or protrusion to extend over the full width given that the required guiding function is adequately achieved, that the C- shaped and dove-tailed guide elements may be used together or separately or other shapes or types of guide elements may be used, or that the guide elements may be omitted altogether, particularly when the frame 2 adequately performs a guiding function.
• FIG. 4 depicts the combined lens 8A in perspective view illustrating the interaction between the guide channel 28, protrusion 30 and guide rails 36, 38 and showing the adjustment mechanism 24.
• the adjustment mechanism comprises a lever 40 having a pivot 42 close to its centre. At the uppermost end of the lever 40 is provided an actuator 10B. A lug 44 is located at an upper part of the lever 40 and connects to the lens element 14. Another lug 46 (partially obscured) is located at a lower end of the lever 40 and connects to the lens element 16.
• the lugs 44, 46 may be connected to the lens elements in various ways of which the skilled person will be familiar. Most preferably, the connection will be a pin and hole connection allowing relative rotation.
• the pin may be integrally moulded with the lens elements and the lug may be recessed slightly into the lens element in order to reduce the space required within the frame 2.
• FIG. 5 there is shown the combined lens 8B of FIG. 4, viewed in the direction of sight of a user.
• the lens 8B is mounted in the frame 2, which is partially cut away to reveal the adjustment mechanism 24.
• Pivot 42 is mounted on a pin 50 provided within the frame 2.
• the pin 50 may be integrally moulded with the frame 2 or may be a separate part, e.g. a metal pin used in a plastic frame.
• the pin 50 allows the lever 40 to rotate at the pivot 42.
• the guiding channel 28 and rails 36, 38 are indicated adjacent the upper and lower edges 30, 34 respectively.
• the actuator 10B In the position according to FIG. 5, the actuator 10B is in a neutral position and the lever 40 is substantially vertical.
• the actuator 10B has been moved in the opposite direction towards the left. This causes the lever 40 to rotate in an anti-clockwise direction. In this case, lug 44 pulls lens element 14 towards the left while lug 46 pushes lens element 16 an equal amount towards the right. This causes the diopter of the combined lens 8B to decrease to a value of around -0.5. Adjustment of the combined lens 8 A takes place in a similar way.
• FIG. 8 shows a top view of a portion of the frame 2 with the actuator 10B removed.
• An upper part of the lever 40 protrudes through the frame 2 via a slot 52.
• the slot 52 is provided with optional interlocking teeth 54 along one of its sides and a resilient seal 56 along the opposite side.
• the lever 40 may be also provided with a number of teeth 58.
• the resilient seal presses the lever 40 against the side of the slot 52 causing the teeth 58 to engage with the interlocking teeth 54. Once engaged, the teeth 54, 58 prevent undesired movement of the adjustment means.
• the actuator 10B In order to adjust the focal length of the combined lens 8B, the actuator 10B must be moved against the pressure of the seal 56 in the direction of arrow Z.
• the seal 56 also helps to keep the slot 52 closed, preventing the introduction of dirt into the frame 2 interior.
• FIG. 9 shows a pair of spectacles 1 according to a second embodiment of the invention.
• Spectacles 1 include a frame 2 having arms 4 pivotally attached thereto at hinges 6 in a conventional manner.
• the frame 2 carries combined lenses 65A and 65B of adjustable focal length. These may be constructed according to the first embodiment and with some or all of the features described above and shown in FIGS. 2-4, but with an adjustment mechanism as will be described below. Adjustment of the focal length takes place by turning rotatable elements 60 A and 60B. Note that the rotatable elements 60 A and 60B are depicted in the drawings as having a relatively large size, but in practice they may be significantly smaller as they need only be used infrequently.
• Rotatable elements 60A, 60B may be made sufficiently small and recessed within the frame so that they protrude below the edge of the frame by only a small amount or do not protrude at all. This prevents the rotatable elements from resting against the cheeks of the wearer or otherwise becoming an obstruction, and hides the rotatable elements from view so that the spectacles have an attractive appearance and the adjustment mechanism is hidden and does not spoil the look of the spectacles.
• the combined lenses have optical axes 12A, 12B. During adjustment of the focal length as will be described below, the relative positions of the lens axes 12A, 12B remains substantially constant. This is important, since for correct vision, the optical axis should align substantially with the distance between a wearer's eye centres.
• FIG. 10 shows a rear view (from the wearer's point of view) of half of the pair of spectacles 1, divided by separation line A- A' and dissecting the frame to show the internal structure.
• One lens element 66A is connected to the control lever 62 at connection point 62A and one lens element 66B is connected to 62B.
• the control lever 62 pivots around point 62C mid- way between connection points 62A and 62B.
• a lateral movement of one lens element will induce a lateral movement of the other lens element in the opposite direction.
• the lateral movement of each lens element is equal and the lens axes are maintained in the same position relative to the frame.
• Lens element 66A interacts with rotatable element 60A via interlocking teeth 68 and 70A, with teeth 68 formed on a lower edge of lens element 66A and teeth 70A formed on rotatable element 60A.
• rotation of the rotatable element 60A is translated into lateral movement of the lens elements 66A.
• rotatable element 60A has two portions having different diameters, with teeth 70A formed on the inner smaller diameter portion 72A and teeth 70B forming an adjustment portion on the outer larger diameter portion 72B.
• Rotatable element 60 A protrudes slightly below the bottom edge of the frame so that teeth 70B are accessible to the user to manually turn the rotatable element 60A, This can most conveniently be achieved with the user's thumbs engaging with teeth 70B.
• the rotatable element may also be positioned so that its lower portion with teeth 70B does not protrude below the frame but is slightly recessed, so that but the user's thumb (or finger) is still able to engage with the teeth by pressing against the lower edge of the frame.
• Rotatable element 60A rotates about pin 61, which is connected to the frame 2.
• a number of studs 3 which protrude inwards from the frame portion 2a to support the lens elements while permitting lateral movement of the lens elements.
• the number of studs 3, which can be applied to the spectacles 1, is not limited to the number shown in FIG. 10. Nor are the dimensions of the elements limited to the dimensions of the elements used in FIG. 10.
• FIG. 11 shows in more detail a perspective view of the two lens elements 66A and 66B and how they are connected to the control lever 62.
• the control lever 62 is pivotally connected by a pin 74 going through the central axis hole 62C of the control lever 62.
• the pin 74 is connected to the frame portion 2a of the spectacles 1.
• the pin 74 and the central axis hole are aligned along axis line XI.
• Lens element 66 A is pivotally connected to control lever 62 by pin 76C through hole 62A of the control lever 62 and a hole 76A in a protrusion 78A connected to lens element 66A.
• Both holes 62A and 76A and pin 76C are aligned along axis line X2.
• Lens element 66B is pivotally connected to control lever 62 by a pin 76D through hole 62B of the control lever 62 and a hole 76B in a protrusion 78B connected to lens element 66B. Both holes 62B and 76B and the pin 76D are aligned along axis line X3.
• the dimensions of the holes 62A, 62B, 62C, 76A, 76B, the control lever 62, the protrusions 78A and 78B, the pins 74, 76C 76D, and the lens elements 66A and 66B, as the frame 2 of the spectacles 1 are not limited to the dimensions or arrangement shown in the drawings.
• the user turns the rotatable element 60A which acts to move the lens element 66A laterally.
• control lever 62 rotates counter clockwise, thus urging lens element 66B to move laterally to the left by a corresponding amount, as can be appreciated from FIG. 11.
• lateral movement of lens element 66A to the left will result in moving lens element 66B to the right.
• FIG. 12 shows a cross sectional view through the axis of the rotatable element 60A, showing in more detail the different portions 61 A and 6 IB of the rotatable element, and the connection of lens element 66A with the rotatable element 60A both located within the frame 2 of the spectacles 1.
• the axis of the rotatable element 60A is shown as axis line X4.
• the rotatable element 60A has two portions 72A and 72B with different diameters , with portion 72A being smaller in diameter than 72B.
• Portion 72A has teeth 70A which interlock with teeth 68 attached to or formed on lens element 66A.
• Portion 72B also has an adjustment portion 70B for manually rotating the rotatable element for adjusting the focal length.
• the adjustment portion 70B may comprise teeth, or a roughened or smooth surface suitable for manual adjustment.
• Portions 72A and 72B are rotatably connected to the frame 2 via pin 61. The shape and the distances between the elements are not limited
• each combined lens is provided with an adjustment mechanism so that both lenses can be individually adjusted to suit each eye of the wearer.
• the lens elements of the second embodiment may have a graduated surface and a planar surface, with the planar surfaces abutting against one another in a face-to-face relation.
• a thin film a high viscosity liquid or gel may be used between the two lens elements (whether they have abutting planar surfaces or not), to lubricate the interface between the lens elements and provide a stick slip effect to keep the position of the lens elements fixed against unintended adjustment of the lens.
• the liquid or gel may be selected to more closely match the refractive index of the lens elements to improve light transmission through the lens.

Landscapes

• Physics & Mathematics (AREA)
• Health & Medical Sciences (AREA)
• Ophthalmology & Optometry (AREA)
• General Physics & Mathematics (AREA)
• Optics & Photonics (AREA)
• General Health & Medical Sciences (AREA)
• Eyeglasses (AREA)

Priority Applications (4)

Applications Claiming Priority (2)

Publications (2)

Family

ID=45375743

Family Applications (1)

Country Status (5)

Cited By (5)

Families Citing this family (5)

Citations (3)

Family Cites Families (11)

• 2011
  • 2011-11-03 GB GB1118986.7A patent/GB2498171A/en not_active Withdrawn
• 2012
  • 2012-11-05 GB GB1406869.6A patent/GB2509456B/en not_active Expired - Fee Related
  • 2012-11-05 CN CN201280054051.1A patent/CN103907047B/zh not_active Expired - Fee Related
  • 2012-11-05 WO PCT/EP2012/071793 patent/WO2013064679A2/en not_active Ceased
  • 2012-11-05 JP JP2014539354A patent/JP6038943B2/ja not_active Expired - Fee Related
  • 2012-11-05 KR KR1020147015160A patent/KR20140084332A/ko not_active Withdrawn

Patent Citations (3)

Also Published As

Similar Documents

Legal Events