RU2021120388A - OPTICAL-HAPTIC CONTROL SYSTEM USING ROTARY CAMS - Google Patents

Claims (29)

1. An optical-haptic control system, comprising: a first cam assembly, comprising a first cam body, a hole in the first cam body, and paws for folding haptics disposed in the hole; a second cam assembly located on one side of the first cam assembly, wherein the second cam assembly includes a second cam body, an opening in the second cam body, and optical element folding members disposed in the opening; and a central plate for holding the intraocular lens in the hole of the main part of the second cam, while the central plate is located between the first cam assembly and the second cam assembly. 2. Opto-haptic control system according to claim 1, further comprising a bottom cover located on the opposite side of the second cam assembly from the first cam assembly, while the bottom cover contains openings that accommodate pins that extend from the tabs for folding the haptic elements and around which the paws are rotated for folding haptic elements. 3. Opto-haptic control system according to claim 2, in which the bottom cover includes a recessed ring and a raised central surface formed by the recessed ring, while the recessed ring accommodates the raised ring formed around the perimeter of the main part of the second Cam. 4. Opto-haptic control system according to claim 1, in which the central plate contains a surface for the lens and a channel passing at least partially through the surface for the lens, wherein each of the first pair of guides and the second pair of guides is located on both sides of the channel, wherein the channel accommodates elements for folding the optical element. 5. The opto-haptic control system according to claim 4, in which each of the elements for folding the optical element contains a main part, a tongue extending from the main part to engage with the main part of the second Cam, and a slope at the opposite end of the main part from the tongue, made with the possibility of engaging with the optical element of the intraocular lens, when the second cam assembly is actuated, and at the same time, each of the elements for folding the optical element additionally contains protrusions from opposite sides of the main part, which are located in the channels for the protrusions formed in at least one from the first pair of guides or the second pair of guides. 6. Opto-haptic control system according to claim 1, in which the main part of the first Cam contains the outer perimeter and the inner perimeter; wherein the inner perimeter of the first cam body defines an opening in the first cam body and one or more cam surfaces configured to engage with haptic folding tabs when the first cam assembly is actuated; while the protruding part of the Cam extends from the main part of the first Cam on the outer perimeter; while the main part of the second Cam contains the outer perimeter and the inner perimeter; wherein the inner perimeter of the main portion of the second cam defines an opening in the second cam assembly and one or more cam surfaces configured to engage with members for folding the optical element when the second cam assembly is actuated; wherein the recessed portion is formed in the outer perimeter of the main portion of the second cam; and wherein the first cam assembly is located such that the protruding part of the cam is located in the recessed part between the first end and the second end of the recessed part. 7. Opto-haptic control system according to claim. 1, in which each of the tabs for folding haptic elements has a first end and a second end and contains a protrusion at the first end and a pin extending from the second end, while the protrusion for each of the paws for folding haptic elements passes through the corresponding holes in the central plate. 8. Opto-haptic control system according to claim 7, in which the protrusion for each of the tabs for folding the haptic elements is configured to follow one or more cam surfaces formed in the perimeter of the hole in the first cam assembly, so that one or a plurality of cam surfaces engage with the protrusion to allow rotation of the haptic element folding tabs when the first cam assembly is actuated. 9. Opto-haptic control system according to claim 1, wherein each of the first cam assembly and the second cam assembly are disc-shaped. 10. The opto-haptic control system according to claim 1, which further comprises an intraocular lens located on the central plate, while the intraocular lens contains an optical element located over the channel formed in the lens surface of the central plate, and the intraocular lens further comprises haptic elements that extend from the optical element through one or more holes in the central plate. 11. Instrument for introducing an intraocular lens (IOL), containing: IOL located inside the cavity; nose; a piston configured to advance the IOL through the spout; a haptic optic control system (HOMS) comprising a cam mechanism configured to transfer user actuation to the HOMS to actively deform the IOL prior to advancing the IOL into the spout. 12. The IOL insertion tool of claim 11, wherein the HOMS cam mechanism is further configured to transfer user actuation of the HOMS to actively deform the IOL without the IOL contacting the nose or plunger. 13. The IOL insertion tool of claim 12, wherein the cam mechanism comprises one or more tabs, the one or more tabs being movable within the cavity in response to actuation by the user, resulting in deformation of the IOL. 14. The IOL insertion tool of claim 11, wherein the HOMS is further configured to fold one or more IOL haptics under the IOL optic and fold one or more edges of the IOL optic over the one or more folded IOL haptics. 15. The IOL insertion tool of claim 11, wherein the HOMS is further configured to extend in opposite directions a pair of IOL haptics.