The present disclosure relates to a machine for polishing a lens, that is, to for lens to its final surface for use by a wearer. The machine provides a method of polish a lens in which a lap and a lens are moved relative to each other in paths that are n repetitious to thereby prevent the formation of grooves, ridges or other aberrations in lens surface that can occur when repetitious regular or uniform lens finishing motions utilized.

The use of machines for finishing lenses is a well-known technology and background information relating to the prior art relevant to this disclosure reference be had to the following United States Patents: 4,862,644; 3,732,647; 3,552,899; 4,534,1 4,521,994; 4,135,333; 4,085,594; 4,510,717; 4,320,599; and 3,838,542.

The final polishing of a lens is achieved by moving a lens secured to a lens bl against an optical lap. The optical lap has a surface configuration with the desi ultimate shape of the surface of the lens being finished. The lens is normally secure a block by adhesive, and the block typically has spaced apart pin receiving recesse the rearward surface that receives pins that are a part of the lens finishing machine which motion is imparted to the lens block.

The machine of this disclosure employs a base on which the other structures mounted. The base supports a motor that provides rotational energy imparted to various elements in the machine. Spaced apart lap drive bearing blocks support lap d shafts, each shaft having an eccentric at its upper end. A lap holder body has beari that receive the eccentrics so that the lap holder body is moved in an orbital path. use of laps secured to the lap holder body, laps are thereby moved in an orbital pat in a plane parallel to that of the base.

A pair of spaced apart lens arms are supported above the base on a lens support assembly. This assembly is simultaneously rotated and laterally displaced a a common axis. The motion of the lens arm support assembly is imparted to lens a

which extend out and over the lap and have pins at the outer end thereof for engaging lens blocks.

Thus the lens finishing machine of this disclosure provides an arrangement wherein laps are orbitally rotated in a horizontal plane and wherein the lens holders are oscillated in two vertical planes, the vertical planes being perpendicular to each other to thereby provide relative motion between the laps and lens block in a compound non-repetitive manner.

A better understanding of the invention will be had by reference to the following description and claims, taken in conjunction with the attached drawings.

Description of the Drawings

Figure 1 is an elevational view of the basic elements making up the machine of th disclosure for finishing the surface of a lens in which the elements are mounted on horizontal base plate. The base plate is normally supported horizontally by superstructure and cabinet arrangement but such elements are not shown so as to ful view the mechanisms which provide the motions necessary to achieve the finishing of lens.

Figure 2 is a top view of the lens finishing machine of Figure 1 as taken along t line 2-2 of Figure 1.

Figure 3 is a bottom view taken along the line 3-3 of Figure 1 and showing primari the pulley and belt arrangement as employed in the machine illustrated in Figures 1 a 2.

Figure 4 is a front elevational view of the lens finishing machine of Figure 1.

Figure 5 is a partial cross-sectional view taken along the line 5-5 of Figure 1 a showing a lap holder body and means for orbitally moving the lap holder body in a pla parallel to that of the base plate.

Figure 6 is a cross-sectional view as taken along the line 6-6 of Figure 2 showi the basic structures as employed for imparting reciprocal movement of the lens holde in which the lens holders are reciprocated simultaneously in two planes, each plane bei perpendicular to each other and each plane being perpendicular to the plane of orbi movement of the lap holder.

Description of the Preferred Embodiment

Referring first to Figure 1 of the drawings, a lap is shown in dotted outline and indicated by the numeral 10. The lap is a standard element used in lens finishing and has an external surface defining that desired of the finished lens. Also shown in dotted outline is a lens 12 affixed to a lens block 14. The function of the machine is to move the lens 12 and lap 10 relative to each other so as to grind the surface of the lens to conform to that of the lap. Such movement must be non-repetitious so as to prevent the formation of ridges and grooves and other aberrations in the finished lens surface.

The elements of the machine that provide the desired movement between the lens block 14 and lap 10 are supported to a base plate 16 illustrated as being horizontal and will be described as being horizontal, it being understood that the description of the machine with reference to a horizontal base plate 16 is for purposes of simplicity and not limitative. The machine illustrated and to be described could function as well if the base plate 16 was vertical or at any angle between horizontal and vertical.

Supported to the top surface 16A of the base plate are two lap drive bearing blocks 18 and 20. The preferred embodiment of the machine which incorporates the principles of this disclosure is shown and will be described for use in finishing two lenses simultaneously since such is the normal application, it being understood that a machine which is equipped to finish a single lens would incorporate the same basic principles of the disclosure.

The lap drive bearing blocks are, as shown in cross-section in Figure 5, in the form of tubular housing, each supported to and extending upwardly from the base top surface 16A. Each of the bearing blocks 18 and 20 include upper and lower bearings 22 supporting lap drive shafts 24 and 26. Lap drive shafts 24 and 26 are thus supported parallel and spaced apart from each other, and each is supported to rotate about an axis that is perpendicular to the top surface 16A of the base plate.

A plate 28 extends between the tubular lap drive bearing blocks 18 and 20 and or structural proposes to more rigidly support the bearing blocks, the plate being para to the base plate 16.

Supported above plate 28 is a lap holder body 30 that, as illustrated, is in the fo of a machined or cast member which receives, on its lower surface, spaced ap bearings 32 and 34. The top surface of the lap holder body 30 receives lap vises 36 a 38, as shown in Figures 1 and 4 but not in Figure 5. The lap vices each include han portions 40 and 42 by means of which vice jaws 44 can be moved toward or away fr each other to thereby grasp a lap 10 as shown in dotted outline in Figure 1. Lap vi 36 and 38 are of a known arrangement commonly employed in lens finishing machin to expeditiously provide for removal and replacement of laps as necessary when changi from finishing one set of lenses to a different set of lenses. Figure 5 shows top surfa 46 of the lap holder body 30 that is adaptable to receive lap vices 36 and 38.

As shown in Figure 5, received on the upper end of each of the lap drive sh 24 and 26 is an eccentric 48 and 50 respectively. Eccentrics 48 and 50 have eccen shaft 48A and 50A respectively extending therefrom, these eccentric shafts being recei in bearings 32 and 34.

Affixed to the lower end of lap drive shaft 24 below plate 16 is a first lap dr sheave 52 and in like manner, affixed to the lower end of lap drive shaft 26 is a lap dr sheave 54.

Referring to Figure 2, a top view of the machine, there is shown supported on top of base plate 16 a motor 56. The motor has a shaft 58, as seen in Figure extending through the base plate 16, and the bottom view of Figure 3 shows the m shaft 58 having a primary drive sheave 60 affixed to it. A belt 62 encompasses primary drive sheave 60 and the lap drive sheaves 52 and 54. The preferred belt, illustrated in Figure 3, is of the notched type, and the sheaves 52, 54, and 60 preferably also notched so that sheaves 52 and 54 remain in synchronization with e other. A take-up reel 64 is mounted on the bottom of the base plate. By adjusta sliding arrangement take-up reel 64 can be moved to take the slack out of belt 62 so

to keep a desired degree of tension in the belt. Other than to provide means of regulating the tension in belt 62, the take-up reel has no function in the lens grinding processes.

With the motor 56 energized, rotating the primary drive sheave 60, the lap drive sheaves 52 and 54 and thereby shafts 24 and 26 are rotated, which imparts an orbital movement to the lap holder body 30. This orbital movement is in a plane parallel the base plate 16 and simultaneously orbitally moves the lap vises 36 and 38 as long as motor 56 is energized.

The method of imparting orbital motion to the lap vises and thereby to laps 10 secured in the vises has been described. Next, the motion imparted to the lens block 14 and thereby lens 12 will next be described, with reference primarily to Figures 1, 2 and 6.

Affixed to the top surface of base 16 are two upstanding spaced apart support blocks 66 and 68. Anchor bolts 70 and 72 are received in threaded openings in blocks 66 and 68 respectively. The anchor bolts extend facing each other and in a common axis 74, the axis being parallel to base 16. The anchor bolts 70 and 72 each have an enlarged diameter head portion at the outer end, and the anchor bolts are of smooth cylindrical shape on all portions that are exterior of the threaded openings in the blocks 66 and 68.

Guided on anchor bolts 70 and 72 is a lens arm support assembly, generally indicated by the numeral 76. The lens arm support assembly is formed of a base 78 which is parallel to base 16. Upwardly extending from the lens arm support base 78 are three spaced apart post sections 80A, 80B and 80C. The post sections are parallel to each other, spaced apart and perpendicular to base 16 and have opening 82A, 82B and 82C respectively therein, the openings being in alignment about an axis which is parallel to axis 74. Openings 8.2A, 82B and 82C receives bushing 84A, 84B and 84C respectively.

Slidably and rotatably received in bushings 84A, 84B and 84C is a lens arm rocker shaft 86. A first lens arm body portion 88 is received on and affixed to rocker shaft 86 between the post sections 80A and 80B. In like manner, a second lens arm body 90 is

received on rocker shaft 86 between the post sections 80B and 80C. By means of screws 92, the lens arm bodies 88 and 90 are locked to shaft 86.

As seen in Figure 2, lens arm forward portion 94 is affixed to a shaft 108 passi through bushings 109A and 109B in lens arm body 88. In like manner lens arm forw portion 96 is secured to lens arm shaft 110 passing through bushings 111 A and 111 lens arm body 90. The outer end of the lens arms are directly over lap vices 36 and

Each of the lens arm forward portions 94 and 96 have attached to the outer e thereof lens block engagement member 98 and 100 respectively that include downwar extended pointed pins 102 configured to engage recesses (not seen) in lens block It can therefore be seen that movement of the lens arm bodies 88 and 90 is transmit to the lens block 14 positioned over each of the lap vises 36 and 38.

Affixed to shafts 108 and 110 at the rearward ends of arm bodies 88 and 90 bearing covers 104 and 106. Bearing covers are cylindrical. Two set screws secure e of the bearing covers onto their respective shafts. Set collar 113A and 113B on sh 108 and 110 are provided to eliminate any play back and forth in arm bodies 88 and

The ability of the lens arms 94 and 96 to pivot in the lens arm supports 88 and allows the same pressure in all the different planes of movement of the lens block 14 lens 12 in arm supports relation to lap 10.

Affixed to the lower surface of base 16, as seen in Figure 3, are air cylin supports 112 and 114, only support 112 being seen in Figure 1. Through openings and 118 in base 16, air cylinders 120 and 122 are received. Air cylinders have pis rods 124 and 126 respectively extending therefrom, the piston rods being pivot attached at their lower ends to air cylinder supports 112 and 114. The upper ends of air cylinders 120 and 122 are pivotally attached respectively to the outer ends of bearing covers 104 and 106 by means of bearing attachments 128 and 130.

Flexible hoses (not shown) extend to the air cylinders 120 and 122. By means of controllable pressure (not shown) the piston rods 124 and 126 are urged outwardly from the air cylinders to apply upward force on the outer ends of the bearing covers 104 and 106 and apply downward force on the lens block engagement members 98 and 100. By controlling air pressure applied to cylinders 120 and 122, the force of engagement of each lens 12 against each lap 10 is regulated. In addition, by control of air pressure the arm may be pivoted to move the lens block engagement members 98 and 100 in the direction away from the laps 10 to enable the lens and lens blocks to be removed and replaced. The air pressure control systems are not shown in detail since such systems are well-known in the trade of lens grinding equipment for controlling the force of a lens against a lap during lens finishing procedures.

The method by which a lens is held in contact with a lap and the means by which the force of engagement of the lens with the lap have been illustrated. Now the mechanism by which movement of the lens blocks relative to the lens laps will be described. In the lens finishing machine of this disclosure the lenses are moved with reference to the laps simultaneously in two directions, that is, when viewing the machine from above, as in Figure 2, in a fore and aft direction as indicated by arrow 132 and in a reciprocal lateral direction as indicated by arrow 134. The method of movement of the lens blocks in the fore and aft direction as indicated by arrow 132 will be first described.

As seen in Figures 1 , 4, and 6, there is, attached to support block 66, a rocker arm post 136 which is in the form of a bolt having a threaded end portion received in the opposite end of the threaded opening that receives anchor bolt 70. The portion extending externally of block 66 is cylindrical with an enlarged diameter head.

Pivotably received on post 136 is a rocker arm 138. More particularly, bearing 140 is received by the rocker arm 138, the bearing, in turn, being received by the rocker arm post 136. Adjacent the upper end 138A of the rocker arm is an opening 142 having a bushing 144 therein. The bushing slidably and rotatably receives lens arm rocker shaft

86.

Referring now to Figures 1 and 2, there is positioned on the upper surface 16A o the base a gear box 146. The gear box has a vertical drive shaft 148 that extends through an opening in the base, and the shaft receives a pulley 150, as seen in Figure 3.

The gear box has a horizontally extending eccentric drive shaft 152. The rocke arm lower end has a drive post 154 in the form of a bolt extending from it. Connecting the eccentric drive shaft 152 and the rocker arm drive post 154 is a pitman 156, the length of which is adjustable. Adjustment of pitman 156 is necessary to center the lens arms 94 and 96 with pins 102 in relation to the center of lens block 14 and lens 12 relative to lap 10.

When the gear box drive shaft 148 is rotated the eccentric drive shaft 152 i thereby simultaneously rotated which moves pitman 156 in a reciprocal manner. Thi reciprocal motion is transferred to the rocker arm 138 and such motion is thereb transferred to the lens arm rocker shaft 86. This pivotal motion is thereby transferred t the lens arm support assembly 76 and to the lens arm bodies 88 and 90 to thereb produce the fore and aft movement of the lens arm indicated by the arrow 132 in Figur 2.

Now the method whereby the reciprocal lateral motion is imparted to the len holders, as indicated by arrow 134 in Figure 2, will be described.

As seen best in Figure 6, there is supported to the top surface 16A of the bas plate a tubular lens drive bearing block 158 which, in turn, supports upper and lowe bearings 160. The bearings receive a lens arm drive shaft 162. The lower end of the len arm drive shaft extends through an opening 168 within the base plate and has attache to it below the base plate, a lens arm drive sheave 170.

The upper end of the lens arm drive shaft has an eccentric 172 secured theret with an eccentric shaft 172A extending from it.

Affixed to the bottom surface of the lens arm support assembly base 78 is a bearing housing 174 and positioned within this bearing housing is a rotary pillow block bearing 176. The eccentric shaft 172A is received by bearing 176.

It can be seen that as a lens arm drive shaft 62 is rotated the eccentric 172 imparts a reciprocal motion to the lens arm support assembly 76 that slides back and forth on the anchor bolts 70 and 72. For this purpose, extending from the bottom of the end of arm support assembly base 78 are boss portions 178 and 180, each of which has an opening receiving bushings 182 and 184 therein. These bushings permit the lens arms support assembly 76 to pivot relative to the anchor bolts 70 and 72, and also to slide back and forth along the axis 74 in response to the motion imparted by eccentric 172. This reciprocal lateral direction is conveyed from the lens anchor support assembly 76 to the lens arm bodies 88 and 90 and thereby to the lens block 14.

Referring to Figure 3, the method of rotating the shafts 148 and 162 is illustrated. Affixed to lap drive shaft 24 below the lap drive sheave 52 is a secondary drive sheave 186. A belt 188, which is preferably notched so as to preserve the rotational relationship between shafts 148 and 160, laps around pulleys 150 and 170.

To maintain the proper tension in belt 188, a take-up reel 190 is secured to the bottom of base 16 and functions in the same way as take-up reel 64 with respect to belt 62.

The lens finishing machine heretofore described provides a means of conveniently supporting an optical lap holder or, specifically, two optical lap holders, and means fo providing a rotary motion to the optical lap holders. Simultaneously, the machine provides means of holding lens blocks to thereby position lenses in contact with the laps and in a manner wherein the lens blocks are reciprocated simultaneously in perpendicula directions with respect to the orbiting lap holders. This combined, complex motions o the lap holder and lens block substantially eliminates the possibility of repeate movements of the lens block with respect to the lap holder to thereby ensure that highes quality finishes will be obtained on lenses utilizing the machine.

The claims and the specification describe the invention presented and the ter that are employed in the claims draw their meaning from the use of such terms in t specification. The same terms employed in the prior art may be broader in meaning th specifically employed herein. Whenever there is a question between the broa definition of such terms used in the prior art and the more specific use of the ter herein, the more specific meaning is meant.

While the invention has been described with a certain degree of particularity, i manifest that many changes may be made in the details of construction and arrangement of components without departing from the spirit and scope of t disclosure. It is understood that the invention is not limited to the embodiments set fo herein for purposes of exemplification, but is to be limited only by the scope of attached claim or claims, including the full range of equivalency to which each elem thereof is entitled.