DE217254C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 217254 CLASS 42 Λ. GROUP

CARL ZEISS company in JENA.

Meniscus-shaped spectacle lens. Patented in the German Empire on August 1, 1908.

The invention relates to spectacle lenses, both corrective lenses, the ametropes distant or Pointing close objects sharply - ■ diffusing lenses for myopic ones and collecting lenses for hypermetropic ones and for aphakic eye glasses as well as magnifying glasses, d. H. such collecting glasses designed to emmetrope, who are already presbyopic to enable sharp vision at close range. It is known,

ίο that a corrective glass of the form of a meniscus, if one turns its hollow surface towards the eye, of objects in the peripheral parts of the visual field presents a somewhat less poor image than a glass of more or less symmetrical shape. This fact also applies to magnifying glasses to. It finds its explanation in the fact that the relation to the axis of the spectacle lens crooked tufts which, when seen directly, reproduce those peripheral objects mediate in the refraction through the peripheral part of the lens a smaller overall error will be obtained if the glass is meniscus than if it is more or less symmetrical. The demand has already been reached through suitable ones Choice of the "curvature" of the meniscus a single one of the faults of oblique tufts as completely as possible. Since the crooked tufts that correspond to the pupil of the eye to have only a small opening, to cross at the point of rotation of the eyes, so you needed only this point, which is about 3 cm behind the apex of the hollow surface, according to a known, especially emphasized by Gullstrand the sentence from the dioptric of the eye as the center a narrow aperture and thus had the new for the practical optics Task traced back to such a known way. Roughly in this way are corrective lenses have been calculated that are free from astigmatism, e.g. B. by Ostwalt.

According to the patent specification 119915 the Reduction of the errors of oblique tufts in dioptric systems, the diaphragm of which has a is greater or less distant from one or more surfaces of the system, be brought about by one or more of the spherical surfaces of any Aperture distance deformed, d. H. in the technical sense of this word that one can see its curvature while maintaining the property of the surface to be changed as a surface of revolution in with respect to the system axis, can be changed continuously from the vertex to the edge. As a field of application this corrective agent for the errors of oblique tufts are used in the said patent system of composite type, namely eyepieces and photographic Lenses, labeled.

The present invention arose on the one hand through the transfer of the correction means according to patent specification 119915 in the case of a spectacle lens as a single lens with a narrow rear screen of unalterable and unusually large distance, on the other hand, by combining this remedy with the one already practiced Change in the curvature of the meniscus. The aim of the invention is correction no longer a single mistake wrong

Claims (1)

Tufts, but two. Each of the two corrective agents given works both on one as well as on the other of the two errors that are to be corrected. The correction of two errors is already evident when a single surface is deformed than it is possible to use this area, not to the same extent, but to the same extent Senses deformed as if it were a bundle of axially parallel rays from the diameter of the lens the spherical deviation due to a so-called aplanatic To eliminate the area known from the spherical surface corresponding to its apex in deviates in such a way that its curvature from apex to edge is steady The degree of curvature of the second surface, which is left spherical, approaches. The deformation becomes So a diffusing spectacle lens is thinner on the edge, a collecting lens is thicker on the edge. But since in the second case the practically required small edge thickness is not to be exceeded needs, but can assume from the outset a correspondingly smaller vertex thickness, then a reduction in the Weight of the lens, in the first case directly, in the second case indirectly, with the Deformation connected. The most favorable deflection deviates considerably from the deflections, by means of which one can with a spectacle lens that has the same number of diopters and the same Kind (according to the distinction in the entrance) belongs, but not deformed in any area ; is, the best correction of one or the other of the same two errors is more skewed Tuft scored. The change in the most favorable deflection on the one hand with the type and on the other hand with the number of diopters of the spectacle lens remains between such limits that of: the two radii, the apex radius of the deformed surface and the radius of the spherical surface, at most one longer than a third and none shorter than an eighth is the focal length of the lens. If one chooses as the two errors that are to be eliminated as far as possible, the Astigmatism and the distortion from, it follows from. an in-depth investigation, that the more perfect correction can be achieved with deformation of the less curved surface. Depending on the choice of the two errors to be corrected, an oblique tuft falls in the case of ··,.: ■ the same vertex thickness of the lens and the same Curvature of its spherical surface differs from the shape of the deformed surface; the end. In all' However, the determination of the course of the meridian curve of the deformed surface is necessary t \ made possible by the comprehensive information, made to explain the new correction means in patent specification 119115 have been. For the practical implementation of such non-spherical surfaces of revolution are already several grinding devices' known, z. B. from the French patents 292531, 327311 and 349342. In the drawing, two corrective spectacle lenses are shown as examples of the invention. The first is binoculars for a severely myopic eye, the second a reading glass for a strongly hypermetropic or an aphakic eye. The diffusing meniscus of FIG. 1 consists of glass with an exponent of refraction of 1.52. He has ico mm focal length; its strength is ten diopters. In addition to the large distance between the objects, a narrow rear diaphragm D is assumed, the distance I from the vertex of the rear surface of which is 30 mm. The radius r of the rear surface is 15.8 mm. The vertex thickness d is 0.5 mm. The front surface is slightly deformed. Its apex radius r ₀ , at the same time the radius of the spherical surface which is only dotted as unreal and which corresponds to the apex, is 23.0 mm. From this spherical surface of the edge of the deformed surface is: 32 mm diameter by only ¹ mm from J _4. The extent to which the correction of astigmatism and distortion has been achieved can be seen from the following summary. It contains, for several inclinations w of the entering tuft, firstly with regard to the astigmatic correction, the back focal lengths s'j of the sagittal and 's't of the meridional component of the exiting tuft, ie the distances from the exit point to the interfaces, and secondly with regard to the Correction of the distortion, which is strongly barrel-shaped without the application of the deformation, the so-called magnification ratio V, in this case the ratio of the angular distance of the object point and the linear distance of the image point from the optical axis. o ° 26.265 ° ^q "™ ^T ° 37, ^s ' f 99.26 mm 100.29 ^mm 101.82 mm s't 99.26 - 97.88 - 102.73 - V. 100.00 - 99.01 - 98.31 - The collecting meniscus of Fig. 2 is made of glass with an exponent of refraction of 1.655. Its focal length is 72.59 mm, so its strength is 13.8 diopters. It is assumed that the object lies in a plane which is perpendicular to the axis and 330 mm from the vertex of the front surface and that a narrow aperture D is located at a distance I of 30 mm behind the. Vertex of the posterior surface is located. The radius r of the front surface is 21.30 mm. The apex thickness is 5.0 mm. The back surface is deformed. The radius r ₀ of the vertex the spherical surface corresponding to the rear surface is 35.0. The edge of the deformed surface is 34 mm in diameter ^x / ₄ mm from this imaginary spherical surface. The table below again contains the sizes explained in the first example. However, V here means the ratio of two distances and could therefore be given as a percentage. The distortion would become very highly pincushion without applying deformation