WO2004088392A1 - Telescope magnifying spectacles - Google Patents

Abstract

The invention relates to telescope magnifying spectacles (1) provided with at least one receiving ring (4) for a telescope system (5) which is fixed to at least one spectacle lens (3) by means of an adhesive layer. Said receiving ring (4) is provided with a contact face on the face thereof oriented towards the spectacle lens (3). Said contact face is used for receiving the adhesive layer and is provided with slots for receiving an adhesive substance.

Description

 Telescopic magnifying spectacles

The invention relates to telescope magnifying glasses in which at least one receiving ring for each telescope system is firmly connected to at least one spectacle lens by an adhesive layer.

Such telescopic magnifying glasses have been known for years from the prior art.

For example, DE 1 787 396 describes magnifying glasses, the optical systems of which are applied to the respective spectacle lenses by screw or plug rings, the screw and plug rings being made of a transparent material. The screw or plug rings or the optical system are cemented directly onto the outer surface of the lens. Putties are used which allow sufficiently durable and permanent connections between the lens material silicate and metal as the material of the screw or plug rings.

From DE 1 276 363 binocular magnifying glasses are known, with mounting rings for magnifying systems being firmly connected to a spectacle frame or with spectacle lenses. The spectacle lens is connected to the respective receiving ring by cementing. The respective magnifying glass systems are rotatably mounted in their associated mounting ring. Such magnifying glasses already offer a significant advantage over the magnifying glasses from DE 1 787 396, namely that with these two magnifying glass systems, which are applied to the two spectacle lenses, several different magnifications and associated work distances can be set alternately. By turning the magnifying glass systems without attachment lenses, the magnifying glasses are set to a certain working distance. When changing to a different magnification or working distance, the attachable lenses can then be applied to the magnifying glass systems and the new working distance can be set again by twisting.

A particularly disadvantage of such magnifying glasses is the very high weight, since when using corrective glasses, depending on the ametropia, the weight of the total glasses can increase considerably, especially since it was not yet possible to produce organic glasses.

Furthermore, binocular magnifying glasses are known from utility model DE 93 03 663, optical systems also being introduced into receiving rings and the receiving rings being firmly connected to a frame or spectacle frame. The receiving rings have a fixed angle to the vertical of the connecting straight line between the center points of the receiving rings, the receiving rings not being applied to spectacle lenses, but rather being connected to the spectacle frame via webs. To adjust the magnifying glass system to a new working distance, all you have to do is turn the magnifying glass system in the mounting ring.

Different working distances can thus be set. Spectacle wearers can also use such magnifying glasses by placing the magnifying glasses on the existing glasses. However, this is very uncomfortable for the respective ^'user, wherein again the weight plays a major role. The telescope magnifying glasses described in the prior art (DE 1 276 363 and DE 1 787 396) are applied directly to a spectacle lens. The frame parts of the magnifying glasses are generally made of metal and are cemented onto the lens. The problem here is that the thermal expansion coefficients of the two parts to be connected are different. This is particularly a problem if the mounting ring is to be cemented onto an organic spectacle lens. If the temperature changes, the cement will come loose or the glasses will break if the glue or cement is subjected to major temperature influences.

It is therefore an object of the invention to eliminate the above-mentioned disadvantages of the prior art and to provide a device and a method which enable the receiving rings to be more permanently bonded or cemented, especially on organic spectacle lenses.

According to the invention, this object is achieved in that the at least one receiving ring (4) is provided on a side facing the spectacle lens (3) with a contact surface for receiving the adhesive layer, the contact surface having cutouts for receiving adhesives.

The at least one receiving ring, which is cemented or glued onto the spectacle lens, is provided with a contact surface which makes permanent, permanent bonding possible, although the linear expansion coefficients of the at least one receiving ring and the spectacle lens differ greatly from one another. The adhesive gap is carried out in such a way that the shear deformation, which forms in the adhesive gap as a result of different material expansions when the temperature changes, is distributed over a defined and sufficiently large thickness so that the shear forces that occur become small enough.

The contact surface is advantageously formed by an annular recess.

By introducing an annular recess into the receiving ring, it is thus possible for the adhesive gap thickness to be increased significantly and thus for stable and permanent bonding or cementing of receiving rings on organic spectacle lenses.

In a particularly advantageous embodiment of the invention, it is provided that a processing surface of the at least one receiving ring for forming an adhesive gap of defined thickness is provided on an inner and / or outer edge of the at least one receiving ring on the side facing the spectacle lens.

The receiving ring can be machined on the inside to form a recess. However, a thin edge is left as a spacer when gluing or cementing. It is particularly expedient to leave the edge of the receiving ring in the outer region of the receiving ring. An aesthetic design of the receiving ring in connection with the spectacle lens can thereby be ensured. It also ensures that there is no wedge-shaped adhesive gap and thus an angular error is excluded. A particularly expedient development of the invention is provided by an adapter for exchanging the telescope systems.

With the help of an adapter, the individual telescope optics or telescope systems can be attached to the mounting rings and fastened. In this way, it is advantageously possible to replace the telescope systems with their individual magnifications as required, with existing magnifying glasses, without the need for new magnifying glasses if a different magnification is required. Thus, only the individual telescope systems with their different magnifications are required. This solution is therefore a more cost-effective alternative to purchasing multiple telescopic glasses.

Advantageous refinements and developments of the invention result from the further subclaims and the exemplary embodiment described in principle below with reference to the drawing.

It shows:

Figure 1 is a schematic representation of a telescope magnifying glasses, in which the receiving rings are firmly connected to glasses, top view in the use position;

FIG. 2a shows a basic representation of a receiving ring according to the invention;

FIG. 2b shows a basic illustration of an alternative receiving ring according to the invention; Figure 3 is a schematic representation of the design of the receiving ring according to the invention;

Figure 4 is a schematic representation of the connection of the receiving ring according to the invention with an eyeglass lens;

FIG. 5 shows an enlarged view of the connection of the receiving ring to the spectacle lens according to FIG. 4; and

Figure 6 is a schematic diagram of a telescope magnifying glasses when replacing the telescope systems.

FIG. 1 shows telescope magnifying glasses 1, a spectacle frame 2 being provided with organic spectacle lenses 3. Organic glasses are of course also understood to mean polycarbonate. A mounting ring 4 is applied to the spectacle lenses 3 by gluing or cementing. Telescope systems 5 are attached or fitted onto the receiving rings 4. In the binocular version, as can be seen in this exemplary embodiment, the receiving rings 4 have a fixed, nasally inclined angle to the receiving surfaces of the spectacle lenses 3. The convergence of the receiving rings 4 with the telescope systems 5 enables the wearer or user of the telescope magnifying glasses 1 to see objects closely with both eyes.

FIG. 2a shows the receiving ring 4 according to the invention from FIG. 1. The receiving ring 4 is turned out on the inside on the face side, a thin edge 6 remaining as a spacer during the gluing or cementing. The processing to produce such a recess 7 can of course also be carried out by a milling process can be produced. Advantageously, the edge 6 can remain on the outside, so that the adhesive or the putty can be prevented from forming a visible and unsightly bead of adhesive. It is of course also possible for the puncture 7, as in FIG. Furthermore, the puncture 7 can also take place on an outer and on an inner edge 6 and 7 of the end face serving for gluing, so that a thin edge remains as a spacer in the center of the receiving ring 4, as shown in more detail in FIG. 3. Such designs of the receiving ring 4 thus allow an adhesive gap of a defined thickness. In the event of thermal stress, the deformation is distributed over a thicker adhesive gap without having a negative impact on the adhesion of the adhesive.

FIG. 4 shows the receiving ring 4 in connection with the organic spectacle lens 3. The annular recess 7 on the adhesive surface of the receiving ring 4 can be seen in this example on the inner edge of the receiving ring 4. The contour of the turned-out step, which is filled with adhesive, is designed in such a way that the smallest possible von Mises criterion is set in a finite element simulation calculation in the largest part of the adhesive gap under thermal stress. In such connections, for example the receiving ring 4 made of aluminum and the organic spectacle lens 3, whose coefficients of linear expansion are very different, the thickness of the adhesive gap should expediently be as large as possible. The thickness of the adhesive gap depends, of course, on the elastomechanical properties of the hardened adhesive, with a soft adhesive that can withstand large shear deformations without creeping, the gap can be made narrower. The depth of the turned contour should, for example, be 0.2 to 0.5 mm, a width of the recess 7 of 2.5 mm having proven very useful. The wall thickness of the remaining edge 6 of the receiving ring 4 can advantageously have a width of 0.2 mm. Thus, depending on the use of the adhesive, the material of the receiving ring 4 and the lens material, the depth of the recess 7 and the wall thickness of the remaining edge 6 can be variable.

A section of the bond shown in Figure 4 is shown in Figure 5. Here, the contact surface of the receiving ring 4 with the spectacle lens 3 does not have a flat and smooth support, as is known from the prior art, but a recess 7 and an edge 6. This can result in a defined adhesive gap 8. The glass surface of the spectacle lens 3, which is connected to the receiving ring 4 in the case of cementing, can be roughened by sandblasting in order to ensure that the adhesive adheres better to the spectacle lens

3 to ensure and the receiving surface of the receiving ring

4 to mark. Thus, the deformation in the adhesive and thus also the stress that is generally present within an adhesive bond is smaller under thermal stress.

This can now ensure that receiving rings 4 can also be cemented onto organic spectacle lenses 3, in order to offer users of such telescope magnifying glasses 1 a variant which is better in terms of weight than was previously possible with mineral lenses.

In all of these exemplary embodiments, the receiving rings 4 relate to receiving rings made of aluminum. But it's Of course, it is also possible that the receiving rings 4 can be made of plastic, for example. Likewise, the invention should not only relate to receiving rings 4 in connection with organic spectacle lenses 3, but it would also be possible for the receiving rings 4 according to the invention to also be able to be cemented onto mineral glasses. The durability is also better there than with conventional gluing or cementing with an undefined thin gap, as is already known from the prior art. Of course, it would also be possible not to make the recess 7 completely ring-shaped, but to provide the receiving ring 4 with a plurality of recesses 7 on the edge of the receiving ring 4.

FIG. 6 shows a basic illustration of the telescope magnifying glasses 1, with the receiving rings 4 on the spectacle lenses

3 of the eyeglass frame 2 are already cemented or glued on. With the expansion of the receiving rings according to the invention

4 by means of an adapter 9 it is possible to attach individual telescope systems, such as the telescope system from DE 93 03 663 to the mounting rings 4 according to the invention or, for example, to mounting rings of the magnifying glasses from DE 1 276 363. An adapter ring 11, which is already known from the prior art, can be screwed onto an external thread 10 on a housing of the telescope system 5. Now the telescope system 5 with the adapter ring 11 firmly screwed or attached can be inserted into the adapter 9 according to the invention, with, of course, the optics having to be rotated. This is used for fine adjustment by the eccentrically constructed housing of the telescope system 5. The adapter 9 with the telescope system 5 used can now be fitted onto the mounting rings 4 which have already been cemented on Take rings 4 by means of a fit and secured with a locking screw 12. The user of the telescope magnifying glasses 1 can make the fine adjustment by turning the eccentric and secure the housing of the telescope system 5 against rotation by means of a further locking screw 13.

With the adapter 9 according to the invention in connection with the adapter ring 11, additional telescope optics, which have a higher or a lower magnification, can thus be provided for a given “basic equipment”, which can now be easily applied by the user himself to such telescope magnifying glasses 1. It is ensured optically that the eyepiece or the exit pupil of the telescope system 5 is as close as possible to the eye or the entrance pupil of the eye. As a result, the field of view reaches a maximum size.

Claims

Claims: 1. Telescope magnifying glasses, in which at least one receiving ring for each telescope system is firmly connected by an adhesive layer with at least one spectacle lens, characterized in that the at least one receiving ring (4) on a side facing the spectacle lens (3) with a contact surface for receiving the Adhesive layer is provided, the contact surface having recesses for receiving adhesive. 2. Telescope magnifying glasses according to claim 1, characterized in that the contact surface is formed by an annular recess (7). 3. Telescope magnifying glasses according to claim 2, characterized in that a processing surface of the at least one receiving ring (4) to form an adhesive gap of defined thickness on an inner and / or outer edge of the at least one receiving ring (4) on the side facing the spectacle lens (3) is provided. 4. Telescope magnifying glasses according to claim 2 or 3, characterized in that a wall thickness of the edge (6) of the at least one receiving ring (4) of less than 0.2 mm is provided. 5. Telescope magnifying glasses according to claim 2 or 3, characterized in that an insertion depth of> 0.2 mm is provided. 6. Telescope magnifying glasses according to claim 1, characterized in that the at least one spectacle lens (3) is designed as an organic spectacle lens. 7. telescope magnifying glasses according to claim 1, characterized in that the receiving rings (4) have a fixed, nasally inclined angle to the receiving surfaces of the lenses in binocular design. 8. Telescope magnifying glasses according to claim 1, characterized by an adapter (9) for exchanging the telescope systems (5). 9. Telescope magnifying glasses according to claim 8, characterized in that the adapter (9) for fixing against rotation of the telescope system (5) is provided with locking screws (12, 13). 10. A method for applying receiving rings ^' to spectacle lenses, in particular spectacle lenses for telescope magnifying glasses, in which the receiving rings for telescope systems are firmly connected to the spectacle lenses, and wherein the receiving rings in binocular design have a fixed, nasally inclined angle to the receiving surfaces of the spectacle lenses that the receiving rings (4) are provided on a side facing the spectacle lenses (3) with a contact surface for receiving an adhesive layer, which is designed in such a way that a defined, sufficiently thick adhesive gap results, the contact surface being formed by an annular recess (7) is formed, and then the receiving rings (4) are applied to the spectacle lenses (3), in particular cemented or glued on. 11. The method according to claim 10, characterized in that a recess for forming the contact surface on an inner and / or outer edge of the receiving rings (4) is introduced on the side facing the spectacle lenses (3). 12. The method according to claim 11, characterized in that the recess, in particular the transition from the approximately axial direction to the approximately horizontal direction of the processing is optimized after a finite element simulation. 13. The method according to claim 10, characterized in that the annular recess (7) is produced by turning or milling processes.