DE102018124791A1 - Joint for glasses - Google Patents

Abstract

The application relates to a joint for spectacles, comprising a first bore for fixing the joint to a fixed element, and further comprising a second bore for fixing a rotatably flexible element, wherein the joint further comprises holding elements with respect to the second bore, define a first rotational position and a second rotational position, so that a flexible rotary element is releasably fixed in the first position or the second position.

Description

background

In the field of eyeglasses, it is common to provide different fronts and different straps to fit the face geometry.

In this case, the provision of different fronts and ironing and the corresponding joints for the stirrups and the fronts is costly, as a variety of different elements must be designed and manufactured.

Most on the market and especially used and thus known eyeglass joints with a spring function follow a very similar construction. Particularly rigid spectacle fronts made of inflexible materials (metal, flexible plastics with a high material thickness, or even buffalo horn and wood) or with a material thickness that severely restricts yielding feathers of the front require a so-called flex hinge or flex joint.

The majority of these joints have behind the axis of rotation, which allows the folding of the bracket and usually connects the front movable with the brackets, each a sliding bearing with a bolt in the longitudinal axis of the bracket. This bearing is provided with a compression or tension spring (compression springs are usually around the bolt, tension springs behind). An externally abutting stop first forces an end position of the stirrup in the open state. If now the bracket is opened further, i. If the bracket is almost overstretched, the bearing shifts. The most common design is very simple: a longitudinal bolt is guided in a longitudinal sleeve, with an internal stop prevents the pulling out of the bracket and only allows a more or less controlled way of movement. The built-in coil springs automatically return the bar to the neutral open state. In some variants, a constant pressure is exerted when wearing to anchor the glasses firmly on the head, in other variants of the spring effect is only the comfortable placement of the glasses, because the brackets when donning the glasses at the widest point of the head should give way to a certain extent ,

However, these constructions have one or more disadvantages. Although there is a high flexibility in joints with this construction and also required, but from a technical size limit, they are no longer suitable for use with coil springs, which has an adverse effect. In addition, in these constructions, the size of the component does not allow for particularly springy coil springs, because the size of the joints for weight reasons and by installation in a temples the size may not be infinitely generous, which also has a disadvantageous effect.

In addition, the bolt in the sleeve requires sufficient clearance, otherwise, with close fit, frictional forces could greatly hinder the restoring forces of the springs or even cancel. As a consequence of this design all joints with this or a similar, similar technique have a high latitude: not only do the stirrups move in the desired rotational movement about the axis of rotation (usually the screw which movably connects the components), they are also strong susceptible to torsional forces, which may be detrimental to wearing the goggles. The temples are prone to 'wobble' when you hold the glasses to a bracket, can be found with a shaking that the comparatively heavy front of a sometimes violent up and down movement is exposed. This is due to the interaction of the forces that occur because the front protrudes far from the center of the joint.

Furthermore, the limitation of the component sizes means that noticeable consolidation tolerances can occur with the small springs installed in the interior of the sleeve. This often leads to greatly unequal detrimental flex effects: for example, it can happen that one of the two stirrups opens appreciably earlier, another disadvantage. Eyewear that requires pressure on the temple may experience asymmetries that can make eyewear adjustments difficult. This may limit the actual wearing comfort and changes the optical properties of the eyeglass lens system in a negative way. In addition, the visual appearance of the wearer may be negatively affected.

All these not insignificant disadvantages are known and have been accepted on the market for decades. Obviously, the advantages of the spring effect and the comfortable placement of the glasses outweigh the disadvantages of a certain sponginess of the ironing movement, the disadvantage of wobbling and the uneven force distribution sufficiently.

Other hinge systems, however, rely on the intrinsic flexibility of the materials used. Here it is both the elasticity of the material and the interaction of the components that do not really defined in a specific location spring, but by the interaction of geometry and Material, respectively material thickness or weakening effect and produces a more or less noticeable spring effect. This type of glasses is made almost exclusively from spring plates (eg stainless steel, titanium or bronze compounds). A use of these constructions in glasses that have a high intrinsic volume, so glasses from quasi three-dimensional elaborated front parts (glasses made of plastic, wood, horn, etc.) would be perceived as disadvantageous, since the balance of power and the torsional behavior between the relatively heavy components the glasses front and the intrinsically flexible materials (sheets) are in no functional relationship.

The object of the invention is inter alia to provide a novel joint that solves at least one disadvantage of the prior art.

The object is achieved by a joint according to claim 1.

Further advantageous embodiments are subject of the dependent claims and the detailed description and the figures.

list of figures

• 1 eine schematische Darstellung gemäß Ausführungsformen der Erfindung,
• 2.1-2.4 einen schematischen Ablaufplan gemäß Ausführungsformen der Erfindung,
• 3 und 3.1 eine perspektivische Ansicht eines erfindungsgemäßem Gelenks im Einsatz,
• 4.1-4.4 schematisch verschiedene Anbringungswinkel in Bezug auf ein feststehendes Element in einem erfindungsgemäßen Gelenk, und
• 5.1-5.5 weitere optionale Aspekte eines erfindungsgemäßen Gelenks

Hereinafter, the invention will be explained in more detail with reference to the figures. In these shows:

• 1 a schematic representation according to embodiments of the invention,
• 2 .1-2.4 is a schematic flowchart according to embodiments of the invention,
• 3 and 3 1 shows a perspective view of a joint according to the invention in use,
• 4 .1-4.4 schematically different mounting angles with respect to a fixed element in a joint according to the invention, and
• 5 .1-5.5 further optional aspects of a joint according to the invention

Detailed description

Hereinafter, the invention will be illustrated in more detail with reference to the figure. It should be noted that various aspects are described, which can be used individually or in combination. That Any aspect may be used with different embodiments of the invention, unless explicitly illustrated as a mere alternative.

Furthermore, in the following, for the sake of simplicity, usually only one entity will be referred to. Unless explicitly stated, however, the invention may also have several of the entities concerned. As such, the use of the words "a," "an" and "an" is to be understood merely as an indication that at least one entity is used in a simple embodiment.

The invention is based on ideas from rapid development. Thus, the novel joints and the bracket according to the invention allow a simple custom-made production of glasses, so that it no longer requires storage.

In 1 is shown a part of a joint according to the invention. The joint has a joint housing Y on. Here are in 1 two perspective view (front / rear view) of a joint shown, as they can come for example in a pair of glasses for use. A is an axis of rotation for attachment of a fixed element, such as a spectacle front specified. In the corresponding bore, a suitable fastener, such as a screw or a split pin, are introduced to secure the fixed member / the spectacle front thereto. The axis of rotation A allows the fixed element to be fixed at different angles relative to the joint housing Y. After connection with the fixed element, the compound is releasably rigid as a rule. With B is a rotation axis for fixing a rotatably flexible element, such as a temple, specified. In the corresponding bore, a suitable fastening means, such as a screw or a split pin, are introduced to secure the flexible element / the temple thereto. With C is an optional bevel / chamfer referred to, with the screw heads, for example, can be retracted inserted into the bore according to axis of rotation A. A corresponding optional bevel / chamfer can also be arranged on the bore according to the axis of rotation B. D is a first holding elements shown that the flexible rotary element prevents further rotation and thus defines a first end point / first position with respect to the joint housing Y. With E a second holding elements is shown that the flexible rotary element prevents further rotation in the opposite direction and thus defines a second end point / second position with respect to the joint housing Y.

In 2 various positions of a flexible element with respect to a fixed to a fixed element joint according to the invention are shown.

In part illustration 2.1 an "open" first position ("0 °") is shown in which the flexible element Z, for example a temple Z, by means of the joint (shown from top to bottom left to top right striped element) on a fixed element is attached. A part stands out for this X (in perspective in 3 shown) in the lateral opening of the joint housing Y and into the bore according to the axis of rotation A into it. The rotatory flexible element Z may be hollow, for example, as through Z.1 indicated. With D a first holding element is shown that the flexible rotary element Z prevents further rotation and thus a first end point / first position with respect to the joint housing Y Are defined.

In part illustration 2.2 the same ensemble is shown, wherein now a partially open position, for example 29 °, is shown. In this case, as shown in the figure by locking lugs on the joint housing Y certain intermediate positions can be provided by kraftüberwindbar between the first end position and a second end position. Without force would be the rotationally flexible element Z releasably fixed in this intermediate position. In such an arrangement, a small amount of force usually results in that when overcoming the locking element, the rotatably flexible element Z is pushed further or slides off the latch.

In part illustration 2.3 the same ensemble is shown, wherein now a further partially open position, for example, 58 °, is shown. In this case, as shown in the figure by locking lugs on the joint housing Y certain intermediate positions can be provided by kraftüberwindbar between the first end position and a second end position. Without force would be the rotationally flexible element Z releasably fixed in this intermediate position. In such an arrangement, a small use of force usually results in that, when the locking element is overcome, the rotatably flexible element Z is pushed further or slides off the latching lug.

In part illustration 2.4 a "closed" second position ("~ 90 °") is shown. With E a second holding elements is shown that the flexible rotary element Z prevents further rotation and thus defines a second end point / second position with respect to the joint housing Y.

The joint can be like in 3 be assembled as an example of an exploded view of a pair of glasses assembled. At the glasses front / the fixed element X a subarea protrudes X.1 in the joint housing Y into it. The subarea X.1 For example, it can minimize torsional forces on the joint through the front of the glasses. On the opposite side of the joint housing Y can the rotationally flexible element / the temple Z be introduced. Both the rotationally flexible element Z and the subregion X.1 have a hole, so that in the inserted state, the holes corresponding to the axes of rotation A respectively. B are arranged. Into the holes corresponding to the axes of rotation A and B suitable fastening elements can be introduced.

In 3 are exemplary similar fasteners I and J shown. For example, by J a hollow screw with internal thread shown in the one (maggot) screw I can be screwed. The screw I can also be hollow inside. Both the screw I as well as the banjo bolt J may include suitable elements for connection / rotation with a tool. For example, in 3 .1 a tool F shown that with optional actuators G (for manual rotation) can be equipped. In the tool F can be a suitable bit H with corresponding insertion elements H.1 (optional) are introduced. This will allow the screws I be rotated accordingly. On the opposite side, ie with the (hollow) screws J can be essentially the same bit H come for use. To the forces on the fixed element X can optionally reduce a suitable collar K be provided.

In 4 or the 4 .1-4.4 are different angles between the joint housing Y and the fixed element X, which of course also refers to the angular range of the flexible rotary element Z impact. While in 4 .1 a close position of about 0.3 ° is shown in 4 .2 shows an angle of 4.2 °. In 3 will be a wide angle of 3.3 ° and in 4 .4 an extra-wide angle of 4.3 ° branched. The angles shown are exemplary only and suitable angles in a range of about 0 ° to 7.5 ° can be assumed. That is, in the case of glasses, an adaptation to one and the same spectacle front can thus be provided for different carriers with different head widths, as a result of which manufacturing cost advantage can be achieved.

In 5 Fig. 1 is a temple as an example of a flexible rotational element Z with respect to a fixed element X shown in a joint Y from above. In 5 .2 is the eyeglass temple as an example of a flexible rotary element Z in relation to a fixed element X in a joint Y according to 5 .1 shown from the side. The holes (corresponding to the axes of rotation A and B) with inserted (hollow) fasteners I or J shown.

Are the fasteners I respectively. J hollow as in 5 .1 and 5.2, this can be used, for example, for a further element, eg a protective front, to be used without tools by means of a 5 .3 shown detent in the corresponding cavities of the fasteners I respectively. J , (de-) can be mounted. For example, a sunglass front in front of optical glasses or a goggle front in front of optical glasses can be mounted as needed. In 5 .4. is this principle of 5 .3 again (this time with respect to the axis of rotation B) shown. For example, such a lateral (wind / spray) protection (optionally movable with the flexible rotary element Z ) by means of an in 5 .5 shown detent in the corresponding cavities of the fasteners I respectively. J to be (de-) mounted. How out 5 .4. it can be seen that two such optional elements can be arranged simultaneously on a joint.

The overall size of the novel joint is subject to the limits of the currently technically feasible sizes of the individual components. The novel joint can be designed with a height of a few mm, e.g. 3-10 mm, but also for larger items such. Car doors are manufactured (height based on the horizontal orientation of the joint.

It is conceivable to manufacture the components in a rapid prototyping or rapid manufacturing process in order to obtain small parts and components with high accuracy. This makes it possible to install the new technology in a small space. Metals of all kinds are suitable as building materials, provided that they are suitable for the abovementioned rapid prototyping or rapid manufacturing processes, or that they can also be processed using technically usual methods (such as pressing, casting, milling, sawing) , However, plastics can also be used as long as they can withstand permanent bending and tensile loads (e.g., injection moldable polymers and thermoplastics).

As stated previously, the rotatably flexible element Z can be hollow Z.1 be designed. It is hollow to understand that the area Z.1 is not rigid, ie consists of "solid material". For example, the area Z.1 also still ungelasertes / unpolymerized material, for example in the range of a temples / rotatory flexible element Z which would come to rest in the area of an ear. Typically, these areas are bent to accommodate the particular wearer (typically under the influence of heat). Now, if a local, flexible filling of the cavity is provided, so can a bend of the otherwise hollow rotatable element Z be provided, in which the radius of the tube remains almost constant.

Claims (6)

A gland joint comprising a first bore for securing the joint to a stationary member, and further comprising a second bore for securing a rotationally flexible element, the gland further comprising retaining members having a first rotational one relative to the second bore Define position and a second rotational position, so that a flexible rotary element is releasably fixed in the first position or the second position. Joint after Claim 1 , characterized in that in a rotational movement from the first rotational position to the second rotational position, the flexible rotary element slides in the second bore. A rotatory flexible element, wherein the rotatably flexible element is designed for insertion into a bore, wherein the rotatably flexible element is produced by a rapid development process, wherein the eyeglass temple is hollow in sections, wherein the cavity by non- (laser) sintered / polymerized Powder was produced. Glasses having a spectacle front and two joints according to one of the preceding Claims 1 to 2 , Glasses having a spectacle front and two rotatory flexible elements Claim 3 , Glasses having a spectacle front and two joints according to one of the preceding Claims 1 to 2 and two rotationally flexible elements after Claim 3 ,

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