IT201800002892A1 - Spring hinges for glasses - Google Patents

Description

Description of the industrial invention entitled "Spring hinges for glasses"

The present invention refers to spring hinges for eyeglasses, of the type generically known also as "flex hinge", which have a joint on which one or more springs act to identify a stable open position and a stable closed position of the temples of the eyewear and to allow, if desired, an elastic over-opening of the temple.

A spring hinge for eyeglasses generally comprises two parts hinged with a pin, intended to be attached respectively to the front and to a shaft of the eyeglass frame. The part associated with the rod is formed by a casing or "box" for fixing the rod and by a joint element that slides in the casing against the action of springs that push it opposite the joint, so as to provide the desired hinging elastic as mentioned above.

Embodiments of these types of hinge are for example described in EP0896692, EP0902908 and EP0679920.

The realization of the sliding joint element and the arrangement of the springs to react on it are particularly critical, especially considering that the dimensions of the entire mechanism must be kept small even though its considerable strength and durability are necessary. The machining complexity of the various parts and the total cost of the hinge must also be kept reasonably low.

In order to try to satisfy all these requirements, in the known art, for example, hinges for eyeglasses have been proposed in which the sliding joint element has the rear end inside the box which is L-shaped or T-shaped to support the springs which I push it towards the inside of the box. However, this involves machining on the sliding element that is not always acceptable, given the usually very small dimensions of this element and the consequent difficult workability. In addition, any processing, bending or sharp edge made on this element can weaken it and lead to fatigue breakage during the use of the glasses.

Hinges have also been proposed in which the elongated joint element is U-shaped, with the ends of the arms of the U forming the pivoting end and the bottom of the U forming the support for the spring, which is thus received in the arms of the U.

Such a type of hinge is shown for example in EP2274647.

The processing of the U is however delicate, the width dimensions of the hinge are constrained by the dimensions of this U and, furthermore, possible problems of weakness due to the U-shaped folding operations of the hinge element are added. In addition, the U shape produces a stiffness of the pivot element which generates further possibilities of breakage. Attempts to increase strength by employing special materials, reinforcement ribs or similar expedients come up against excessive cost and additional machining difficulties.

Hinges have also been proposed where the spring is fitted onto the elongated joint element and, to support the spring, the rear end of this element is threaded and provided with a nut or a locking ring is crimped on it. . However, even these solutions have proved to be not optimal because they are relatively complex and expensive and not particularly robust.

The general purpose of the present invention is to provide an improved hinge for glasses, which allows for example to have a satisfactory strength and ease of manufacture and assembly. Furthermore, a further object is to provide a hinge that has a more modular structure, to allow the production of hinges with a different transverse dimension and / or with a different number of hinging slots with satisfactory ease. A further object is also to provide a construction and / or assembly method for such an improved hinge.

In view of these purposes, according to the invention, it was thought to produce a spring hinge for eyeglasses comprising a casing and at least one articulation element which protrudes from the front of the casing with a pivoting front end and which has an elongated body which is slidably housed in a housing in the casing, the elongated body of the articulation element ending with a rear end, opposite the front pivot end, on which at least one spring contained in the casing acts to push the articulation element in an opposite direction at its front pivot end, characterized by the fact that the joint element has a seat near its rear end, in which a pin transversal to the extension of the joint element between the rear end and the front pivot end is accommodated, and on this pin pushes the at least one spring. A method is also described according to claims 10 and 11.

To clarify the explanation of the innovative principles of the present invention and its advantages with respect to the known art, an exemplary embodiment applying these principles will be described below, with the help of the attached drawings. In the drawings:

-figure 1 represents a partial schematic view of a pair of glasses equipped with a hinge according to the invention;

-figure 2 represents a schematic view in exploded perspective of a first embodiment of a hinge according to the invention;

-figure 3 represents an enlarged schematic view of a hinge according to the invention mounted in a pair of glasses;

figure 4 represents a schematic perspective view of a pre-assembled part of the hinge of figure 2, with a removable capsule for the temporary locking in position of the pre-assembled elements;

-figure 5 represents a schematic view in exploded perspective of a second embodiment of a hinge according to the invention;

figure 6 represents a schematic perspective view of a stop element of the hinge of figure 5;

figure 7 represents a schematic perspective view of a part of the hinge of figure 5 in assembled condition;

figure 8 represents a schematic perspective view of a capsule for the temporary block in the assembled position of the elements of the hinge part of figure 6;

figure 9 represents a schematic perspective view of the hinge part of figure 7 with the blocking cap of figure 8 to form a pre-assembled unit;

figure 10 represents a schematic perspective view of the preassembled group of figure 9 introduced into a receiving casing which is fixed to a part of glasses to be hinged;

- Figures 11 and 12 represent schematic views, respectively in exploded and assembled perspective, of a variant of the hinge according to the invention;

-figure 13 represents a schematic view in perspective of a possible variant of a stop element present in the hinge according to the invention;

-figure 14 represents a schematic view in perspective similar to figure 7 but with the stop element of figure 13;

-figure 15 represents a schematic view in perspective of another possible variant of a stop element present in the hinge according to the invention;

- figure 16 represents a schematic view in perspective similar to figure 7 but with the stop element of figure 15;

-figure 17 represents a schematic view in exploded perspective of a third embodiment of a hinge according to the invention;

figure 18 represents a schematic perspective view of a part of the hinge of figure 17 in the assembled condition;

figure 19 represents a schematic perspective view of the hinge of figure 17 in the assembled condition;

figure 20 represents two possible variants of a hinge according to the invention with different transverse widths;

-figure 21 represents a schematic view in exploded perspective of a fourth embodiment of a hinge according to the invention;

figure 22 represents an enlarged schematic view of the hinge of figure 21 assembled and mounted in a pair of glasses;

-figure 23 represents a schematic perspective view of a shearing operation to obtain elements of the hinges according to the invention starting from a metal band.

With reference to the figures, Figure 1 shows a partial view of a pair of glasses 10 with a front 11 and a rod 12 hinged together by means of a spring hinge, generally indicated with 13, made according to the principles of the present invention.

The hinge 13 comprises a first part 14 and a second part 15 hinged together along an axis 16 to allow the opening and closing movement of the rod 12 with respect to the front 11. For simplicity, figure 1 shows only a right half of the eyewear 10, the second half being a mirror image of it as clear to the technician. As will become clearer below, the first and second parts of the hinge will be fixed in a manner known per se (screws, welding, gluing, etc.) to the respective parts of the glasses.

Figure 2 shows a first embodiment of a hinge according to the invention.

In this embodiment, the part 14 of the hinge comprises a carcass or "box" 17 which internally identifies a cavity or housing 18 which is open at the front and which slidably accommodates a joint element 19. The sliding joint element 19 has a front end 20 which protrudes at the front from the seat in the casing for pivoting to the second part 15 according to the pivot axis 16. To achieve the pivoting, the front end 20 of the articulation element 19 preferably has a slot 21 which is crossed by a pin 22 inserted in a suitable transversal seat 23 in the second part 15 of the hinge. Advantageously, the second part 15 comprises a notch 24 which is crossed transversely by a hole which makes the said seat 23 for the pin 22. The notch 24 accommodates the front end 20 of the articulation element 19 so as to contain it and guide it laterally allowing the desired rotation around the axis 16. The pin 22 can advantageously be made in the form of a screw which is screwed into the hole 23 after the end 20 of the articulation element 19 has been inserted into the notch 24. see clearly in Figure 2, the articulation element 19 has a body 25, elongated in the sliding direction, which is housed in the cavity 18 of the casing 17. This elongated body ends with a rear end 26, opposite the front end 20 of pivoting, and on which acts at least one spring 27 also contained in the cavity 18 in the casing to elastically push the articulation element in a direction opposite to its front end of pivot. ento.

Advantageously, the articulation element 19 can be made (preferably by blanking from a strip or sheet of suitable material, for example metal, or also by laser cutting or by chemical photo-blanking or photoengraving or by using other known techniques) , with constant thickness in the direction parallel to the pivot axis 16.

The articulation element 19 has near its rear end 16 a seat 28 in which a pin 29 extended with an axis which is transversal to the extension of the articulation element between its rear 26 and front 20 ends is received. pin pushes the at least one spring 27. The spring is preferably a helical spring which is arranged side by side and parallel to the elongated body of the joint element. Preferably, in the embodiment of figure 2 there are two springs, arranged on the two sides of the articulation element 19 and the pin 29 protrudes symmetrically on two sides of the articulation element with its two opposite ends to form with each of these end a support for one of the two springs 27.

The spring or springs 27 react between the pin 29 and the casing 17. For this purpose, the hinge of figure 2 advantageously comprises a stop element 30 intended to be constrained to the casing near the front pivot end of the articulation element to support the end 33 of the spring 27 which is opposite the end 34 of the spring which pushes on the pin 29. Advantageously, the stop 20 has a passage 31 through which the elongated body 25 of the articulation element 19. The stop 20 can also preferably comprise pins 32 for receiving and guiding the ends 33 of the springs 27.

In particular, the stop 30 can be made to fit into the mouth of the cavity 18. For this purpose, as can be seen better in figure 4, the stop 30 can preferably have a U-shape with arms 42 of the U which are elastically spread apart and directed towards the hinge pivot so as to fit against the internal walls of the cavity near the front opening of the cavity when the stop is forcibly inserted into the cavity 18. Preferably, from the bottom 41 of the U the pins 32 protrude perpendicularly for the ends 33 springs.

Figure 3 shows the enlarged view of the hinge 13 assembled and constrained between the front 11 and the rod 12 of a pair of glasses.

Advantageously, the stop 30 can also act as a limit switch allowing the springs / springs to never reach the pack and, consequently, to lose less load with the cyclical use of the glasses. Alternatively, it can be the spring itself that performs the limit switch function.

The open or closed positions of the hinge can be advantageously made elastically stable by means of a cam interference of the head surface 39 of the casing 17 against corresponding sliding surfaces 40 which are present on the element 15, with a system known per se and easily imaginable from technical based on the description made here. In particular, by rotating the hinge, the sliding of the surface 39 on the appropriately shaped surface 40 draws the joint element outwards against the action of the springs until the two parts of the hinge reach one of the two stable positions. If desired, the over-opening of the hinge beyond the normal opening position is also allowed thanks to the further elastic sliding of the joint elements against the action of the springs.

Figure 4 shows the joint element with the pin, the springs and the stop mounted on it. For clarity, the casing 17 which is to receive them is shown with broken lines.

Figure 4 also shows the possible use of a removable capsule 35 which allows the assembly formed by the articulation element 19 to be pre-assembled and moved with the pin 29, the springs 27 and the stop 30 before inserting this assembly into the casing 17 and fastening the articulation element to the second part 15 of the hinge.

This can be useful, for example, when the casing 17 must be tied to a rod by means of an operation that could be hindered or prevented by the presence of the said group already inside the casing. For example, in case of fixing by induction spot welding (or, more generally, through the use of filler material) of the casing on a metal rod it might be preferable to insert the entire assembly into the casing only after the welding of the casing on the rod.

As it is clear from Figure 4, using the capsule 35 it is therefore possible to form a pre-assembled group by means of the steps of mounting the pin 29 on the articulation element 19 and the at least one spring 27 to push on the pin, insert on the front pivot end 20 the removable capsule 35 so that it engages between the front pivot end 20 (for example by means of one or two protrusions 36 which snap elastically into the slot 21) and the at least one spring 27 (with possible interposition of the stop 30, if present) to hold the springs in place against the pin. Push fingers 37 can be provided protruding from the capsule towards the stop 30 to push on the stop and keep the springs 27 compressed. These push fingers 37 can be two, to accommodate the front part of the articulation element between them and can comprise laterally the projections 36 which engage elastically from the sides into the slot 21.

It is thus possible to easily move the preassembled group before its introduction into the housing in the casing and also to ship the two parts separately to the final assembler of the glasses.

When the time comes (for example when the carcass has been fixed on the shaft of a pair of glasses) it is then possible to insert the part of the preassembled group into the cavity in the carcass and then remove the block capsule 35 from the preassembled group.

To facilitate the manipulation of the press-assembled unit with the capsule, the capsule can advantageously have a wide gripping end 38 from which the fingers 37 can advantageously protrude.

Figure 5 shows, exploded, another embodiment of a hinge according to the invention. For convenience and clarity of presentation, elements similar to those of the previous realization are indicated with the same numbering increased by 100.

In this embodiment of Figure 5, there is therefore a hinge 113 with a part 114 of the hinge which comprises a casing or "box" 117 which internally identifies a cavity or housing 118 which is open at the front and which slidably accommodates two joint elements 119 arranged together parallel to have front ends 120 which project forwardly from the seat in the casing for pivoting to a second part 115 along the pivot axis 116. To provide the pivot, the front end 120 of the articulation elements 119 preferably has a slot 121 which is crossed by a pin 122 inserted in a suitable seat 123 in the second part 115 of the hinge.

Advantageously, the second part 115 comprises notches 124 which each receive the front end 120 of a joint element 119, so as to contain it and guide it laterally. These notches are transversely crossed by the hole that makes the seat 123 for the pin 122. The pin 122 can be advantageously made in the form of a screw which is screwed into the hole 123 after the end 20 of the articulation element 119 has been inserted. in the notch 124.

Each joint element 119 can be made substantially the same as the joint element 19 already described above, and have a body 125 elongated in the sliding direction in order to have the front end 120 protruding from the housing 118 and an opposite rear end 126 which comprises a seat 128 (advantageously a transverse hole) for a transverse pin 129. Advantageously, the articulation element 119 can be made, preferably by cutting a sheet or a strip of suitable metal material, with constant thickness in the direction parallel to the pivot axis 116.

In the embodiment shown in Figure 5, the pin 129 is only one, arranged with the opposite ends within the respective facing seats 128 of the two articulation elements 119, so as to connect the two articulation elements 119 at the rear and constitute a support for the thrust of a spring 127 arranged between the two articulation elements 119.

The spring 127 is preferably a helical spring which is arranged side by side and parallel between the elongated bodies 125 of the two joint elements 119, with one end 134 pushing on the pin 129 and an opposite end 133 which reacts on the casing 117, for example thanks to the use of a stop element 130 which is intended to be fastened to the casing similarly to the stop 30 of the previous embodiment.

As described with reference to the previous embodiment, the open and closed positions of the hinge can be advantageously made elastically stable by means of a cam interference of the head surface 139 of the casing 117 against corresponding sliding surfaces 140 on the element 115 during the hinged movement. Similarly, over-opening can also be elastically allowed.

Figure 6 shows the enlarged stop 130 in greater detail. As can be seen in this figure, the stop 130 can be generically U-shaped and can comprise a base part 141 from which a pin 132 protrudes perpendicularly onto which the front end 133 of the spring 127 is inserted, and two opposite side walls 142 elastically spread apart and intended to fit into the front opening of the housing 118. The base part 141 laterally comprises two opposite recesses 131 which allow the passage of at least a portion of the elongated body of the articulation elements 119, so as to allow longitudinal sliding of the two joint elements, as is also clear from figure 7.

In figure 7, the joint elements, the pin, the spring and the stop assembled are shown. As it is clear from Figure 7, the two articulated elements 119 may also have a lowered section 154 between limit switch steps to be received in the recesses 131 and establish the maximum amplitude of the sliding movement of these articulated elements 119 in the hinge.

In this way, the stop 130 can also act as a limit switch allowing the springs to never reach the pack and, consequently, to lose less load with the cyclic use of the glasses, as already described above.

Figure 8 shows a removable capsule 135 for the temporary blocking of the elements shown in Figure 7 and which allows the assembly formed by these elements to be pre-assembled and moved. In particular, the capsule 135 can comprise a pushing finger 137 which protrudes from the capsule towards the stop 130 to push on the stop and keep the spring 127 compressed. Lateral protrusions 136 on the finger 137 or on lateral wings 137a side by side on the two sides of the finger 137 they can elastically engage the slots 121 of the two articulation elements 119 so as to elastically lock the capsule on the assembled group of figure 7, as clearly visible in figure 9. The capsule can advantageously comprise a wide gripping end 138 from which the finger can advantageously protrude 137 and any lateral wings 137a.

As shown in figure 10, the group assembled with the capsule 135 can be easily inserted into the casing 117, for example already fixed on a rod 12, as described for the previous embodiment.

Figure 11 shows a variant embodiment of a hinge according to the invention, in which the stop 130 is made in two parts 130a and 130b (advantageously specular and L-shaped) and the two articulation elements 119 each have a seat (advantageously one elongated slot 155) for guiding said two parts 130a and 130b. Advantageously, in order to slide along the seats 155, the two parts 130a and 130b have teeth 156, 157 protruding oppositely on the sides. The thrust of the spring 127 on the two parts 130a and 130b keeps these two parts close together, as can also be seen in figure 12. When the hinge is also assembled with the casing and the stop is locked in the casing, the two articulation elements 119 can to slide to a limited extent in the casing for a length imposed by the sliding of the teeth 156, 157 in the seats 155, so as to also perform the limit switch function as already described for the previous embodiments. Figure 13 shows a further possible variant embodiment of the stop 130, in which this stop, U-shaped, has opposite lateral protrusions 158, 159 (for example cylindrical shaped) which are inserted into the seats or elongated slots 155 (preferably rounded at the ends to match the lateral shape of the projections 158, 159) to allow the elements to slide along the stop, as is clear from figure 14, and to perform the limit switch function.

The stop 130 can also be made without lateral projections, as is shown for example in Figures 15 and 16, in the event that, for example, a function of limiting the sliding amplitude of the articulation elements 119 and / or not is not required. a guiding function of the sliding of the articulation elements along the stop is necessary in addition to the guiding function offered by the facing walls of the articulation elements 119. In this case, for example, the springs themselves may perform the limit switch function.

Figures 17 (exploded), 18 (partially assembled) and 19 (assembled) show a further embodiment of a hinge according to the invention. For convenience and clarity of presentation, elements similar to those of the first embodiment are indicated with the same numbering increased by 200. In this further embodiment, there is therefore a hinge 213 with a part 214 of the hinge which includes a carcass or "box" 217 which identifies internally a cavity or housing 218 which slidably accommodates two joint elements 219 which have an elongated body 225 and which are arranged parallel to each other to have front ends 220 which protrude forwardly from the cavity in the casing for pivoting to a second part 215 according to the pivoting axis 216. To achieve the pivoting, the front end 220 of the articulation elements 219 preferably has a slot 221 which is crossed by a pin 222 inserted in a suitable seat 223 in the second part 215 of the hinge. Notches 224 can be provided in the hinge part 215 for receiving and laterally guiding the pivot ends of the articulation elements 219.

Unlike the previous embodiments, the casing 217 is of the type open at the bottom (i.e. on the side intended to be against the rod of an eyeglass) to allow the insertion in the cavity of the articulation elements, of a spring 227 and of a rear pin 229. The casing 217 can therefore have the front end of the casing 218 (i.e. the end towards the pivot axis 216 of the hinge) closed to less than two passages or slots 231 for the sliding passage of the elements joint 219 which thus protrude from the casing with their front ends 220. The spring 227 (advantageously a helical spring) and which is received between the articulation elements 219, can thus rest with a front end 233 against an inner surface 230 of the casing between the slots 218. The internal surface 230 can therefore essentially perform the function of the locking element of the previous embodiments.

The rear end 234 of the spring 227, on the other hand, pushes on the pin 229 which is arranged between the rear ends 226 of the articulation elements 219 to have the opposite ends which are accommodated in suitable seats 228. These seats 228 can also be for example open towards the lower opening of the housing 218 to facilitate the lateral assembly of the pin 229. For example, the rear end 226 of the articulation elements 219 can be shaped like a hook to make the open seats 228.

As can be seen clearly in figures 17 and 18, the two articulation elements 219 can be identical to each other and also be advantageously made (for example by shearing from a sheet or strip of metal material) with a constant thickness in the direction parallel to the pivot axis 216.

As described with reference to the previous embodiments and now easily imaginable by the technician, the open and closed positions of the hinge can be advantageously made elastically stable by means of cam interference of the head surface 239 of the casing 217 against corresponding sliding surfaces 240, suitably shaped, present on the element 215. The elastic over-opening can also be easily realized, as already described above.

As can be seen clearly in figures 17 and 19, the casing and the part 215 of the hinge can also be made in their lower part with protrusions or teeth 260, 261 to be easily weldable, by passing electric current, on respective metal parts of the frame. of a pair of glasses, according to a technique known per se and easily imaginable by the skilled technician.

At this point it is clear to the technician how it is possible to easily make hinges with different transversal width, while keeping the joint elements the same and for example simply using pins, pins, carcasses and second part of the hinge of suitable transversal width (i.e. in the direction of the pivot axis).

For example, in figure 20 two hinges according to the invention are shown (generically indicated with 113a and 113b) with such a different transverse width thanks to a different distance between the two joint elements of the previous embodiments of hinges with two joint elements.

The hinges according to the invention can also be easily made with a number of joint elements greater than two, advantageously always keeping said joint elements equal to each other as they are shown and described with reference to the previous embodiments.

By way of example, figures 21 and 22 show a further embodiment of the hinge according to the invention, similar to the embodiment of figure 5 but with three joint elements instead of two. For descriptive convenience, elements similar to the embodiment of Figure 5 will be indicated with the same numbering further increased by 200.

As can be seen clearly in Figure 21, there is therefore a hinge 313 with a part 314 of the hinge which comprises a casing or "box" 317 which internally identifies a cavity or housing 318 open from the front and which slidably accommodates three articulated elements 319 arranged between parallel to them to have front ends 320 projecting forwardly from the housing 317 in the housing for pivoting to a second part 315 along the pivot axis 316. To provide the pivot, the front end 320 of the articulation elements 319 has preferably a slot 321 which is crossed by a pin 322 inserted in a suitable seat 323 in the second part 315 of the hinge. Similarly to the hinge 113, the second part 315 preferably has notches 324 which each receive the front end 320 of one of the articulation elements 319, so as to contain it and guide it laterally. These notches are transversely crossed by the hole that makes the seat 323 for the pin 322.

As in the previous embodiments, the pin 322 can advantageously be made in the form of a screw.

Each joint element 319 can be made substantially the same as the joint element 19 or 119 already described above, and have a body 325 elongated in the sliding direction to have the front end 320 protruding from the housing 318 and an opposite rear end 326 which comprises a seat 328, for example a through hole, for a transverse pin 329 which passes through the central articulation element 319 and ends with opposite ends in the lateral articulation elements 319.

The two areas of the pin 329 between joint elements placed side by side can each constitute a support for a respective thrust spring 327 arranged between said joint elements side by side.

As in the previous embodiments, the springs 327 are preferably helical springs placed between the elongated bodies 325 of the two articulation elements 319, with one end 334 pushing on the pin 329 and an opposite end 333 which reacts on the casing 317, for example thanks to the use of a stop element 330 for each spring. In particular, this stop element can be similar to one of those already described previously and will therefore not be further described here in detail. The two stops 330 can also be joined in one piece, for example with a central sliding slot of the central joint element as shown for the stop 30. Surfaces 339 and 340 can identify the stable positions of open and closed hinge, similarly to previous achievements. Even the elastic over-opening can be easily obtained, if desired, as easily understood by the technician, thanks to the sliding of the joint elements against the action of the springs.

It is now easy to imagine also a pre-assembly capsule (even if not shown), similar to the capsules already described above but suitable for temporarily locking the group formed by three joint elements, pin, springs and stops of the embodiment of figure 21. For example, the capsule can be a combination of the capsules 35 and 135, in order to have pushing fingers on the stops 330 which receive between them the central articulation elements 319 (like the fingers 37 of the embodiment of figure 4) but also with lateral protrusions outside the outermost articulation elements 319 (such as the lateral projections 137a of the embodiment of Figure 8).

If desired, with such a capsule it is possible to move and insert the preassembled unit into the casing 317, as already described above for the previous embodiments.

Figure 22 shows the hinge 313 completely assembled and mounted between a front 11 and a rod 12 of an eyewear.

At this point it is clear how the intended purposes have been achieved. It has been found that a hinge according to the present invention is more robust, even though it is simple to make, assemble and mount on a pair of glasses. In particular, the joint element is sturdy and less prone to breakage during use. Furthermore, this hinge can be easily produced with any number of articulation elements, also advantageously all identical to each other. In this way, it is possible to produce hinges with a plurality of articulation elements in an economical way.

Such articulation elements are moreover easily achievable by simply blanking from a sheet or a strip of suitable material (even if other known manufacturing methods - for example molding - can be used).

Figure 23 shows, for example, a blanking equipment, comprising a matrix 70 and a punch 71, which sequentially cut joint elements of the invention from a strip 72 of suitable material (for example metal). The shape of the articulation elements may of course be different from that shown in figure 23 and for example be provided with seats or slots for sliding the stops or even have the embodiment of figure 17.

In addition to obtaining the articulation elements by means of only blanking operations, if necessary, shaping coining can also be provided, as can now be easily imagined by the technician.

For simplicity, in the embodiments shown here, the two parts of the hinge hinged to each other have been designed coplanar when the rod 12 is in the open position and angled (for example at about 90 °) when the rod is in the closed position. Of course, as easily imagined by the technician, these two parts can however be made with a suitable shape to be mounted on surfaces of the glasses having different inclinations (for example, at right angles when the rod is in the open position). In particular, the hinge part intended to be fixed to the front can be suitably shaped to create hinges with different fixing angles between the two parts of the hinge while the hinge part with the casing is kept parallel to the extension of the rod. Naturally, the above description of embodiments applying the innovative principles of the present invention is given by way of example of these innovative principles and must therefore not be taken as a limitation of the patent scope claimed herein. In particular, the characteristics of the various solutions shown here can be mixed together according to specific needs and desires, as can now be easily imagined by the skilled technician. For example, a casing open at the bottom can be used in place of the casing open at the front and vice versa; the various stops described or their characteristics (presence or absence of guide pins of the springs, lateral guides, passages for the articulation elements, etc.) can be used in the various embodiments, also suitably realizing sliding seats in the various articulation elements that they are free. The different articulation elements can also be used in the various embodiments and the various embodiments can comprise a different number of articulation elements, stops, pins and springs with respect to those shown in the various embodiments, as can now be easily imagined by the technician. The articulation elements can also have a different shape, for example according to the desired dimensions for their articulation end or the desired sliding extent. The entire hinge can be made of suitable metal materials.

External springs can also be provided on the external sides of the joint elements even in embodiments with more than one joint. For example, the two or three joint element embodiments described here may also include further more external springs, by suitably dimensioning the casing and making the transverse pin protrude laterally (as shown for example in the embodiment of Figure 2 with a single joint element) to provide support for these additional springs. As already mentioned above, the means for fixing the hinges to the glasses can of course be of any known type (gluing, screwing, welding, etc.), depending on the specific needs, as easily imagined by the skilled technician. If desired, the two parts of the hinge can also be fixed inverted on the glasses with respect to as shown here.

Finally, the exact shapes and proportions between the various parts can vary according to specific practical needs.

Claims (11)

Claims 1. Spring hinge for spectacles comprising a housing (17, 117, 217, 317) and at least one articulation element (19, 119, 219, 319) projecting forward from the housing (17, 117, 217, 317) with a pivot front end (20, 120, 220, 320) and which has an elongated body (25, 125, 225, 325) which is slidably housed in a housing in the housing (17, 117, 217, 317), the elongated body of the articulation element (19, 119, 219, 319) ending with a rear end (26, 126, 226, 326), opposite the front pivot end, on which at least one spring acts (27, 127, 227, 327) contained in the casing (17, 117, 217, 317) to push the joint element (19, 119, 219, 319) in an opposite direction to its front pivot end (20, 120, 220, 320), characterized by the fact that the articulation element (19, 119, 219, 319) has a seat (28, 128, 228, 328) near its rear end (26, 126, 226, 326), in which it is housed a pin (29, 129, 229, 329) transversal to the extension of the articulation element (19, 119, 219, 319) between the rear end and the front pivot end, and on this pin (29, 129, 229, 329 ) pushes the at least one spring (27, 127, 227, 327). 2. Spring hinge according to claim 1, characterized in that said at least one spring (27, 127, 227, 327) is a helical spring arranged side by side and parallel to the elongated body of the at least one articulation element (19, 119, 219, 319). 3. Spring hinge according to claim 1, characterized in that said at least one spring (27, 127, 227, 327) is a helical spring with a first end (43, 134, 234, 334) which pushes on said pin ( 29, 129, 229, 329) and a second opposite end which reacts on the casing (17, 117, 217, 317). 4. Spring hinge according to claim 3, characterized in that said helical spring has the second end (17, 117, 317) which reacts on the casing (17, 117, 317) by interposition of a stop element (30, 130 , 330) which is attached to the casing (17, 117, 317) near the front pivot end of the articulation element (19, 119, 319). 5. Spring hinge according to claim 2, characterized in that the pin (29, 329) is received in the seat in an intermediate position at its opposite ends to protrude for a portion from opposite sides of the said articulation element and provide a support for the thrust of a helical spring on each of said opposite sides of the joint element. 6. Spring hinge according to claim 1, characterized in that it comprises at least two of said articulation elements (119, 219, 319) arranged parallel and spaced from each other to accommodate said at least one spring between them, with said transverse pin which connects the two articulation elements (119, 219, 319) between the seats and with an area of the pin between the two articulation elements (119, 219, 319) on which the spring pushes. 7. Spring hinge according to claims 4 and 6, characterized in that the stop element (130, 230, 330) is fixed to the casing (117, 217, 317) between the at least two articulation elements (119, 219, 319). 8. Spring hinge according to any of the preceding claims, characterized in that it comprises a plurality of joint elements (19, 119, 219, 319) parallel and equal to each other. 9. Method of manufacturing a hinge for glasses according to any one of the preceding claims, comprising forming the articulation elements (19, 119, 219, 319) by blanking from a metal strip. 10. Method of manufacturing a hinge for glasses according to any one of the preceding claims, comprising forming a preassembled group by means of the steps of: -assemble the said pin (29, 129, 229, 329) on the at least one joint element (19, 119, 219, 319) and the at least one spring (27, 127, 227, 327) to push on the pin; And -insert on the front pivot end a temporary locking capsule (35,135) which engages the pivot front end of the at least one articulation element (19, 119, 219, 319) and pushes the at least one spring (27, 127 , 227, 327) to keep the spring in position against said pin (29, 129, 229, 329), before introducing the at least one articulation element and the at least one spring into the housing in the casing (17, 117, 217, 317), in the sense of allowing the movement of the at least one articulation element with the at least one spring separated from the casing. 11. Method of assembling a hinge according to claim 10, characterized in that it comprises the steps of inserting part of the preassembled group with the at least one articulation element (19, 119, 219, 319) and the at least one spring (27, 127, 227, 327) within the housing in the casing (17, 117, 217, 317) and then removing said temporary locking capsule (35, 135) from said preassembled assembly.