Hinge for eyeglasses

A hinge, particularly for rotatably coupling two parts of a pair of eyeglasses preferably made of plastics. The hinge is constituted by at least one first element, which merely allows the mutual positioning of the two components, and by at least one separate second element, which allows the mutual and temporary rotary coupling of the two parts.

BACKGROUND OF THE INVENTION 
The present invention relates to a hinge, particularly for rotatably 
coupling two components of a pair of eyeglasses preferably made of 
plastics. 
Eyeglasses are currently known in which the temples, made for example of 
metal or acetate, are associated with the front, which is made of the same 
materials, by interposing a metallic hinge that is constituted by a first 
element, such as a perforated lug that is partially embedded in the front, 
and by a second element, constituted by two perforated shoulders that 
protrude from the tip of the temple; the first and the second elements are 
associated one another by a pivot. 
The insertion of the pivot therefore allows to achieve both the positioning 
and the rotary coupling between the temple and the front. 
However, these conventional hinges are not free from drawbacks: the pivot 
must have minimal tolerances to ensure the precise coupling between the 
temple and the front, and said tolerances, in view of the extremely small 
size of the pivot, require expensive precision machining operations; 
moreover, a certain time is required to assemble the hinge to the 
components of the eyeglasses, and this entails an increase in the 
production cost. 
Another conventional solution entails, if the front and the temples are 
made of plastics, a direct coupling between the front and the temple of a 
pair of eyeglasses without using an interposed coupling hinge; said 
coupling is provided by means of two L-shaped flaps that are arranged in a 
mirror-symmetrical fashion with respect to a median plane lying 
longitudinally to said temple and protrude longitudinally and 
perimetrically from the tip of the temple. 
Said two flaps can be arranged at two seats formed proximate to the lateral 
end of the front that can be arranged adjacent to the temple. 
However, this conventional solution, too, has drawbacks: the center 
distance between the two seats formed on the front can be different from 
the one calculated for optimum coupling in relation to the center distance 
of the two flaps, thus entailing difficulty in coupling the temple to the 
front. 
This requires the mutual positioning of the flaps and of the seats to be 
calculated with a certain precision: an excessive center distance could in 
fact lead to difficulty in mutually coupling the front and the temple, 
causing easy breakage of the two parts during assembly or during 
replacement of one of them, whereas an insufficient center distance would 
lead to easy disengagement between the temple and the front; the smaller 
the center distance, the easier this can be achieved. 
Regardless of the above-mentioned drawbacks, the direct mutual coupling of 
the front and the temple, without using a hinge, occurs by elastic 
deformation of the end of the temples that is associable with the front; 
this entails that an excessive pressure applied at said end facilitates 
the breakage of the temples or of the flaps associated therewith during 
coupling to the front. 
The difficulty in achieving optimum mutual pivoting of the temple and of 
the front in the above described solution is increased by the fact that 
the two seats for the two flaps must be formed on the front by using an 
insert in the mold provided with two undercuts. 
SUMMARY OF THE INVENTION 
The aim of the present invention is therefore to solve the described 
problems, eliminating the drawbacks of the cited prior art, by providing a 
hinge that allows to achieve rotary coupling between two parts of a pair 
of eyeglasses, said coupling being obtainable in an optimum manner with 
good precision in the placement of the two components and in their 
rotatable fixing. 
Within the scope of this aim, an important object is to provide a hinge 
having considerable impact resistance. 
Another object is to provide a hinge that allows to assemble and 
disassemble the parts of the pair of eyeglasses simply and rapidly, 
allowing to perform these operations repetitively without affecting the 
integrity of the components of the pair of eyeglasses. 
Another object is to provide a hinge that has a low cost and can be 
produced with conventional machines and equipment. 
This aim, these objects, and others that will become apparent hereinafter 
are achieved by a hinge, particularly for rotatably coupling two parts of 
a pair of eyeglasses, characterized in that it is constituted by at least 
one first element that merely allows the mutual positioning of said two 
components and by at least one separate second element that allows the 
mutual and temporary rotary coupling of said two parts.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
With reference to the above figures, the reference numeral 1 designates a 
first part of a pair of eyeglasses; in the particular embodiment 
illustrated, said part is a temple, which has a for example rectangular 
shape in plan view, is preferably made of plastics, and can be coupled to 
a second part, such as a front, designated by the reference numeral 2. 
The temple 1 has a first end 3 that can be arranged adjacent to the front 2 
at a second lateral end 8 thereof. 
A first upper flap 4a and a second lower flap 4b protrude at right angles 
to the first end 3; said flaps are mutually identical and are arranged on 
planes that are parallel to each other and to a plane that passes through 
the upper surface 50 of the temple 1; said first and second flaps 4a and 
4b are approximately as wide as said temple 1 is thick. 
A first element 5a protrudes from the free end of the first upper flap 4a, 
at right angles to, and away from, the second lower flap 4b, and is 
preferably constituted by a cylindrical pin having a chamfered upper end. 
A second flexible element 5b protrudes from the second lower flap 4b 
towards the first flap 4a and along the same axis as the first element 5a. 
The second element 5b is constituted by a cylindrical stem 6a the diameter 
whereof is approximately equal to the diameter of the first element 5a; a 
frustum-shaped head 6b is associated, in an upward region, with the stem 
6a and has a base diameter that is greater than the diameter of the stem 
6a, thus protruding perimetrically from said stem. 
Said second element 5b has a first diametrical recess 7 the length whereof 
is such as to allow the elastic deformation of said second element 5b, so 
as to temporarily reduce the base dimensions of said element. 
The second end 8 of the front 2 has a first hollow 9a and a second hollow 
9b that are mutually identical, are essentially shaped like a 
parallelepiped, and are formed adjacent to each other starting from the 
inner lateral surface of the front 2. 
The first hollow 9a and the second hollow 9b have such dimensions as to 
allow the insertion of the first and second elements 5a and 5b, which are 
associated respectively with the first flap 4a and with the second flap 
4b; a base 10 is formed between the first hollow 9a and the second hollow 
9b, and the height of said base is greater than the distance between the 
second element 5b and the first flap 4a and is approximately equal to the 
height of the stem 6a of the second element 5b. 
The second end 8 also has a hole 11 which, starting from the lower 
perimetric edge 12 of the front 2, and by passing through the first hollow 
9a and the second hollow 9b and the base 10 along an axis that is 
approximately parallel to the axis of the first and second elements 5a and 
5b, affects part of the thickness of the upper perimetric edge 13 of said 
front 2. 
Said hole 11, the diameter whereof is equal to the diameter of the first 
element 5a and of the stem 6a, forms a first seat 14a, which is shaped 
complementarily with respect to the first element 5a and is located 
proximate to the upper perimetric edge 13, a second cylindrical seat 14b 
at the base 10, and a second recess 15 at the lower perimetric edge 12. 
Operation is as follows: the first end 3 of the temple 1 is placed adjacent 
to the second end 8 of the front 2, inserting the first and second flaps 
4a and 4b at the first and second hollows 9a and 9b, so that the first 
flap 4a rests above the base 10; the first element 5a is thus positioned 
at the first seat 14a, thus determining the mutual positioning of the 
temple 1 and of the front 2; simultaneously, the second element 5b is 
inserted in the second seat 14b with a snap action and the second element 
5b is positioned so that the outer perimetric edge of the head 6b abuts 
against the upper surface of the base 10 in order to allow rotation of the 
temple but not its disengagement from the front unless it is forced by 
means of an adapted tool. 
It has been observed that the hinge thus conceived has achieved the 
intended aim and objects, since the first element allows only mutual 
positioning of the two parts of the pair of eyeglasses, which are 
constituted by a temple and a front in the particular embodiment, and the 
second element allows the mutual and temporary rotary coupling of said two 
parts; said hinge furthermore has considerable impact resistance and is 
easy to assemble and disassemble; moreover, disassembly can be performed 
by means of an appropriate tool that allows to deform the head 6b, 
disengaging the second element from the second seat and thus disengaging 
the temple from the front. 
The coupling between the parts can be achieved in an optimum manner with 
extreme precision in the positioning of the two parts and in their fixing. 
Furthermore, the elastic deformations affecting the hinge during coupling 
and uncoupling are very limited, considerably reducing the possibilities 
of breakage occurring because the elasticity limit is exceeded. 
By acting like a spring, the second element 5b furthermore allows to 
eliminate any plays, thus ensuring correct friction against the base 10 
during mutual rotation. 
The invention is of course susceptible of numerous modifications and 
variations, all of which are within the scope of the same inventive 
concept. 
Thus, for example, in an equivalent manner, if the pair of eyeglasses 
includes a temple constituted by a first and a second pieces, said pieces 
can be likened to the first and second parts and therefore be associated 
by interposing a hinge according to the invention. 
Likewise, if the front of a pair of eyeglasses is constituted by two 
mutually identical parts, they can be associated by interposing a hinge 
according to the invention, which must be symmetrical with respect to a 
median plane that lies transversely to the pair of eyeglasses. 
FIGS. 5 and 6 illustrate a second embodiment of a hinge for rotatably 
coupling a first end 103 of a temple 101 and a second lateral end 108 of a 
front 102. 
A first flap 104a and a second flap 104b protrude, on mutually parallel 
planes, at right angles to the second end 108; a first element 105a and a 
second element 105b respectively protrude at right angles to said first 
and second flaps 104a and 104b along the same axis and above said flaps. 
The first element 105a, which is constituted by a pivot, and the second 
element 105b, which is flexible and mushroom-shaped, can be inserted at a 
first hollow 109a and at a second hollow 109b that are formed in the first 
end 103 starting from the inner lateral surface of the temple 101. 
A base 110 is formed between the first hollow 109a and the second hollow 
109b. 
The temple 101 furthermore has a first seat 114a and a second seat 114b 
that are formed by a single hole 111 which, starting from the lower 
perimetric edge 120 of the temple 101, affects the first and second 
hollows 109a and 109b, the base 110, and part of the thickness of the 
upper perimetric edge 121. 
By placing the first end 103 adjacent to the second end 108 and by 
inserting the first element 105a in the first seat 114a, it is possible to 
mutually position the front 102 and the temple 101 quickly and simply, 
whereas the simultaneous snap insertion of the second element 105b in the 
second seat 114b allows the temple 101 to rotate but not to disengage from 
the front 102. 
This solution, too, allows to achieve the intended aim and objects. 
FIGS. 7 and 8 illustrate a third embodiment of a hinge for rotatably 
coupling a first end 203 of a temple 201 and a second lateral end 208 of a 
front 202. 
This solution provides for two first elements 205a and 205b, which protrude 
from two first flaps 204a and 204b associated at right angles with the 
first end 203 of the temple 201, and for a second element 205c that 
protrudes at right angles, and along the same axis as the two first 
elements 205a and 205b, from a third flap 204c arranged below the two 
first flaps 204a and 204b. 
The second end 208 has three hollows 209a, 209b, and 209c that are mutually 
identical and have such dimensions as to allow the insertion of the two 
first elements 205a nd 205b and of the second element 205c that are 
associated with the two first flaps 204a and 204b and with the second flap 
204c. 
By means of a single hole 211, starting from the lower perimetric edge 212 
of the front 202 and with an axis that is approximately parallel to the 
axis of the two first elements 205a and 205b, there are provided two first 
seats 214a and 214b, which are shaped complementarily to the two first 
elements 205a and 205b, and a second seat 214c, which allows the snap 
insertion of the second element 205c. 
By arranging the first end 203 adjacent to the second end 208, the 
insertion of the two first elements 205a and 205b in the two first seats 
214a and 214b allows to mutually position the front 202 and the temple 
201, whereas the simultaneous snap insertion of the second element 205b in 
the second seat 214c allows the temple 201 to rotate but not to disengage 
from the front 202. 
This solution, too, allows to achieve the intended aim and objects. 
FIGS. 9 and 10 illustrate a fourth embodiment of a hinge for rotatably 
coupling a first end 303 of a temple 301 and a second lateral end 308 of a 
front 302. 
This solution provides for a first element 305a, which is constituted by a 
cylindrical pivot interposed between two first flaps 304a and 304b that 
protrude at right angles from the first end 303 of the temple 301, and for 
a second element 305b, which protrudes from the first end 303 at right 
angles to a second flap 304c arranged below the two first flaps 304a and 
304b and parallel thereto. 
Three hollows 309a, 309b, and 309c are formed at the second end 308 of the 
front 302, and a first upper base 310a and a second lower base 310b are 
formed between said hollows. 
A first seat 314a is formed at the first upper base 310a and is constituted 
by a recess which, starting from the free end, is arranged along the 
longitudinal median axis; said first seat 314a is adapted to contain the 
first element 305a, since its width is equal to the outside diameter of 
the pivot. 
The second element 305b can be inserted with a snap action at a second seat 
314b formed on the second lower base 310b along an axis that is 
approximately parallel to the axis of said second element 305b. 
By arranging the first end 303 adjacent to the second end 308 and by 
inserting the first element 305a in the first seat 314a, the front 302 and 
the temple 301 are mutually positioned, whereas by simultaneously 
inserting, with a snap action, the second element 305b in the second seat 
314b the rotation of the temple 301 is allowed but its uncoupling from the 
front 302 is not. 
This solution, too, allows to achieve the intended aim and objects. 
FIGS. 11 and 12 illustrate a fifth embodiment of a hinge for rotatably 
coupling a first end 403 of a temple 401 and a second lateral end 408 of a 
front 402. 
This solution provides for a first element 405a that protrudes at right 
angles and upwardly from a first flap 404a that is associated at right 
angles to the first end 403. 
A second flap 404b is arranged at right angles to the first end 403 and 
above the first flap 404a, and a second mushroom-shaped element 405b 
protrudes from said flap 404b; said mushroom-shaped element is constituted 
by a stem 406a associated with a head 406b that protrudes perimetrically 
from said stem 406a and has a diametrical recess that allows its elastic 
deformation. 
A first tab 416a and a second tab 416b protrude at right angles from the 
second end 408; both tabs are L-shaped and are constituted by a third flap 
417a and by a fourth flap 417b that are associated at right angles to the 
second end 408; a first hollow cylinder 418a and a second hollow cylinder 
418b protrude downwardly from said third and fourth flaps along a same 
axis that is perpendicular thereto; said cylinders are adapted to 
internally form a first seat 414a and a second seat 414b that are shaped 
complementarily with respect to the first element 405a and to the stem 406 
of the second element 405b. 
By placing the first end 403 adjacent to the second end 408 and by 
inserting the first element 405a in the first seat 414a, the front 402 and 
the temple 401 can be mutually positioned, whereas by means of the 
simultaneous snap insertion of the second element 405b in the second seat 
414b and through the protrusion of the head 406b above said second seat 
414b, the temple 401 is allowed to rotate but not to disengage from the 
front 402. 
This solution, too, allows to achieve the intended aim and objects. 
FIGS. 13 and 14 illustrate a sixth embodiment of a hinge for rotatably 
coupling a first end 503 of a temple 501 and a second lateral end 508 of a 
front 502. 
Two first flaps 504a and 504b protrude at right angles to the second end 
508 and are arranged on parallel planes; a first element 505a protrudes 
from the upper flap in a downward direction and along a perpendicular axis 
and is shorter than the center distance between said two first flaps 504a 
and 504b. 
The lower flap of the two first flaps 504a and 504b has a first seat 514 
that is formed by a hole having the same axis as the first element 505a. 
A second flap 504c protrudes at right angles to the first end 503, and a 
second element 505b is associated with said second flap in an upward 
region and along a perpendicular axis. 
Said second element 505b is constituted by a cylindrical hollow stem 506a 
the diameter whereof is approximately equal to the diameter of the first 
seat 514; said stem is associated with a frustum-shaped hollow head 506b 
the base diameter whereof is greater than the outside diameter of the stem 
506a. 
By placing the first end 503 adjacent to the second end 508 and by 
inserting the second element 505b in the first seat 514, and by partially 
inserting the free end of the first element 505a in the cavity of the 
second element 505b at the head 506b, the front 502 and the temple 501 are 
mutually positioned, whereas by means of the simultaneous snap insertion 
of the second element 505b in the first seat 514 the temple 501 is allowed 
to rotate but not to disengage from the front 502. 
his solution, too, allows to achieve the intended aim and objects. 
FIGS. 15 and 16 illustrate a seventh embodiment of a hinge for rotatably 
coupling a first end 603 of a temple 601 and a second lateral end 608 of a 
front 602. 
A first flap 604a and a second flap 604b protrude at right angles to the 
first end 603; said flaps are arranged on mutually parallel planes, and a 
first element 605a and a second element 605b are associated with said 
flaps and are arranged along a same axis that is perpendicular to said 
first and second flaps 604a and 604b. 
The second element 605b is essentially T-shaped, with a cylindrical stem 
606a that is associated with an equally cylindrical head 606b. 
A third flap 617a and a fourth flap 617b protrude at right angles to the 
second end 608 and are arranged on mutually parallel planes. 
Said third and fourth flaps 617a and 617b have, proximate to their free 
end, a first seat 614a and a second seat 614b that are constituted by a 
first hole and a second hole which have the same diameter and are formed 
along a same axis that lies at right angles to said third and fourth flaps 
617a and 617b. 
The third and fourth flaps 617a and 617b have, at the free end, an opening 
that is formed along a longitudinal plane and gives said end a C-like 
shape that allows elastic deformation for coupling, with or without a snap 
action, to said first and second elements 605a and 605b. 
By arranging the first end 603 adjacent to the second end 608 and by 
inserting the first element 605a in the first seat 614a, through the 
opening formed in the free end of the fourth flap 617b, it is possible to 
mutually position the front 602 and the temple 601, whereas by means of 
the simultaneous snap insertion of the second element 605b in the second 
seat 614b the temple 601 can be rotated but not disengaged from the front 
602. 
This solution, too, allows to achieve the intended aim and objects. 
FIGS. 17 and 18 illustrate an eighth embodiment of a hinge for rotatably 
coupling a first end 703 of a temple 701 and a second lateral end 708 of a 
front 702. 
A first flap 704a protrudes at right angles to the first end 703 and is 
arranged proximate to the lower perimetric edge 720 of the temple 701. 
A substantially cylindrical element 705 protrudes at right angles to the 
first flap 704a and above it and is constituted by an axially flexible 
central body 760a, by a first lower body 760b, and by a second upper body 
760c. 
The central body 760a has two mutually opposite truncated cones whereon a 
plurality of longitudinal slits are provided which allow said central body 
760a to temporarily increase its dimensions in plan view and thus allow 
the second upper body 760c to move axially. 
Two second flaps 704b and 704c protrude at right angles to the second end 
708, are arranged on mutually parallel planes, and have a center distance 
that is approximately equal to the height of the central body 760a. 
Proximate to their free end, the two second flaps 704b and 704c 
respectively have a first seat 714a and a second seat 714b that are 
constituted by a first hole and by a second hole having the same axis, 
which is perpendicular to said two second flaps 704b and 704c. 
By arranging the first end 703 adjacent to the second end 708 and by 
inserting the first element 705 in the first seat 714a, it is possible to 
mutually position the front 702 and the temple 701, whereas by means of 
the subsequent insertion of the second upper body 760c in the second seat 
714b and through the simultaneous snap insertion of the central body 760a 
between the second flap 704b and the second flap 704c, the temple 701 is 
allowed to rotate but not to disengage from the front 702. 
This solution, too, allows to achieve the intended aim and objects. 
In another embodiment, the first element that allows the mutual positioning 
of the two parts may have, if it preferably has a cylindrical shape, a 
radial knurling that interacts with a complementarily shaped knurling 
formed at the first seat, whereat it can be positioned; this allows to 
achieve, once the parts have been joined, a micrometric rotation, for 
example of the temple with respect to the front. 
As an alternative, said knurling and said complementarily shaped seat can 
be formed for example at the stem of the second element that allows the 
mutual temporary rotary coupling of the two parts. 
FIGS. 19, 20, and 21 illustrate a further embodiment of a hinge for 
rotatably coupling a first end 803 of a temple 801 and a second lateral 
end 808 of a front 802. 
A first upper flap 804a and a second lower flap 804b protrude from the 
first end 803 and are arranged parallel to each other; each flap has a 
first through hole 811a arranged along a same axis lying at right angles 
to said flaps. 
A first hollow 809a and a second hollow 809b are formed at the second end 
808, are mutually identical, are substantially shaped like a 
parallelepiped, and are formed so as to be mutually adjacent starting from 
the inner lateral surface of the front 802. 
A base 810 is formed between the first and the second hollows, whereas a 
second hole 811b is formed at the second end 808; starting from the lower 
perimetric edge 812 of the front 802, said second hole passes through the 
first hollow 809a, the second hollow 809b, and the base 810 along the same 
axis as the hole formed on the first and second flaps 804a and 804b once 
the temple and the front have been mutually associated. 
Said hole 811 forms a first seat 814a proximate to the upper perimetric 
edge 813 of the front 802. 
A single element allowing the mutual positioning of the two parts of the 
pair of eyeglasses and their mutual temporary rotary coupling can be 
arranged at the first hole 811a and at the second hole 811b; said element 
is constituted by an essentially cylindrical pivot 830 the diameter 
whereof approximately matches the diameter of said first and second holes; 
said pivot has, in an approximately median region, one or more flexible 
radial flaps 831 which, once they have passed at said hole formed on said 
base 810, lock above said base. 
The materials and the dimensions constituting the individual parts of the 
device may of course also be the most appropriate according to the 
specific requirements.