ITVI20130106A1 - HINGE FOR THE TURNTABLE HANDLING OF A DOOR - Google Patents

Description

HINGE FOR THE ROTATING HANDLING OF A DOOR

DESCRIPTION

Field of application

The present invention is generally applicable to the technical sector of closing or damping / control hinges, and particularly relates to a hinge for the revolving movement of a door, in particular but not exclusively an armored door.

State of the art

As is known, closing or cushioning hinges generally comprise a movable element, usually fixed to a door, a leaf or the like, hinged on a fixed element, usually fixed to the supporting frame of the latter, or to a wall and / or to the floor.

More specifically, in the case of concealed hinges for armored doors or similar, the fixed element of the hinges is inserted inside a tubular support structure which includes a rear subframe anchored to a wall or similar support and an anchored front frame. to the subframe.

The mobile element, then, generally includes a fixing wing that can be anchored to the door intended to come out of the tubular support structure in the open position and to re-enter completely inside the tubular support structure in the closed position.

Generally, these hinges are purely mechanical, and do not allow any type of adjustment of the opening angle of the door or in any case any control of the movement of the door itself.

Examples of such known hinges are illustrated in documents US5075928 and WO2010049860. The absence of control makes these hinges extremely dangerous, since due to the huge mass of the armored door there is the danger of unhinging the door itself or bending of the tubular support structure to which the hinge is anchored.

Also due to the huge mass of the armored door, the hinge tends to lose its initial position and / or to disassemble.

Furthermore, adjusting the door position is tiring and complicated. In addition, at least two operators are required to carry out the same.

Another recognized drawback of these hinges lies in the high friction that develops between the fixed and mobile element, which leads to premature wear and frequent breakages, with the consequent need for continuous training.

Presentation of the invention

The object of the present invention is to at least partially overcome the drawbacks encountered above, by providing a hinge with high functionality, constructive simplicity and low cost.

Another object of the invention is to provide a hinge which allows to control the movement of the door in opening and / or closing.

Another object of the invention is to provide a sturdy and reliable hinge.

Another object of the invention is to provide a hinge with extremely limited overall dimensions.

Another object of the invention is to provide a hinge which ensures automatic closing of the door from the open door position.

Another object of the invention is to provide a hinge capable of supporting even very heavy doors and frames.

Another object of the invention is to provide a hinge which has a minimum number of constituent parts.

Another object of the invention is to provide a hinge capable of maintaining the exact closing position over time.

Another object of the invention is to provide a hinge which is safe.

Another object of the invention is to provide a hinge which is easy to install.

Another object of the invention is to provide a hinge which simplifies the maintenance and / or replacement operations thereof.

Another object of the invention is to provide a hinge which allows a simple adjustment of the door to which it is connected.

Another object of the invention is to provide a hinge that is reversible, that is, it can be used straight or upside down without changing its behavior.

These purposes, as well as others which will appear more clearly in the following, are achieved by a hinge having one or more of the characteristics described and / or claimed and / or illustrated herein.

Advantageous embodiments of the invention are defined in accordance with the dependent claims.

Brief description of the drawings

Further characteristics and advantages of the invention will become more evident in the light of the detailed description of some preferred but not exclusive embodiments of a hinge 1, illustrated by way of non-limiting example with the aid of the accompanying drawing tables in which:

FIG.1 is an exploded view of a first embodiment of hinge 1;

FIGS. 2a and 2b are respectively axonometric and top views of the embodiment example of hinge 1 of FIG.1 in closed configuration;

FIGS. 3a and 3b are respectively axonometric and top views of the embodiment example of hinge 1 in open configuration;

FIG. 4 is a schematic view of the pin 40 - cam 51 - interface element 62 - elastic contrast element 61 assembly that can be used in the example of embodiment of hinge 1 of FIG.1;

FIGS. 5 and 6 are respectively side views of a first embodiment of the interface element 62 and of the pin 40 which can be used in the embodiment of the hinge 1 of FIG.1;

Figures 7a, 7b and 7c are respectively lateral views, sectioned along a plane VIIb - VIIb and sectioned along a plane VIIc - VIIc of the example of embodiment of hinge 1 of FIG.1 which includes the first example of embodiment of the element interface 62 and pin 40 of FIGS. 5 and 6, the hinge being in a closed configuration;

FIGS. 8a, 8b and 8c are respectively lateral views, sectioned along a plane VIIIb - VIIIb and sectioned along a plane VIIIc - VIIIc of the example of embodiment of hinge 1 of FIG.1 which includes the first example of embodiment of the interface element 62 and pin 40 of FIGS. 5 and 6, the hinge being in a partially open configuration;

FIGS. 9a, 9b and 9c are respectively lateral views, sectioned along a plane IXb - IXb and sectioned along a plane IXc - IXc of the example of embodiment of hinge 1 of FIG. 1 which includes the first embodiment of the interface element 62 and the pin 40 of FIGS. 5 and 6, the hinge being in a totally open configuration;

FIGS. 10a and 10b are side views of a second embodiment of the pin 40 usable in the embodiment example of hinge 1 of FIG.1;

FIG. 10c is a side view of a second embodiment of the interface element 62 usable in the embodiment example of hinge 1 of FIG.1;

Figures 11a, 11b, 11c and 11d are respectively lateral views, sectioned along a plane XIb - XIb, sectioned along a plane XIc - XIc and sectioned along a plane XId - XId of the example of realization of hinge 1 of FIG.1 which includes the second embodiment of the pin 40 of FIGS. 10a, 10b and of the interface element 62 of FIG. 10c, the hinge being in a closed configuration;

FIGS. 12a, 12b, 12c and 12d are respectively lateral views, sectioned along a XIIb - XIIb plane, sectioned along a XIIc - XIIc plane and sectioned along a XIId - XIId plane of the example of realization of hinge 1 of FIG. 1 which includes the second embodiment of the pin 40 of FIGS. 10a, 10b and of the interface element 62 of FIG. 10c, the hinge being in a partially open configuration;

FIGS. 13a, 13b, 13c and 13d are respectively lateral views, sectioned along a plane XIIIb - XIIIb, sectioned along a plane XIIIc - XIIIc and sectioned along a plane XIIId - XIIId of the example of embodiment of hinge 1 of FIG. 1 which includes the second embodiment of the pin 40 of FIGS. 10a, 10b and of the interface element 62 of FIG. 10c, the hinge being in a totally open configuration;

FIG.14 is an exploded view of a second embodiment of hinge 1;

FIGS. 15a and 15b are axonometric views of the example of embodiment of hinge 1 of FIG. 14 respectively in closed and open configuration;

FIGS. 16a and 16b are respectively axonometric and top views of the embodiment example of hinge 1 of FIG. 14 in which the movable element 20 is mounted on a door D and the fixed element 10 is mounted on a frame F, the door D being in a closed configuration;

FIGS. 16c and 16d are respectively axonometric and top views of the embodiment example of hinge 1 of FIG. 14 in which the movable element 20 is mounted on a door D and the fixed element 10 is mounted on a frame F, the door D being in an open configuration;

Figures 17a, 17b and 17c are respectively seen from above, sectioned along a plane XVIIb -XVIIb and sectioned along a plane XVIIc - XVIIc of the example of embodiment of hinge 1 of FIG.14, the hinge being in closed configuration;

FIG. 17d is an enlarged view of some details of FIG. 17b, with in FIG. 17 is an exploded view of these details;

FIG. 17f is an enlarged view of further details of FIG. 17b, with in FIG. 17g an exploded view of these details;

FIG. 17h is an exploded axonometric view of an embodiment of the hinge 1 similar to that illustrated in FIG. 14, in which the hinge body 11 is integral with the counterplate 102; FIG. 17i is an axonometric view of the hinge body 11 of the embodiment of the hinge 1 of FIG.17h;

FIG.18 is an exploded view of a third embodiment of hinge 1;

FIGS. 19a and 19b are axonometric views of the example of embodiment of hinge 1 of FIG. 18 respectively in closed and open configuration;

FIGS. 20a and 20b are respectively axonometric and top views of the embodiment example of hinge 1 of FIG. 18 in which the movable element 20 is mounted on a door D and the fixed element 10 is mounted on a frame F, the door D being in a closed configuration;

FIGS. 21a and 21b are respectively axonometric and top views of the embodiment example of hinge 1 of FIG. 18 in which the movable element 20 is mounted on a door D and the fixed element 10 is mounted on a frame F, the door D being in an open configuration;

FIGS. 22a, 22b, 22c and 22d are respectively seen from above, sectioned along a plane XXIIb - XXIIb, sectioned along a plane XXIIc - XXIIc and sectioned along a plane XXIId - XXIId of the example of realization of hinge 1 of FIG. 18, the hinge being in a closed configuration; FIGS. 23a, 23b, 23c and 23d are respectively seen from above, sectioned along a plane XXIIIb - XXIIIb, sectioned along a plane XXIIIc - XXIIIc and sectioned along a plane XXIIId - XXIIId of the example of realization of hinge 1 of FIG. 18, the hinge being in a first partially open configuration;

FIGS. 24a, 24b, 24c and 24d are respectively seen from above, sectioned along a plane XXIVb - XXIVb, sectioned along a plane XXIVc - XXIVc and sectioned along a plane XXIVd - XXIVd of the example of realization of hinge 1 of FIG. 18, the hinge being in a second partially open configuration;

FIGS. 25a, 25b, 25c and 25d are respectively seen from above, sectioned along a plane XXVb - XXVb, sectioned along a plane XXVc - XXVc and sectioned along a plane XXVd - XXVd of the example of realization of hinge 1 of FIG. 18, the hinge being in a totally open configuration;

Figure 26 is an exploded view of a fourth embodiment of hinge 1;

FIGS. 27a and 27b are axonometric views of the example of embodiment of hinge 1 of FIG. 26 respectively in closed and open configuration;

FIGS. 28a, 28b and 28c are sectional views along a plane XXVIIIa - XXVIIIa of the embodiment example of hinge 1 of FIG.16 respectively in closed, partially open and totally open configuration;

FIG.29 is an exploded view of a fifth embodiment of hinge 1;

FIGS. 30a and 30b are sectional views along respective planes XXXa - XXXa and XXXb - XXXb of the example of embodiment of hinge 1 of FIG.29 in closed configuration;

FIGS. 30a, 30b and 30c are top, side and front views respectively of the hinge body 11 of the embodiment example of hinge 1 of FIG.29;

Figure 32 is a front view of the bush 70 of the fifth embodiment example of hinge 1 of Figure 29;

FIGS. 33a, 33b, 33c and 33d are lateral views respectively, sectioned along a plane XXXIIIb - XXXIIIb, sectioned along a plane XXXIIIc - XXXIIIc and enlarged of the example of embodiment of hinge 1 of FIG. 29 in an operative configuration.

Detailed description of some preferred embodiments With reference to the aforementioned figures, the hinge according to the invention, generally indicated with 1, will be particularly useful for the possibly controlled rotating movement in opening and / or closing of a closing element D, such as for for example an armored door, which can be anchored to a stationary support structure, such as a wall, a floor or a ceiling.

In a preferred but not exclusive embodiment, as illustrated in FIGS. from 1 to 17c, the hinge 1 can be inserted concealed in a tubular support structure, which can be formed in a per se known way by a rear counterframe CF, which can be anchored to the wall W or similar support, and by a front frame F anchored to the counter frame CF.

In particular, in a first embodiment illustrated in FIGS. from 1 to 13d, the hinge 1 can be anchored to the frame F by means of the plate P1, kept in the operative position by the screw means V1.

On the other hand, in a second embodiment illustrated in FIGS. from 14 to 17c, the hinge 1 can be configured as a retractable "anuba" hinge, anchored to the frame F by means of the plate P2.

In both embodiments, the hinge 1 can be retractively inserted into the tubular support structure formed by the rear counter frame CF and the front frame F.

On the other hand, in FIGS. 18 to 33d illustrate some embodiments of the non-retractable hinge 1.

In particular, the embodiment illustrated in FIGS. 18 to 25d is a hinge of the "anuba" type adapted to be mounted externally to a door, for example an armored door, as illustrated for example in FIGS. from 20a to 21b.

On the other hand, FIGS. 26 to 33d illustrate hinges adapted to be mounted in view on the frame of a door. The embodiment illustrated in FIGS. 26 to 28c differs from that illustrated in FIGS. 29 to 33d due to the fact that the latter has means for adjusting the position of the door when it is in the closed position.

The above embodiments have some common features or sets of features and some features or sets of features unique to certain embodiments. Unless otherwise specified, the common characteristics will be referred to generically with a single identification number, and the peculiar characteristics of one or more embodiments will be specified.

Conveniently, the hinge 1 may comprise a fixed element 10, which can be fixed to the stationary support W, for example by means of the frame F or the counter frame CF, on which a movable element 20 rotatable around a longitudinal axis X, which can be substantially vertical, is hinged. , between an open position, illustrated for example for the above first embodiment in FIGS. 3a, 3b, and a closed position, illustrated for example for the same embodiment in Figures 2a and 2b.

Advantageously, the fixed element 10 may include a box-shaped hinge body 11 which can be anchored to the stationary support W, while the mobile element 20 may include fastening means 21 to the door D.

In the embodiments of the hinge 1 illustrated in FIGS. from 1 to 17c the box-shaped hinge body 11 can be retracted into the tubular support structure formed by the rear counterframe CF and the front frame F, while the fastening means 21 can be defined by a fastening wing designed to protrude from the tubular support structure in the open door position D, as illustrated for example in FIGS. 16c and 16d, and to return inside the same in the position of door D closed, as shown for example in Figures 16a and 16b.

In particular, in the first embodiment illustrated in FIGS. from 1 to 13d the fixing wing 21 can be configured according to the teachings of the Italian patent application VI2012A000156, in the name of the same Applicant, and can therefore have a substantially "C" shape, with a central portion 22 able to be connected with the door D by means of the fixing bracket 30 and a pair of end portions 23, 23 'mutually facing each other and operatively connected with the box-like body 11.

On the other hand, the fixing wing 21 of the hinge 1 of the embodiment illustrated in FIGS. 14 to 17c is rotatably connected to the hinge body 11 by means of the pin 40, which will be better described later.

Also in the embodiment illustrated in FIGS. from 18 to 25d the fastening means 21 to the door D are defined by a fixing wing, rotatably connected to the hinge body 11 by the pin 40.

In the embodiments illustrated in FIGS. from 26 to 33d, on the other hand, the fastening means 21 are defined by a pair of cheeks 24, 24 'suitable for mutually cooperating to lock the door D.

In all embodiments of the hinge 1 illustrated in FIGS. from 1 to 33d, the hinge body 11 may include a through seat 12 defining the X axis within which the pin 40 is inserted with minimum play, which can be connected to the fastening means 21.

Depending on the embodiment of the hinge 1, the pin 40 will have one or both ends 41 mutually connected with the fastening means 21.

In this way, the pin 40 will be integrally movable with the door D between the open and closed positions. Thanks to this characteristic, the hinge 1 will be able to support even very heavy doors D without misalignments or changes in behavior.

Conveniently, respective anti-friction elements 13, such as bearings, as in the embodiments illustrated in FIGS, can be placed at the ends of the through seat 12 of the box-like body 11. 1 to 25d, or bushings, as in the embodiments illustrated in FIGS. from 26 to 33d.

This will allow the mobile element 20 to rotate around the X axis with minimum friction, so that the hinge 1 is able to move even very heavy doors D.

The hinge body 11 may internally include a working chamber 14 defining a second axis Y substantially perpendicular to the first axis X defined by the through seat 12 for the pin 40.

Conveniently, the pin 40 may include cam means 50 rotating around the X axis, while the working chamber 14 may include cam follower means 60 interacting with the first ones to move slidingly along the Y axis between a first and a second position of limit switches, illustrated for example in Figures 7b and 9b.

The cam follower means 60 may include an elastic contrast element adapted to elastically contrast the thrusting force imparted by the cam means. For non-limiting example, the elastic contrast element may include, respectively consisting of, a spring, a nitrogen cylinder or a portion made of polymeric material.

In a preferred but not exclusive embodiment of the hinge 1, the elastic contrast element may consist of an elastomer body 61, which may have a plate-like, discoidal or cylindrical shape.

Advantageously, the elastomeric body 61 can be made of compact type polyurethane elastomer, for example Vulkollan®. Conveniently, the elastomer may have a Shore A hardness of between 50 ShA and 95 ShA, preferably between 70 ShA and 90 ShA. More preferably, the elastomeric body 61 may have a Shore A hardness of 80 ShA.

The use of elastomer instead of the classic spring will allow to develop a very high force, when braking and / or pushing, in very narrow spaces. The stroke of the elastomeric body 61 along the Y axis, in fact, may be a few millimeters, for example 4 mm.

Furthermore, the elastomeric body 61 will allow to obtain a highly efficient braking effect, for example in opening as in the embodiments illustrated in FIGS. from 1 to 25d, in a purely mechanical hinge, without the use of oil or in any case hydraulic damping means.

In these embodiments, in fact, following the opening of the door D, the elastic contrast element 61 will pass from the first to the second end-of-stroke position and will remain in this last position until the door is closed by a user, so that the hinge 1 is a control hinge braked in opening.

In the embodiments illustrated in FIGS. from 26 to 33d, on the other hand, the elastomeric body 61 is used in thrust, in order to make the cam 50 and the cam follower means 60 interact reciprocally and maintain the door stop positions, as better explained later on.

Advantageously, moreover, the cam follower means 60 may include an interface element 62 having a first end 63 'interacting with the elastic contrast element 61 and a second end 63' interacting with the cam means 50.

In the embodiments illustrated in FIGS. from 1 to 25d, the interface element 62 may have a substantially "C" shape with a central elongated portion 64 defining a third longitudinal axis Z substantially parallel to the X axis and perpendicular to the Y axis and a pair of transverse appendages d 'ends 65', 65 '' substantially perpendicular to the X axis and parallel to the Y axis.

Both the elongated central portion 64 and the transverse end appendages 65 ', 65' 'may include respective operating surfaces 66, 67', 67 '' located at the front end 63 '', the function of which will be explained later. .

In the embodiment illustrated in FIGS. from 26 to 28c, the interface element 62 may have a generally cylindrical shape, and be configured as a pusher.

In the embodiment illustrated in FIGS. from 29 to 33d, the interface element 62 can be composed of two pieces, a cylindrical pusher 68 'and a pressing disk 68' 'inserted in a bushing 70, the function of which will be better explained later.

Conveniently, the pin 40 may include the cam means 50, so that the latter rotate integrally with the former around the X axis.

Advantageously, then, the cam means 50 may include one or more cam elements adapted to interact with the cam follower means 60.

More particularly, in the embodiments illustrated in FIGS 1 to 9c, 14 to 17c and 26 to 33d the cam means 50 may include a single cam element, while in the remaining embodiments the cam means 50 may include two cam elements ..

The cam elements may have a different configuration according to the embodiment.

For example, in the embodiments illustrated in FIGS. from 1 to 9c and from 14 to 17c, the single cam element can be defined by a plate-like body 51 which can be removably inserted transversely into a seat 42 of the pin 40 so that a portion of the first protrudes from the second. This configuration simplifies the assembly of hinge 1.

On the other hand, the plate-like body 51 can be integrated into the pin 40 in an irremovable manner.

Conveniently, the plate-like body 51 may have a front peripheral edge 53 adapted to interact with the interface element 62, for example at the operating surface 66. For this purpose, the front peripheral edge 53 can be suitably rounded.

In this way, the interface element 62 will progressively compress the elastomeric body 61 following the opening of the door D. The elastomeric body 61, moreover, may be capable of remaining in the elastomeric configuration until the door D closes by a a user. In other words, the hinge 1 will be elastically braked in opening.

In these embodiments, the hinge 1 can be configured so that the cam element 51 meets the operating surface 66 after an angular rotation of the door D, for example 45 ° as particularly illustrated in FIGS. 7b and 8b. Following the interaction with the interface element 62, the cam element 51 will compress the elastomeric body 61, so that the hinge is mechanically braked in opening for the subsequent angular rotation, for example the following 45 ° as particularly illustrated in the FIGS 8b and 9b. In other words, the first angular rotation will be free, that is, not braked, while the subsequent angular rotation will be braked by the braking action of the elastomeric body 61.

On the other hand, in the embodiments illustrated in FIGS. from 26 to 33d, the single cam element can be defined by a plurality of flat faces 43 obtained in correspondence with the central portion of the pin 40. In particular, the flat faces 43 can be three in number, perpendicular to each other to define as many door locking positions D, in the closed position and in the open position in both possible directions.

In the embodiments illustrated in FIGS. from 10a to 13d and from 18 to 25d two cam elements may be provided, in particular a pair of first cam elements 52 ', 52' 'adapted to interact with the operating surfaces 67', 67 '' of the interface element 62 and a second cam element constituted by the plate-like element 51 adapted to interact with the operative surface 66.

The first cam elements 52 ', 52' 'can be defined by a pair of substantially flat faces obtained on the external surface 44 of the pin 40, in longitudinally offset positions so as to come into operational contact with the planar operative surfaces 67', 67 '' of the interface element 62.

Conveniently, the cam means 50 and the cam follower means 60 can be configured so that the substantially flat faces 52 ', 52' 'and the operating surfaces 67', 67 '' are substantially parallel to each other and in mutual contact when the door D it is in the closed position, as for example illustrated in FIGS 11a to 11d, and they are substantially perpendicular to each other and mutually spaced when the door D is in the open position, as for example illustrated in FIGS 13a to 13d.

The plate-like element 51 will also be able to define a plane π substantially perpendicular to the substantially flat faces 52 ', 52' '.

In this way, it will be possible to obtain total control over the door D during the opening phase, for the whole angular rotation of the same.

For a first section of angular rotation, in fact, the substantially flat faces 52 ', 52' 'and the operating surfaces 67', 67 '' will interact with each other to partially compress the elastomeric body 61, bringing it from the rest position or start of stroke to an intermediate compressed position. The plate-like element 51 and the operating surface 66 of the interface element 62 will then interact with each other for the subsequent section of angular rotation of the door D, so as to further compress the elastomeric body 61, bringing it from the intermediate compressed position to the totally position. compressed or end stroke.

This allows you to gradually compress the elastic contrast element, so as to obtain a braking effect for the entire angular rotation of the door D.

The embodiment of hinge 1 illustrated in FIGS. 11a to 13d can open only in one direction, while the embodiment illustrated in FIGS. from 18 to 25d it can open in both opening verses. This also makes it possible to have an ambidextrous hinge, that is, it can be used both straight and upside down. For this purpose, the external surface 44 of the pin 40 may include a respective pair of operating surfaces 52 ', substantially perpendicular and connected to each other.

In this embodiment, moreover, the particular shape of the operating surfaces 52 'will allow to totally control the movement of the door D from the closed position to the one completely open at 180 °.

In the embodiments of hinge 1 illustrated in FIGS. from 1 to 13d, it is possible to adjust the opening angle of door D.

For this purpose, an adjustment dowel 80 can be provided transversely inserted in the hinge body 11 with a first maneuvering end 81 accessible by a user to adjust the penetration of the first 80 through the relative wall of the second 11 and an opposite end 82 adapted to come into contact with the plate-like element 51.

By acting appropriately on the maneuvering end 81 of the grain 80 it will be possible to adjust the opening angle of the door in a simple and rapid way, so that the door D cannot impact against the stationary support W.

Advantageously, moreover, in the embodiment of hinge 1 illustrated in FIGS. from 18 to 25d it is possible to adjust the prestress of the elastic contrast element, which in this embodiment is constituted by the elastomeric body 61.

For this purpose, a slide 90 sliding along the Y axis may be provided with a first end 91 'interacting with the elastomeric body 61 and a second end 91' 'interacting with a pair of adjustment dowels 92.

By acting appropriately on the grains 92, therefore, the user can adjust the sliding of the slide along the Y axis, in order to adjust the prestress of the elastic contrast element as needed, and consequently the force with which it interacts with the cam means and, therefore, which it develops when the door is opened and / or closed.

This is particularly advantageous with the elastomeric body 61, in which a prestress of even a single millimeter corresponds to an extremely high braking force.

The hinge 1, in addition to being extremely effective and functional, is also extremely simple to assemble.

For example, with reference to the embodiment illustrated in FIGS. from 1 to 13d, the hinge body 11 may have, in addition to the through seat 12 intended to contain the pin 40, two through openings 15, 16 to make the working chamber 14 accessible from the outside.

In particular, the first through opening 15 is intended to allow the insertion of the cam follower means 60 into the working chamber 14 and the second opening 16 is intended to allow the insertion of the cam means 50 into the same working chamber 14.

The two through openings 15, 16 define as many axes which are placed perpendicular to each other. In particular, the first through opening defines an axis coincident with the Y axis, while the second opening 16 defines a Y 'axis perpendicular to both the Y axis and the X axis.

In practice, both the cam means 50 and the cam follower means 60 can be removably inserted into the working chamber 14 by sliding along the plane defined by the Y, Y 'axes, perpendicular to the X axis.

This is particularly advantageous if it is necessary to change the elastic contrast element 61, for example to insert a softer or harder one in order to vary the action of the hinge 1 during braking, or to change the plate-like element 51, for example to insert one of a different configuration to vary the braking action of the hinge 1.

The embodiment of the concealed "anuba" type hinge 1 illustrated in FIGS. from 14 to 17c, in addition to the characteristics and advantages indicated above, it is particularly advantageous since thanks to it it is possible to adjust the position of the door D in three dimensions, i.e. both in height and in a plane substantially parallel to the floor as illustrated for example in FIG.16c.

The hinge 1 may include a fixed lower half-hinge 10 with a box-shaped hinge body 11 which can be retracted into the tubular support structure F, CF and a movable upper half-hinge 20 which includes the fixing wing 21 which can be anchored to the door D.

As particularly illustrated in FIGS. from 16a to 16d, the fixing wing 21 is intended to come out of the tubular support structure F, CF in the open position, illustrated in FIGS.

16c and 16d, and to return inside the tubular support structure F, CF in the closed position, illustrated in Figures 16a and 16b.

The fixing wing 21, in fact, may include a first portion 25 'adapted to receive the pin 40 and a second portion 25' 'adapted to receive the fixing bracket 30 and to allow its adjustment along the directions d, d', as illustrated in FIG. 15b.

Conveniently, the fixing bracket 30 may have a first plate-like portion 31 operably anchored to the first portion 25 'of the fixing body 24 monolithically coupled with a second plate-like portion 32, in turn connectable to the door D by means of suitable screws which can be inserted in the holes 33.

The operative connection between the first portion 25 'of the fixing body 24 and the first plate-like portion 31 of the fixing bracket 30 can take place by means of suitable screws 34 which can be inserted through the holes 26 of the fixing body 24 and the openings 35 of the fixing bracket 30 and lockable in suitable locking elements 36.

By acting appropriately on the screws 34 it will be possible to make the fixing bracket 30, and therefore the door D, move along the direction d '. By appropriately loosening these screws 34, in fact, it is possible to make the fixing bracket 30 translate for a stroke equal to the length L of the openings 35 in which the screws 34 themselves are inserted.

The translation along the vertical direction d will be ensured by the grains 37 ', 37' 'inserted through the second portion 25' 'of the fixing wing 21, between which lies the first plate-like portion 31 of the fixing bracket 30. As mentioned above , the latter is secured to the former by screws 34.

The grains 37 ', 37' can be maneuvered after loosening the screws 34, which will allow the translation of the fixing bracket 30 with a stroke equal to the height H of the openings 35 in which the screws 34 themselves are inserted.

To allow the translation of the hinge 1 along the direction of ', the hinge body 11 can be mounted movably on an anchoring plate 100, which can be anchored to the tubular support structure F, CF by means of the screws 101.

For this purpose, a counterplate 102 can be provided, which can be coupled to the hinge body 11 by means of the screws 103 to define a gap 104 between them, in which the anchoring plate 100 is housed. two lateral abutment surfaces 105 ', 105' '.

In the alternative embodiment illustrated in FIGS. 17h and 17i, the counterplate 102 can be integrated into the hinge body 11, ie the two parts can be made together in one piece. This allows a cheaper hinge 1 to be made.

The screws 101 will be engageable in the anchoring plate 100 passing through the slots 106 of the counterplate 102.

By acting appropriately on the screws 101 it will be possible to translate the assembly between the hinge body 11 and the counterplate 102, and therefore the door D, along the direction d ''. By appropriately loosening these screws 101, in fact, it is possible to make the assembly between the hinge body 11 and the counterplate 102, and therefore the hinge 1, translate for a stroke equal to the length L 'of the slots 106 in which the screws 101 themselves are inserted. and / or the distance between the lateral abutment surfaces 105 ', 105' 'of the interspace 104.

The embodiments of the "Anuba" type hinge 1 illustrated in FIGS. 14 to 25d may be suitable for minimizing friction between the fixed half-hinge 10 and the mobile half-hinge 20.

For this purpose, the upper end 110 'of the seat 12 may include a respective upper annular housing 111' capable of accommodating a respective upper anti-friction element 13 ', for example a bearing.

As particularly visible in FIGS. 17d and 17e, the pin 40 may include an upper radial expansion 112 ', for example a flange, with an upper operating surface 113' intended to come into contact with the fixing wing 21 and a lower operating surface 113 '' intended to remain facing the upper annular housing 111 '.

Advantageously, the upper annular housing 111 'and the upper anti-friction element 13' can be mutually configured so that the lower operating surface 113 '' of the upper radial expansion 112 'is capable of abutting against the upper anti-friction element 13 '. In this way, the pin 40 can rotate on the upper anti-friction element 13 'while remaining mutually spaced from the hinge body 11.

For this purpose, the internal diameter D1 of the upper annular housing 111 'can be substantially equal to the external diameter D2 of the upper anti-friction element 13', while the height h2 of the latter can be slightly higher than the height h1 of the first, for example a few tenths. of millimeter.

Furthermore, the lower end 110 '' of the seat 12 conveniently includes a lower annular housing 111 '' capable of accommodating a respective lower anti-friction element 13 ''.

The lower end 41 of the pin 40 may include a blind axial hole 114 suitable for accommodating a locking screw 115. A pressing element 112 '', for example a washer, may also be provided, intended to be interposed between the locking screw 115 and the lower anti-friction element 13 '' to define a lower radial expansion. Advantageously, the latter may include an upper operating surface 116 intended to remain facing the lower annular housing 111 ''.

The latter, the lower anti-friction element 13 '' and the pin 40 can be mutually configured so that the upper operating surface 116 of the pressing element 112 '' is capable of abutting against the pin 40 and remaining spaced from the 13 '' lower anti-friction element.

In this way, any constraint reactions that develop during the rotation of the pin 40 at its lower end 41 will be absorbed by the lower anti-friction element 13 '.

This will prevent the pin 40 from slipping out of the seat 12 and / or the pin 40 from being out of alignment.

To minimize friction between the lower fixed half-hinge 10 and the upper mobile hinge 20, the internal diameter D3 of the lower annular housing 111 '' can be substantially equal to the external diameter D4 of the lower anti-friction element 13 '', while the external diameter D5 of the element presser 112 '' may be slightly smaller than the internal diameter D3 of the lower annular housing 111 ''.

Conveniently, then, the height h3 of the latter may be substantially equal to the sum of the height h4 of the lower anti-friction element 13 '' and the height h5 of the pressure element 112 ''.

Advantageously, the upper and lower anti-friction elements 13 ', 13' 'can be constituted by bearings of the axial-radial type, in order to best discharge both the axial and radial stresses due to the weight of the door D and / or the relative reactions. binding.

In the embodiment of the hinge 1 illustrated in FIGS. from 26 to 33d it will be possible to adjust the position of the movable element 20 in the position of door D closed.

For this purpose, a bushing 70 may be provided with a central hole 71 in which the cylindrical pusher 68 'can be housed. The bushing 70 may include a tubular portion 72 having an external diameter DB and height HB. Furthermore, the bush 70 may have substantially flat upper and lower surfaces 73 ', 73' ', and peripheral tapers 74', 74 ''.

On the other hand, the working chamber 14 may include a first tubular portion 17 'having a first internal diameter DC1 and a second portion 17' of generally rectangular shape, transversal dimension DC2 and height HC.

The bushing 70 can be inserted into the working chamber 14 with the tubular portion 72 placed in correspondence with the second portion 17 '' of the working chamber 14 itself.

The external diameter DB of the portion 72 of the bushing 70 may be slightly less than the internal diameter DC2 of the portion 17 '' of the working chamber 14. The height HB of the portion 72 of the bushing 70 may be substantially equal to the height HC of the second portion 17 '' of the working chamber 14.

The connecting portion 17 '' between the two portions 17 'and 17' of the work chamber 14 can be suitably rounded, as well as the corresponding operating portion 75 of the bushing 70.

Thanks to this configuration, the bushing 70 will be free to translate transversely once inserted into the working chamber 14. The travel of this translation will be defined by the difference between the external diameter DB of the portion 72 of the bushing 70 and the internal diameter DC2 of the portion 17 '' of the working chamber 14. During this translation, the bush 70 will be horizontally guided by the sliding of the upper and lower surfaces 73 ', 73' 'substantially flat on the walls 18', 18 '' of the portion 17 '' of the working chamber 14, also flat.

To adjust this translation, the adjustment dowels 19 ', 19' 'acting on the tapers 74', 74 '' can be provided. In practice, the adjustment dowels 19 ', 19' 'will act in a substantially vertical direction, and the inclined planes defined by the tapers 74', 74 '' will transmit the horizontal component of the thrust force to the bushing 70, causing it to be translated in the portion 17 '' of the working chamber 14.

The connecting portions 17 '' 'of the working chamber 14 and the corresponding operating portion 75 of the bush 70 will then cooperate with each other to allow the partial rotation of the bush 70, so as to vary the inclination of the Y axis and with this is the closed door position, as particularly illustrated in FIG.33c.

In the embodiment of the hinge 1 illustrated in FIGS. from 26 to 33d the elastomeric body 61 will push the cylindrical pusher 68 'against the flat faces 43 formed in correspondence with the central portion of the pin 40, so as to maintain the relative open or closed door positions.

In this embodiment, the shape of the cam means 50 will determine the stroke of the elastomeric body 61. In particular, this stroke may be between 1 mm and 5 mm, and preferably between 1 mm and 3 mm.

From what has been described above, it is evident that the hinge 1 achieves the intended purposes. The hinge 1 is susceptible of numerous modifications and variations. All the details can be replaced by other technically equivalent elements, and the materials can be different according to the requirements, without departing from the scope of protection of the invention defined by the attached claims.

Claims (10)

CLAIMS 1. An Anuba hinge for the controlled rotating movement of a door (D) or similar closing element anchored to a wall (W) or similar stationary support, the hinge comprising a fixed lower half-hinge (10) which can be coupled to the wall (W) or similar stationary support and a mobile upper half-hinge (20) which can be coupled to the door (D) or similar closing element, the fixed (10) and mobile (20) half-hinges being rotatably coupled to each other to rotate between an open position and a closed position around to a first longitudinal axis (X), wherein said fixed lower half-hinge (10) includes a box-shaped hinge body (11), said movable upper half-hinge (20) including a fixing wing (21) that can be anchored to the door (D) and a pin (40) defining said first axis (X) integrally connected to said fixing wing (21), said hinge body (11) including a seat (12) inside which said pin (40) is inserted, in which said seat (12) is defined by a hole passing through said box-shaped hinge body (11), the upper end (110 ') of said seat (12) including a respective upper annular housing (111') capable of accommodating a respective upper anti-friction element (13 '), the lower end (110' ') of said seat (12) including a respective lower annular housing (111' ') capable of accommodating a respective lower anti-friction element (13' '), said movable half-hinge (20) being rotationally pivoted on said hinge body (11) to rotate on said upper anti-friction element (13 ') and / or said lower anti-friction element (13' '), said pin (40) including a lower radial expansion (112 '') capable of abutting against said lower anti-friction element (13 '') to prevent the pin (40) from slipping off said seat (12) and / or to prevent the misalignment of said pin (40) during 'use. 2. Hinge according to claim 1, wherein said pin (40) includes an upper radial expansion (112 ') with an upper operating surface (113') intended to come into contact with said fixing wing (21) and a surface lower operating surface (113 '') intended to remain facing the upper annular housing (111 '), said upper annular housing (111') and upper anti-friction element (13 ') being mutually configured so that the lower operating surface (113' ') of said upper radial expansion (112') is capable of abutting against said upper anti-friction element (13 '), so that said pin (40) rotates on said upper anti-friction element (13') remaining mutually spaced from said hinge body (11). 3. Hinge according to the preceding claim, wherein said upper annular housing (111 ') has a first predetermined internal diameter (D1) and a first height (h1), said upper anti-friction element (13') having a generally annular shape with a second external diameter (D2) and a second predetermined height (h2), said first internal diameter (D1) being substantially equal to said second external diameter (D2), said second predetermined height (h2) being slightly higher than said first height (h1) predetermined to minimize friction between said fixed lower half-hinge (10) and said movable upper half-hinge (20). 4. Hinge according to claim 2 or 3, wherein said lower radial expansion (112 '') comprises an upper operating surface (116) intended to remain facing the lower annular housing (111 ''), said lower annular housing (111 ''), pin (40) and lower anti-friction element (13 '') being mutually configured so that the upper operating surface (116) of said lower radial expansion (112 '') is in contact with said pin (40). 5. Hinge according to the preceding claim, wherein the lower end (41) of said pin (40) includes a blind axial hole (114) adapted to receive a locking screw (115), a pressing element (112 'being provided) ') intended to be interposed between said locking screw (115) and said lower anti-friction element (13' ') to define said lower radial expansion (112' '), and in which said locking screw (115), said pressing element (112 ''), said blind axial hole (114), said lower anti-friction element (13 '') and said lower annular housing (111 '') are configured to pull the pin (40) and push said lower operating surface (113 '') of said upper radial expansion (112 ') against said upper anti-friction element (13') and said upper operating surface (116) of said lower radial expansion (112 '') against said lower anti-friction element (13 '') ). 6. Hinge according to the preceding claim, wherein said lower annular housing (111 '') has a third predetermined internal diameter (D3) and a third height (h3), said lower anti-friction element (13 '') having a generally annular shape with a fourth predetermined external diameter (D4) and a fourth height (h4), said pressure element (112 '') having a generally annular shape with a fifth external diameter (D5) and a fifth predetermined height (h5), said third internal diameter ( D3) being substantially equal to said fourth external diameter (D4), said fifth external diameter (D5) being slightly smaller than said third internal diameter (D3) to minimize friction between said lower fixed half-hinge (10) and said upper movable half-hinge ( 20). 7. Hinge according to one or more of the preceding claims, wherein said pin (40) includes cam means (50) rotating around said first longitudinal axis (X), said box-shaped hinge body (10) at least one working chamber (14) which includes cam follower means (60) interacting with said cam means (50) for sliding along a second longitudinal axis (Y) between a first and a second stroke end position, said cam follower means (60) including at least an elastic contrast element (61). 8. Hinge according to the preceding claim, wherein said at least one elastic contrast element (61) includes, respectively consists of, at least a portion of elastically deformable polymeric material, said cam means (50) being configured to progressively compress said at least a portion in elastically deformable polymeric material of said at least one elastic contrast element (61) following one of the opening or closing of the door (D) or similar closing element, said at least a portion in polymeric material of said at least an elastic contrast element (61) being capable of remaining in the elastically deformed configuration up to the other between the opening or closing of the door (D) or similar closing element by a user so that the hinge is a hinge control flexibly braked in opening and / or closing. 9. Hinge according to the preceding claim, wherein said elastic contrast element (61) consists of a body made of said polymeric material, said cam follower means (60) further including at least one interface element (62) having a first end ( 63 ') interacting with said body made of polymeric material (61) and a second end (63' ') which includes at least one operating surface (66) interacting with said cam means (50), the latter including at least a first cam element (51) having a rounded front peripheral edge (53) for progressively pressing against said operating surface (66) of said second end (63 '') of said at least one interface element (62) so as to push the first end (63 '') of the same against the polymeric material body (61) to deform it elastically. 10. Hinge according to the preceding claim, wherein said polymeric material is constituted by an elastomer having a Shore A hardness comprised between 50 ShA and 95 ShA, preferably between 70 ShA and 90 ShA.