RU2417298C2 - Hinged structure for self-closing doors or similar, in particular, glass doors or similar, and unit comprising such structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: hinged structure comprises the first fixed element attached to a door frame, and the first movable element installed on it with the possibility of rotation, attached to the door for rotation around a longitudinal axis between open and closed positions of the door. The hinged structure also comprises closing facilities that act at the first movable element for automatic return of the door into the closed position after its opening. Besides, the hinged structure comprises hydraulic damping facilities that act at the first movable element for counteraction and damping of displacement as the closing facilities close. At the same time both closing facilities and hydraulic damping facilities are installed in the first working chamber arranged inside the first fixed element. The closing facilities comprise the first cam element arranged as a whole with the first movable element and having the first substantially flat contact surface, and the first plunger element, installed with the possibility of displacement inside the first working chamber along the transverse axis between the compressed final position and the expanded final position, which accordingly correspond to the open and closed positions of the door. At the same time the plunger element has the front surface, which is intended for contact with the cam element surface. Besides, the first contact surface of the first cam element is displaced relative to the longitudinal axis by the specified distance so that the front surface of the plunger element in its extended final position is located behind the longitudinal axis to provide for the possibility of the automatic door closure. At that the closing facilities include the first counteracting elastic facility acting at the first plunger element to push the front surface towards the first contact surface of the first cam element. At the same time the first plunger element has a substantially cylindrical side wall and an end wall that shapes the front surface. At the same time the end wall is designed to separate at least one working chamber into the first compartment of variable volume and the second compartment of variable volume, which are adjacent to each other and are connected with the possibility of fluid medium passage, besides, the first counteracting elastic facility is located in the first compartment. The group of inventions also relates to the door hinged unit, which comprises the hinged structure.

EFFECT: development of such a hinged structure, which is convenient in maintenance, has simple and reliable design and low production cost, provides automatic door closing and provides a support for heavy doors, without modification of its behavior and necessity of any adjustment.

22 cl, 48 dwg

Description

The present invention is applied in the field of hinged and suspended equipment for doors or the like and, in particular, relates to a hinged structure for self-closing doors.

The hinge structure according to the invention can independently close any doors, windows or shutters oriented horizontally or vertically, in particular glass doors.

In addition, the invention relates to a node containing such a hinge structure.

The hinge structure for self-closing doors, in particular glass doors or the like, is known in the art.

This hinge structure, according to the prior art, contains, as you know, a fixed element attached to the door frame, a first movable element to be attached to the door and mounted to rotate on the fixed element to rotate around the longitudinal axis between the open position of the door and the closed position of the door .

This hinge structure, according to the prior art, further comprises means for automatically returning the door to the specified closed position when it is opened.

This articulated structure, according to the prior art, has certain clearly noticeable disadvantages.

The first drawback is the large size, large weight and high cost due to its implementation from many different parts, which further complicate its assembly and maintenance.

In addition, it has poor versatility, and it must be replaced or somehow adjusted when replacing the door or frame on which it is installed.

In addition to this, these hinge structures, according to the prior art, do not provide controlled movement of the door when it is opened and closed. This drawback is especially noticeable with glass doors, the opening and closing movements of which should be smooth to avoid irreparable damage to the door itself.

However, the behavior of these structures, according to the prior art, is highly dependent on the mass of the door on which they are installed.

In addition, during operation, these hinge structures, according to the prior art, have a variable closing position, which leads to inconvenience and an increase in the cost of maintenance.

In addition to this, known structures do not provide the possibility of automatic movement of closing a door after it is opened.

From GB-A-396889, an articulated structure is known having all the features of the restrictive part of claim 1.

The main objective of this invention is to eliminate the above disadvantages by creating a hinge structure that provides convenient maintenance, which has high performance, simple design and low manufacturing cost.

One object of the present invention is to provide a hinge structure that enables automatic door closing from an open position.

A particular task is to create a hinge structure, which provides the possibility of controlled movement of the door with which it is connected.

Another objective of the invention is the creation of a hinge structure that provides support for doors and windows of large weight without changing their behavior and without the need for any regulation.

Another object of the invention is to provide a hinge structure that has a minimum number of parts and which can be adapted to many shells of various shapes and sizes.

Another objective of the invention is the creation of a hinge structure that can keep its closed position unchanged over time.

Another object of the invention is to provide a highly reliable hinge structure that does not create resistance to the closing movement, even with a sharp jerk.

These and other tasks, as will be explained below, are fully achieved using the hinge structure specified in paragraph 1 of the claims.

Preferably, the closing means can be held in the first working chamber, and the hydraulic damping means can be held either in the first working chamber or in a second working chamber different from the first chamber.

According to another aspect of the present invention, there is provided a hinge assembly for self-closing doors or the like specified in claim 20.

Preferred embodiments of the invention are defined in the dependent claims.

Other features and advantages of the invention follow from the following detailed description of several preferred, but not exclusive embodiments of the hinge structure and assembly according to the invention, the description of which is given as non-restrictive examples with reference to the accompanying drawings, in which:

FIG. 1 - a door with a hinge structure mounted on it, according to the invention, in plan view;

FIG. 2 is a first embodiment of a hinge structure according to the invention, in the closed position of the door, in isometric view;

FIG. 3 is a section in the plane AA of the hinge structure according to FIG. 2;

FIG. 4a is a first preferred, but not exclusive configuration of a hinge structure according to FIG. 2, in exploded isometric view;

FIG. 4b is a second preferred, but not exclusive configuration of the hinge structure of FIG. 2, in exploded isometric view;

FIG. 5a and 5c show closure means 4 of a hinge structure according to the invention in an isometric view;

FIG. 5b is a partial sectional view of some parts, as shown in FIG. 5a, in the plane MM;

FIG. 6 shows certain details of the hinge structure of FIG. 5, on an enlarged scale;

FIG. 7a and 8a are sections of a hinge structure according to FIG. 2, in the plane BB in the open and closed position of the door, respectively;

FIG. 7b and 8b are sections of a hinge structure according to FIG. 2, in the plane BB in the conditions of partial opening of the door, during opening the door and closing the door, respectively;

FIG. 9 and 10 are sectional views of alternative embodiments of the hinge structure of FIG. 2, in the plane AA;

FIG. 11 is a second embodiment of a hinge structure according to the invention in an isometric view;

FIG. 12 is a section through a hinge structure according to FIG. 11, in the plane CC;

FIG. 13 is a section through a hinge structure according to FIG. 11, in the plane D-D;

FIG. 14 is a hinge structure according to FIG. 11 is an exploded isometric view;

FIG. 15 - the first and second plunger elements of the hinge structure, according to FIG. 11 is an exploded isometric view;

FIG. 16 shows some details of FIG. 11, while the fixed elements are depicted by dashed lines in an exploded isometric view;

FIG. 17 is a sectional view of a first preferred, but not exclusive embodiment of a finger of a hinge structure according to FIG. eleven;

FIG. 18 is a section through a finger according to FIG. 17, in the plane EE;

FIG. 19 is a sectional view of a second preferred, but not exclusive embodiment of a finger of a hinge structure according to FIG. eleven;

FIG. 20-23 are sectional views of the device of FIG. 11, in the planes F-F and G-G in a partially closed position, in a partially open position during door opening, in an open position and in a partially open position while closing the door, respectively;

FIG. 24 is a door with a hinge mounted thereon, according to a second embodiment of the invention;

FIG. 25 is a node, according to the invention, in isometric view;

FIG. 26 is an isometric view of the assembly according to the invention, wherein the first and second articulated structures are shown in exploded isometric view;

FIG. 27 is an isometric view of the assembly according to the invention, wherein the first and second fixed elements are shown by dashed lines;

FIG. 28 is a section through the first and second hinge structures of the assembly according to the invention in the planes H — H, H′ — H ′, respectively;

FIG. 29 is a section through the first and second hinge structures in the closed position of the door of the assembly according to the invention in the planes L-L, L'-L ', respectively;

FIG. 30 is a sectional view of the first and second hinge structures of the assembly in an intermediate door opening position according to the invention in the planes L-L, L'-L ', respectively;

FIG. 31 is a sectional view of the first and second hinge structures of the assembly in the open position of the door according to the invention in the planes L-L, L'-L ', respectively;

FIG. 32 is a section through the first and second hinge structures of the assembly in an intermediate closing position of the door according to the invention in the planes L-L, L'-L ', respectively.

The figures show embodiments of a hinge structure for self-closing doors or the like, indicated generally by 1, which can be preferably installed, but not limited to, on glass doors.

In all of these embodiments, the hinge structure 1 comprises a substantially fixed element 2 for securing to the door frame T of the door P, and a movable element 3 for securing to the door P. The movable element 3 is pivotally mounted on the stationary element 2 the first longitudinal axis X between the open position of the door and the closed position of the door.

The hinge structure 1 further comprises closing means, indicated generally by 4, and hydraulic damping means, indicated generally by 5, which may consist of, but not limited to, the specified amount of oil in the embodiments indicated here.

Closing means 4 act on the first movable element 3 to automatically return the door to the closed position when opened, and hydraulic damping means 5 act on this element 3 to counteract and damp the movement caused by the closing means 4.

A special feature of the invention common to all of the embodiments indicated here is that the closing means 4 and the hydraulic damping means 5 are held in at least one working chamber 6 inside the fixed element 2.

Due to this arrangement, a hinge structure is obtained, which provides a controlled rotary movement of the door. This means that when the door is in the open position, the closing means 4 act on the movable element 3 and create a torque that causes the door P to rotate about the X axis to the closed position. On the other hand, all this time, hydraulic damping means 5 act on this movable element 3 to create a resistance torque opposite to the torque created by the closing means 4.

The hinge structure according to the invention also provides high safety, since it does not resist the movement of the closing even with a sharp jerk. This prevents injury to inattentive users, in particular children. Regardless of the force exerted on the door, it always returns smoothly to the closed position of the door, which ensures safety for children.

The hinge structure according to the invention is particularly effective and inexpensive because it can keep its original characteristics constant over time, even when used in difficult conditions with a high moisture content and moisture penetration.

In addition, due to the intended arrangement of the closing means 4 and the hydraulic damping means 5 completely, in at least one first working chamber 6 inside the fixed element 2, the hinge structure 1 is especially easy to handle, has a minimum size and requires minimal space for placement. Therefore, its installation does not require special stone or excavation work. As shown in the accompanying figures, the hinge structure 1 is attached to the door frame (or to the wall) along the vertical length of the door above the floor or wall to which the fixed element is attached.

The closure means 4 includes a first cam element 11, integrally formed with the first movable element 3 and having a first substantially flat contact surface 16, and a first plunger element 12 mounted to move inside said first working chamber 6 along the transverse axis Y between the end the position of the compression stroke corresponding to the open position of the door, and the final position of the expansion stroke corresponding to the closed position of the door. The plunger element 12 has a front surface 17, which is designed to contact the surface 16 of the cam element 11.

According to the invention, the first contact surface 16 of the first cam element 11 is offset relative to the longitudinal axis X by a predetermined distance g, so that the front surface 17 of the plunger element 12 in its final expansion position is located behind the specified longitudinal axis X.

Due to this arrangement, the possibility of excellent control of the movement of closing the door is provided. Indeed, the displacement of the contact surface 16 relative to the longitudinal axis X provides the ability to automatically close the door. This means that when the door P closes, starting from the fully open position, as shown in FIG. 8b, 22 and 31, due to the distance g between the X axis and the surface 16, the front surface 17 of the plunger element 12 immediately (after several degrees of rotation) begins to interact with the surface 16, thereby turning the door P into the closed position of the door, as shown in FIG. 7a, 20, and 29.

A first preferred, but not exclusive embodiment of the invention is shown in FIG. 2-8, in which there is only one working chamber 6, containing closing means 4 and hydraulic damping means 5.

In this embodiment, as shown in FIG. 4a and 4b, the fixed element 2 can be formed by a base 7, intended for mounting on the frame T with screws inserted into the holes 8, 8 ', 8 ”, 8”, while the movable element 3 may in turn contain two half shells 9, 9 ', connected together with screws 10, 10'.

The closure means 4 may preferably include a cam element 11, better shown in FIG. 5a, which is capable of pivoting around the X axis with the movable element 3 and is designed to interact with the plunger element 12, better shown in FIG. 5c, which is mounted with the possibility of moving in the longitudinal direction inside the working chamber 6.

As used herein, the term “cam” refers to a mechanical element of any shape that is designed to convert circular motion into rectilinear motion.

Usually, in this embodiment, the plunger element 12 moves along a line Y, essentially perpendicular to the line defined by the longitudinal axis X, to minimize the required space. As shown in particular in FIG. 7 and 8, line Y is defined by the axis of the cylindrical working chamber 6.

The finger 13, shown in particular in FIG. 5a, which defines the X axis, is provided in the fixed element 2. The finger 13, which is intended to be mounted in the cylindrical receiving socket 24 of the fixed element 2, has a central part 14 of a suitable shape that forms the cam element 11, and side parts 15, 15 ′, to be connected to the movable element 3. Due to this arrangement, the cam 11 rotates with the movable element 3.

The cam element 11, which is formed by the central part 14 of the finger 13, comprises a substantially flat surface 16 parallel to the X axis and abutting against the front surface 17 of the plunger element 12. By rotating about the X axis, the surface 16 interacts with the front surface 17 of the plunger element 12 to cause its rectilinear movement along the line d. For this, the working chamber 6 and the cylindrical receiving socket 24 are connected to each other in the contact zone between the surface 16 of the pin 13 and the front surface 17 of the plunger element 12.

As shown in particular in FIG. 5b, surface 16 preferably has a distance g from the X axis of 1-6 mm, preferably 1-3 mm, and more preferably about 2 mm. Due to this distance, the movement of closing the door is fully automatic.

As shown in FIG. 5c, the plunger element 12 consists of a counteracting spring 18, a locking cap 19, a cover cylinder 20 and a check valve 21, which forms means for controlling the flow of oil 5 in the chamber 6, as will be explained in more detail below. Everything is “packaged” and introduced by means of a seal 22 into the working chamber 6, while the locking cap forms its lower wall.

It is understood that the check valve 21 can also be installed inside the cover cylinder 20, as shown, for example, in FIG. 4b. In this case, the front surface 17 of the plunger element 12 is defined by the front surface 23 of the coating cylinder 20.

As shown in particular in FIG. 7a, 7b, 8a and 8b, the end wall 32 of the plunger element 12, which defines its front surface 17, is designed to divide the working chamber 6 into the first and second variable volume compartments 33, 34, which are adjacent to each other and connected to each other with the possibility of the passage of fluid between them. The counter spring 18 is located in the first compartment 33.

This embodiment of the hinge structure according to the invention enables very simple installation. The installation process is carried out simply by inserting the finger 13 into the cylindrical receiving socket 24 of the fixed element 2, connecting its side parts 15, 15 'with the movable element 2 by inserting the surfaces 25, 25' of the finger 13 into the receiving slots 26, 26 'of the half shell 9' introducing the oil seals 27, 27 ', if any, of the thrust bearings 28, 28' and the bearings 29, 29 'of the thrust bearings into the receiving seat 24, attaching the pin 23 to the shell 9' using screws 30, 30 'and connecting them together half shell 9 and half shell 9 'using screws 10, 10'. The plunger element 12, packaged in the above manner, is inserted into its working chamber 6 and the locking cap 19 is tightened.

This assembly process is completed by the supply of oil 5 to the working chamber 6 for hydraulic damping of the closing movement caused by the closing means 4. For this, a through hole 31 in the fixed element 2 can be formed to form an oil loading channel providing a connection between the working chamber 6 and the outer environment, as shown in FIG. 4a. It is clear that the amount of oil to be charged into the chamber 6, as well as the volume of the chamber, can vary depending on the mass of the door R.

The operation of the hinge structure 1 is shown in FIG. 7a, 7b, 8a and 8b.

In the closed position of the door, as shown in FIG. 7a, the flat surface 16 of the finger 13 and the front surface 17 of the plunger element 12 are in contact with each other, being essentially parallel to each other. The counter spring 18 is precompressed between the cylinder 20 and the cap 19. In this position, essentially the entire amount of oil 5 is in the first variable volume compartment 33, which has a maximum volume. The counter spring 18 also has its maximum length.

When the user opens the door P by applying an external load E _{L to it} , the door P moves in the direction of the arrow F ₁ from the closed position of the door, as shown in FIG. 7b. This movement leads to the fact that the flat surface 16 of the finger 13 rotates around the X axis and thereby interacts with the front surface 17 of the plunger element 12 with compression of the opposing spring 18. The flat surface 16 of the finger 13 and the front surface 17 of the plunger element 12 are at an angular distance α apart, which increases when the door is opened. Thus, the end wall 32 of the plunger element 12 is displaced along the Y line in the direction V. At the same time, due to the movement of the separation wall 32, the oil 5 is transferred from the first compartment 33, the volume of which decreases, into the second compartment 34, the volume of which increases accordingly, through the hole 35 of the check valve 21.

In the embodiment shown here, the check valve 21 is formed by an elongated protrusion 36 on the end wall 32, coaxial to the cylindrical working chamber 6, and is a normally open type valve, i.e. allows oil 5 to pass from the first compartment 33 to the second compartment 34 while opening the door and prevents it from flowing back when the door is closed.

In FIG. 8a shows the position of a fully open door. In this position, the flat surface 16 of the pin 13 and the front surface 17 of the plunger element 12 are perpendicular to each other. As shown in FIG. 8a, substantially all of the amount of oil 5 is in the second variable volume compartment 34, which has a maximum volume, while the first compartment 33 has a minimal volume. The counter spring 18 is also in the maximum compression position, which corresponds to its minimum length.

When the user pivots the door P from its fully open position or, equivalently, the user releases the door from the partially open door position (i.e., when the external load E _L no longer acts), the closing means 4 begin to act on the movable element 3 to automatically return door P to the open position. At the same time, hydraulic damping means 5 begin to act on the movable element 3 to counter and dampen the closing movement created by the closing means 4.

In FIG. 8b shows the above state when the door P is in the partially open door position while closing the door in the direction of the arrow F ₂ . In this position, the flat surface 16 of the finger 13 and the front surface 17 of the plunger element 12 are at an angular distance α from each other, which decreases as the door closes. The spring 18 compressed before this has the opposite effect by pushing the front surface 17 of the plunger element 12 against the surface 16 of the finger 13, thereby causing the surfaces 16 and 17 to slide along each other and move the end wall 32 along the line Y in the direction V '. At the same time, due to the movement of the separation wall 32, the oil 5 is transferred from the second compartment 34, the volume of which begins to decrease, into the first compartment 33, the volume of which increases accordingly. However, the oil no longer flows through the opening 35 of the check valve 21, which is closed, but flows back to the first compartment 33 through the tubular space 37 between the side wall 38 of the working chamber 6 and the side wall 39 of the cover cylinder 22 of the plunger element 12. Suitable air space size control 37 can increase or decrease the damping effect provided by the oil 5, which makes the hinge structure according to the invention extremely safe.

In the alternative configuration of the invention shown in FIG. 10, at least one opening 40 may be formed in the side wall 39 of the cover cylinder 20 of the plunger member 12 to facilitate and / or control the return flow of oil 5 to the first compartment 33. Suitable sizes and / or number of openings 40 provide the ability to control the return the movement of the door P to the closed position of the door.

In another alternative embodiment of the invention shown in FIG. 9, the hinge structure 1 may comprise a screw 41 for throttling the air gap 37 and thereby adjusting its size at the request of changing the speed of the return flow of oil 5 and thereby controlling the damping effect.

In FIG. 11-24 show a non-limiting second embodiment of the hinge structure according to the invention, indicated generally by 1 '. It contains a substantially fixed element 2 and a movable element 3 to be fixed to the door P with two half shells 42, 42 '. The fixed element 2 is intended to be mounted on a fixed support S, such as a wall or floor, by means of a collar 43, as shown in FIG. 24.

This second embodiment differs from the first embodiment in that while the closing means 4 are held in a single first working chamber 6, the hydraulic damping means 5 are held in both the first working chamber 6 and the second working chamber 44, which is connected with the first chamber with the possibility of the passage of fluid. As shown in FIG. 14, both the first working chamber 6 and the second working chamber 44 are located in a box-shaped housing defined by the fixed element 2.

This configuration enables the controlled movement of very heavy P doors and / or gates. This result is achieved by the second working chamber 44, which provides an additional volume for hydraulic damping means 5, with which you can effectively control the movement of objects of very large mass.

In this second embodiment, the closing means comprises, in addition to the first cam element 11, a second cam element 45, which also rotates about the X axis with the cam element 11, as shown, in particular in FIG. 17. In addition, the second cam element 45 interacts with the second plunger element 46, which is mounted to move in the longitudinal direction along the line Y 'inside the second working chamber 44.

The line Y ', which is defined by the axis of the second cylindrical working chamber 44, is preferably parallel to the movement line Y of the first cam element 11, which minimizes the required space.

In the second embodiment, the central part 14 of the finger 13, which is always held inside the stationary element 2 in the cylindrical receiving socket 24, defines both the first cam element 11 and the second cam element 45.

The finger 13 is designed for mounting on a fixed element 3 using the mounting surfaces 25, 25 'of the end parts 15, 15'. In particular, the upper surface 25 is intended for insertion into the groove 47 of the half shell 42 of the movable element 3, and the lower surface 25 'is introduced into the side 43 attached to the floor S.

In this embodiment, both the first cam element 11 and the second cam element 45 are formed by customizing the center portion 14 of the finger 13. The first cam element 11, like the first embodiment, comprises a first substantially flat surface 16 parallel to the X axis and abutting into the front surface 17 of the first plunger element 12. The second cam element 45 located above the first is essentially defined by a wall 48 having a pair of second substantially flat surfaces 49, 49 'parallel to X and substantially perpendicular to the first surface 16.

The wall 48 abuts with its surfaces 49, 49 ′ against the front surface 50 of the second plunger element 46. For this, as shown in FIG. 16, the cylindrical receptacle 24 is intended to be connected with both the first working chamber 6 and the second working chamber 44 in the contact zone between the first cam element 11 and the first plunger element 12 and in the contact zone between the second cam element 45 and the second plunger element, respectively .

The second plunger element, similarly to the first plunger element, consists essentially of a second counter spring 51, a second locking cap 52, a second cover cylinder 53 and a second check valve 54, which forms means for controlling the flow of oil 5 in the second working chamber 44, as mentioned above . Everything is “packaged” and inserted using the second seal 55 into the second working chamber 44, while the locking cap 52 defines its lower wall.

As shown in particular in FIG. 20-23, the end wall 50 of the second plunger element 46 is defined by a wall 56, which is designed to divide the second working chamber 44 into the third and fourth variable volume compartments 57, 58, which are adjacent to each other and are fluidly coupled. The counter spring 51 is located in the fourth compartment 58.

The fixed member 2 has a channel 60, shown clearly in FIG. 13, for connecting with each other with the possibility of fluid passage of the first and second working chambers 6, 44. In addition, the channel 60 contains a throttle screw 61 to control the damping effect of the hydraulic means 5.

In the second embodiment described here, the check valve 21 is a normally open type valve, i.e. allows oil 5 to pass from the first compartment 33 to the second compartment 34 during opening the door and prevents it from flowing back when the door is closed, while the check valve 54 is a normally closed type valve, i.e. allows oil 5 to pass from the third compartment 57 to the fourth compartment 58 during opening the door and prevents it from flowing back when the door is closed.

This embodiment of the hinge structure according to the invention enables very simple installation, similar to the first embodiment. The installation process is carried out simply by inserting the finger 13 into the cylindrical receptacle 24 of the fixed element 2, connecting its side parts 15, 15 'with the movable element 3, as mentioned above, introducing the oil seals 27, 27', if any, of the thrust bearings 28, 28 'and bearings 29, 29' of the thrust bearings into the receiving seat 24 and connecting the half shell 42 and the half shell 42 'together using screws 10, 10', 10 ”. The first plunger element 12, packaged in the aforementioned manner, is inserted into its working chamber 6, and the locking cap 19 is tightened, while the second plunger element is designed for packaging and insertion into the second working chamber 44.

This assembly process is completed by the introduction of oil 5 into the working chambers 6 and 44 for hydraulic damping of the closing movement created by the closing means 4. This can be done by using the feed channel 31 in the fixed element 2, which connects the external environment to the second working chamber 44, which the queue is connected with the possibility of fluid passage with the first working chamber 6. It is clear that a predetermined amount of oil 5, loaded through the channel 31, is distributed between the first 33, second 34, three 57 and fourth 58 variable volume compartments. The channel 31, which is suitable, in particular, for adding oil 5 if necessary, is closed by a cap 59.

The operation of the hinge structure 1 is better shown in FIG. 20-23.

In FIG. 20 shows the relative position of the closing means 4 and the hydraulic damping means 5 in the closed position of the door. In this position, the front surface 17 of the first plunger element 12 abuts against the flat surface 16 of the first cam element 11 and is parallel to it to keep the door closed, similar to the first embodiment. The front surface 50 of the second plunger element 46 in turn abuts against the wall 48 with its elements 49, 49 'and is perpendicular to it.

The first counter spring 18 is precompressed between the cylinder 20 and the cap 19, and the second counter spring 51 is compressed between the cap 52 and the cylinder 53. In this position, the first 33 and third 57 compartments of variable volume have a maximum volume, and the second 34 and fourth 58 compartments have a minimum volume. In addition, the counter spring 18 has its maximum length, and the second counter spring 51 has its minimum length (in the maximum compression position).

When opening the door P, i.e. when an external load E _{L is} applied to it, the movable element 3 starts to rotate around the X axis relative to the fixed element 2, the finger 13 moves in the direction of the arrow F ₁ , the first surface 26 of the first cam element 1 and the second surfaces 49, 49 'of the second cam element 45 begin turn with him. This partially open door position during door opening is shown in FIG. 21.

Due to the rotation of the finger 13 and the application of force from the surface 16 to the front surface 17 of the first plunger element 12, it starts to move along the line Y in the direction V. At the same time, the second plunger element 46 starts to move along the line Y 'in the direction V', in the opposite direction V. As the door opens, the angle α between the flat surface 16 of the finger 13 and the front surface 17 of the first plunger element 12 begins to increase, while the angle β between the flat surfaces 49, 49 'of the second plunger element 46 starts flushes decrease.

Thus, the volume of the first compartment 33 begins to decrease with a load on the first spring 18. In addition, as the volume of the first compartment 33 decreases, the oil 5 contained in it starts to flow from the opening 35 of the valve 21 into the second variable volume compartment 34, which begins to receive oil and increases its volume.

At the same time, due to the rotation of surfaces 49, 49 'and the action of the force on the front surface 50 of the second plunger element 46, the volume of the fourth compartment 58 begins to increase with the unloading of the second spring 51. In addition, the volume of the third compartment 57 begins to decrease, oil 5 starts to leak from it to the fourth compartment 58, the volume of which is correspondingly increasing.

In FIG. 22 shows the fully open position of the door. It is clear that the device according to the invention allows opening the door 90 ° also in the other direction. In this position, the fourth compartment 58 has a maximum volume, while the second compartment 34 has a minimum volume. The first spring 18 is at its maximum load (minimum length), and the second spring 51 is at its minimum load (maximum length).

When the user releases the door or moves from the one shown in FIG. 22 of the closed position, the first spring 18 begins to be released, and the first plunger element 12 begins to push into the surface 16 of the finger 13, thereby turning it in the direction of the arrow F ₂ back to the closed position of the door. At the same time, surfaces 49, 49 ′ are compressed by the second spring 51, so that the volume of the fourth compartment 58 begins to decrease and oil flows out of it.

In FIG. 23 shows the above position in which door P is in the partially open position of the door while closing the door in the direction of arrow F ₂ . In this position, the first flat surface 16 of the finger 13 and the front surface 17 of the first plunger element 12 are at an angular distance α from each other, which decreases as the door closes, while the second flat surfaces 49, 49 'of the finger 13 and the front surface 50 the second plunger element 46 are at an angular distance β from each other, which increases.

The previously compressed first spring 18 performs its opposing action by pushing the front surface 17 of the first plunger element 12 to the first surface 16 of the finger 13, which leads to sliding of the surfaces 16 and 17 to each other and to the movement of the first end wall 32 along the line Y in the direction V. Now the second spring 51 is also compressed under pressure from the side of the second wall 48 of the second cam element 45 onto the second plunger element 46, which moves along the line Y 'in the direction V' opposite to the direction w V.

The second valve 54 is a normally closed type valve and does not allow the working fluid to pass through the hole 62, due to which oil 5 is forced to flow out of the hole 63 into the air gap 63 defined by the side walls 65, 66 of the second working chamber 44 and the second coating cylinder 53, respectively . Leaking oil 5 flows through the channel 60 into the first compartment 33, the volume of which is continuously increasing.

The first valve 21, which is a normally open type valve, does not allow oil 5 to pass through the opening 35, therefore, oil flows from the second compartment 34 into the third compartment 57, which are connected to each other with the possibility of fluid flow.

Indeed, in the second embodiment, as shown in the figures, the working fluid flows counterclockwise along the path inside the box-shaped housing formed by the fixed element 2 to hydraulically delay the rotational movement of the movable element 3 relative to its return movement to the closed position of the door. Likewise, the working fluid is also retained during the opening of the door, so that the hinge structure according to the invention is very safe even when a door is installed in which wind or an inattentive user can exert an excessive load on the door.

In an alternative embodiment of the invention, as shown in FIG. 19, the first cam element 11 of the finger 13 may have a rounded peripheral surface, for example, formed by turning, to allow the movement of the door P back to the closed position of the door from any open position of the door. This embodiment is preferred, in particular for fire doors.

In FIG. 25-30 show a preferred, but not exclusive embodiment of the hinge assembly, generally indicated at 70, for mounting on self-closing doors P or the like. The assembly 70 comprises first and second hinge structures 71 and 72, each containing a fixed element 2, 2 ′ to be mounted on the frame T of the door P, and a movable element 3, 3 ′ to be mounted on the door P. The movable elements 3, 3 'are installed with the possibility of rotation on their respective fixed elements 2, 2 'to rotate around the axis X. In this embodiment, the door P acts as a "drive shaft" between two hinge structures 71, 72.

As shown in particular in FIG. 28, closing means 4 and hydraulic damping means 5 are held in two working chambers 6, 44 inside the box-shaped housing defined by the first fixed element of the first hinge structure 71, while the second hinge structure 72 contains second damping means 80, which may also consist of a predetermined amount of the same oil used in the first hinge structure 71 contained in another working chamber 81 inside the box-shaped housing defined by the second fixed element 2 '.

In other words, the first hinge structure 71 acts on the movable element 3 (and thereby on the movable element 3 ') to create the torque C necessary to cause the door P to rotate to its closed position about the X axis, while the second hinge structure 32 acts on its movable element 3 '(and thereby on the movable element 3) to hydraulically dampen the motion caused by the hinge structure 71, creating a resistance torque C' opposite to the torque C.

This configuration provides optimal control of the movement of very heavy doors and gates during both opening and closing movements.

With respect to both construction and operation, the first hinge structure 71 is very similar to the first embodiment shown in FIG. 1-10, or the lower half of the embodiment shown in FIG. 11-24. However, the second hinge structure 72 is very similar with respect to the construction and operation of the upper half of the second embodiment shown in FIG. 11-24. The only functional and structural difference between this embodiment and the hinge assembly 70 is that the working chambers 6, 44 and the working chamber 81 are not connected to each other with the possibility of fluid flow, although their work is identical. In an alternative embodiment, the assembly 70 according to the invention may be formed from a first embodiment of the hinge structure shown in FIG. 1-10 (with the location of the closing means in a single working chamber 6), and the hinge structure 72.

The second hinge structure 72 includes a second pin 13 'having a corresponding contact surface 82, which is designed to interact with another plunger element 83 associated with the second damping means 80.

The contact surface 82 of the second finger 13 'is essentially perpendicular to the surfaces 16 and 49 of the first finger 13 of the first hinge structure 71.

In addition, the second finger 13 'has a central part 14', which defines the corresponding cam element 86, as well as the side parts 87, 87 ', which have a suitable shape for connection with the second movable element 3'.

The cam element 86 interacts with the corresponding plunger element 83, as indicated above.

The second hinge structure 72 further comprises a corresponding check valve 84 located at one end wall 85 of the plunger element 83 to allow oil 80 to pass through while closing the door and to prevent back flow during opening the door. The wall 85 divides the working chamber 81 into the corresponding variable volume compartments 88 and 89, the counter spring 90 being located in the compartment indicated by 88.

As shown in particular in FIG. 29-32, check valves 21, 54, and 84, associated with their respective plunger elements 12, 46, and 83, are normally open type valves.

Another difference between the second hinge structure 72 and the upper half of the second embodiment shown in FIG. 11-24, the second check valve 84 is a normally open type valve (similar to the first valves 21, 54), i.e. allows oil 5 to pass from the fourth compartment 58 to the third compartment 57 during opening the door and prevents its backflow during closing of the door.

Thus, unlike the second embodiment shown in FIG. 11-24, the first valves 21, 54 and the second check valve 84 operate in the same directions, i.e. are open when the door is opened and closed when the door is closed.

The first and second hinge structures 71 and 72 are assembled as described above. Two channels 78, 79 are provided for filling oil 5 after completion of assembly.

In operation, the first and second hinge structures 71, 72 are mounted on the door P and interact with each other to control the rotational movement of the door around the axis X. As shown in FIG. 26, their fingers 13 and 13 'are configured such that the flat surfaces of the finger 13 and the opposing flat surfaces 82, 82' of the finger 13 'located one above the other are perpendicular to each other.

To adjust the alignment of the door P, the first hinge structure 71 may have suitable adjusting pins 75, 76.

The operation of the assembly 70 is identical to the operation of the second embodiment of the hinge structure shown in FIG. 11-24, except that the oil flow 5 is controlled by the normally open type valves 21, 54, while the oil flow 80 is controlled by a valve 84, which is a valve of the same type.

In FIG. 29 shows the first and second hinge structures 71, 72 in the closed position of door R. It is understood that although in FIG. 29-32 only the upper part of the hinge structure 71 is shown, the components of the lower part (not shown) work in exactly the same way as the components of the upper part.

When the door P is opened by the user, i.e. when an external load E _{L is} applied to it, for example, in the direction F ₁ , as shown in FIG. 30, the first finger 13 and the second finger 13 'rotate around the X axis and cause the surface 16 and opposite flat surfaces 82, 83' to rotate around the same X axis. The spring 18 of the first plunger element 12 begins to compress, while the spring 90 begins to expand.

Thus, the volume of the first compartment 33 begins to decrease with the load of the first spring 18. In addition, as the volume of the first compartment 33 decreases, the oil 5 in it begins to flow through the opening 35 of the valve 21 into the second variable volume compartment 34, which starts to receive the oil 5 and increases its volume.

At the same time, by turning the surfaces 82 ', 82, the volume of the compartment 89 begins to increase with the release of the spring 90. The volume of the compartment 88 also begins to decrease, so that the oil 80 in it starts to flow into the adjacent compartment 89, the volume of which increases accordingly. However, since the valve 80 is a normally open type valve, the oil 80 cannot pass through the valve opening and flows into the compartment 89 through the air gap 91 between the side wall 92 of the working chamber 81 and the side wall of the plunger element 83.

When the user releases the door or when it moves from the one shown in FIG. 31 to the closed position, the first spring 18 begins to expand, and the first plunger element 12 begins to push into the surface 16 of the finger 13, thereby causing it to turn in the direction of the arrow F ₂ back to the closed position of the door. At the same time, surface 82 (or 82 ', depending on the direction the door is opened) compresses spring 90, so that the volume of compartment 89 begins to decrease and oil 80 flows out of it.

In FIG. 32 shows the above state when the door P is in the partially open position of the door while closing the door in the direction of the arrow F ₂ . The previously compressed first spring 18 exerts its opposing action by pushing the front surface 17 of the first plunger element 12 to the first surface 16 of the finger 13, causing the surfaces 16 and 17 to slide towards each other and to move the end wall 32 along the line Y in the direction V. Now the second spring 90 also compresses due to the pressure of the cam element 86 on the plunger element 83, which moves along the line Y 'in the direction V' opposite to the direction V.

The first valve 21, which is a normally open type valve, does not allow oil 5 to pass through the opening 35, therefore, oil flows from the second compartment 34 to the first compartment 33 through the air gap 37 between the side wall 38 of the working chamber 6 and the side wall 39 of the cylinder 20. The valve 84, which is also a normally open type valve, allows oil 80 to pass through its bore, causing it to flow from the variable volume compartment 89 to the compartment 88.

It is understood that both the first hinge structure 71 and the second hinge structure 72 may include means for controlling the flow of fluid, similar to those indicated in the first and second embodiments, the description of which was given above. This provides control both during the opening and closing of door R. Thus, the door can be designed to provide zero (or very small) resistance at low closing speeds and to increase its resistance when increasing the closing speed of door R.

Due to this, if the door is installed outside, it can be designed for easy opening by users, while it does not slam under the influence of external factors, such as wind or the like.

From the above description it follows that the hinge structure and assembly, according to the invention, fulfill the tasks and, in particular, satisfy the requirement of providing controlled movement of the door both when it is opened and closed.

During closing the door, this controlled movement prevents the door from hitting its frame, which ensures its safety and long service life.

On the other hand, during the opening, such controlled movement prevents any abrupt opening of the door P due to gusts of wind to protect both the door and any users within its operating limits.

Various changes and variations of the hinge structure and assembly according to the invention are possible within the concept of the invention disclosed in the attached claims. All their parts can be replaced with technically equivalent parts and materials can be replaced depending on various needs without going beyond the scope of the invention.

Although the description of the hinge structure and assembly has been provided with specific references to the accompanying drawings, the numerical references indicated in the description and in the claims are used only for a better understanding of the invention and should not in any way limit the scope of the claims.

Claims (22)

1. A hinge structure for self-closing doors or the like, comprising:
the first fixed element (2), attached to the frame (T) of the door (P), and mounted on it with the possibility of rotation of the first movable element (3), attached to the door (P) for rotation around the longitudinal axis (X) between the open position of the door and the closed position of the door;
closing means (4) acting on said first movable element (3) to automatically return the door (P) to the closed position after it is opened;
hydraulic damping means (5) acting on the first movable element (3) to counteract and damp the movement when closing the closing means (4);
while both closing means (4) and hydraulic damping means (5) are located in the first working chamber (6) located inside the first stationary element (2);
wherein the closing means (4) include a first cam element (11) integrally formed with the first movable element (3) and having a first substantially flat contact surface (16), and a first plunger element (12) installed with the ability to move inside the first working chamber (6) along the transverse axis (Y) between the compressed end position corresponding to the open position of the door and the extended end position corresponding to the closed position of the door, while the plunger element (12) has a front surface (17), otorrhea intended for contact with said contact surface (16) of the cam member (11);
the first contact surface (16) of the first cam element (11) is offset relative to the longitudinal axis (X) by a predetermined distance (g), so that the front surface (17) of the plunger element (12) is located beyond the longitudinal axis in its elongated end position ( X) to enable automatic door closing; and
wherein the closing means (4) include a first opposing elastic means (18) acting on said first plunger element (12) to push the front surface (17) to the first contact surface (16) of the first cam element (11);
characterized in that the first plunger element (12) has a substantially cylindrical side wall (21) and an end wall (32) defining a front surface (17), while the end wall (32) is designed to separate said at least , one working chamber (6) to the first compartment (33) of variable volume and the second compartment (34) of variable volume, which are adjacent to each other and are connected to each other with the possibility of fluid flow, while the first opposing elastic means (18) located in the first separated ii (33). 2. The hinge structure according to claim 1, characterized in that it comprises a finger (13) located inside the first stationary element (2) and having an axis coinciding with the longitudinal axis (X), while the finger (13) has end parts (15 , 15 '), intended for connection with each other with the possibility of rotation of the movable element (3) with the stationary element (2), and the first Central part (14) having a first contact surface (16). 3. The hinge structure according to any one of claims 1 or 2, characterized in that the first contact surface (16) is essentially parallel to the longitudinal axis (X). 4. The hinge structure according to claim 1, characterized in that the first contact surface (16) of the first cam element (11) is located at a distance (g) from the longitudinal axis (X) of between 1 mm and 5 mm and preferably equal to about 2 mm 5. The hinge structure according to claim 1, characterized in that the first compartment (33) of the variable volume has such a shape that it has its maximum volume, and the second compartment (34) of the variable volume has such a shape that it has its minimum volume, when the specified door is in the closed position. 6. The hinge structure according to claim 5, characterized in that it contains a first check valve (21) on the first end wall (32) of the first plunger element (12), while the first check valve (21) is designed to allow the flow of the working fluid from the first compartment (33) to the second compartment (34) after opening the door (P) and to prevent its backflow during closing the door. 7. The hinge structure according to claim 6, characterized in that the first side wall (39) of said first plunger element (12) forms, together with the side wall (38) of the first working chamber (6), an air gap (37) for controlled backflow of the working fluid from the second compartment (34) to the first compartment (33) of variable volume when closing the door (P). 8. The hinge structure according to claim 1, characterized in that the first elastic means (18) act along a transverse direction, which is essentially parallel to the transverse axis (Y) and essentially perpendicular to the longitudinal axis (X). 9. The hinge structure according to claim 1, characterized in that the fixed element (2) comprises a box-shaped housing for accommodating closing means and hydraulic damping means (5). 10. The hinge structure according to claim 1, characterized in that it contains a second working chamber (44), while closing means (4) are located in the first working chamber (6), hydraulic damping means (5) are located as in the first chamber (6 ), and in the second working chamber (44). 11. Hinge structure according to claim 10, characterized in that the closing means (4) include a second cam element (45) and a second plunger element (46), which is mounted with the possibility of longitudinal movement inside the working chamber (44) and is designed to interact with second cam element (45). 12. The hinge structure according to claim 11, characterized in that the central part (14) of the finger (13) has a second contact surface (49) located above the first contact surface (16), while the second contact surface (49) is, according to essentially flat and forms a second cam element (45). 13. The hinge structure according to item 12, wherein the second plunger element (46) has a second end wall (56) for dividing the second working chamber (44) into the third and fourth variable volume compartments (57, 58), which are connected to each other with the other with the possibility of fluid flow, the second elastic means (51) for pressing the second plunger element (46) against the second cam element (45) located in the fourth compartment (58). 14. The hinge structure according to claim 13, characterized in that the closing means (4) and / or hydraulic damping means (5) are made so that the third compartment (57) of variable volume has a minimum volume and the fourth compartment (58) has a maximum volume when the door is in the closed position. 15. The hinge structure according to 14, characterized in that it contains a second check valve (54) in the second end wall (56) of the second plunger element (46) to allow the working fluid to flow from the third compartment (57) to the fourth compartment ( 58) while opening the door (P) and preventing its backflow during closing the door. 16. The hinge structure according to item 12, wherein the second contact surface (49) of the second cam element (45) is substantially parallel to the longitudinal axis (X) and substantially perpendicular to the first contact surface (16) of the first cam element (eleven). 17. The hinge structure according to any one of paragraphs.13-16, characterized in that the first and second elastic means (18, 51) have working directions (Y, Y '), essentially perpendicular to the longitudinal axis (X) and with the opposite orientation (V, V '). 18. A door hinge assembly for closing doors or the like, comprising a first hinge structure (71) according to any one of claims 1-17, characterized in that it comprises a second hinge structure (72) connected to the same door in a longitudinally stepped position relative to the first hinge structure (71) and characterized in that it does not have closing means (4) and contains second damping means (18) for braking and damping movement when closing is created by the closing means (4) of the first hinge structure (71). 19. Hinge assembly according to claim 18, characterized in that the second hinge structure (72) comprises a second pin (13 ') having a corresponding contact surface (82) that is designed to interact with the corresponding plunger means (83) associated with the second damping agents (81). 20. The hinge assembly according to claim 19, characterized in that the second contact surface (82) of the second finger (13 ') is essentially perpendicular to at least one of the contact surfaces (6, 49) of the first finger (13), associated with the first hinge structure (71). 21. The hinge assembly according to claim 20, characterized in that the second hinge structure (72) comprises a corresponding check valve (84) located on the end wall (95) of its plunger element (83) to allow the passage of the working fluid during closing the door and preventing its backflow during door opening. 22. The hinge assembly according to claim 21, characterized in that the check valves (21, 54, 84) associated with the corresponding plunger elements (12, 46, 83) of the first and second hinge structures (71, 72) are normally open valves type.

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