NL1041401B1 - Hinge. - Google Patents

Abstract

Hinge for hingedly connecting a panel to a wall comprising a first hinge part and a second hinge part which fit into each other and which are pivotable relative to each other about a pivot axis between a first and a second position and comprising a damping mechanism with damping element provided for exerting a damping force during the transition from second position to the first position, said damping mechanism comprising a control element which is movable away and towards the damping element substantially in the direction of the pivot axis of the damping element, and which is provided to the extent regulate damping force.

Description

HINGE

This invention relates to a hinge for hingedly connecting a panel to a wall comprising a first hinge part and a second hinge part, which fit into each other and which are pivotable relative to each other about a hinge axis between a first and a second position and comprising a damping mechanism with damping element provided for exerting a damping force during the transition from the second position to the first position.

A wall may, for example, be a wall, but it may also be a wall of a piece of furniture or the like. With a panel, for example, a door panel can be indicated, but also a panel of a cupboard can be indicated.

For panels that are hingedly connected to a wall with the aid of hinges, a damping mechanism is often used to damp the closing of the panel. The damping mechanism can be a separate mechanism that is connected to the panel and / or the wall, but the damping mechanism can also be built into one or more of the hinges. The advantage of a hinge with a built-in damping mechanism is that a damping mechanism does not have to be provided separately. Separate damping mechanisms are often experienced as disruptive and their application also takes time.

An example of a hinge with an internal damping mechanism is shown in GB 2406879. This is a self-closing hinge that uses comb elements to achieve self-closing. The first and the second part are provided with corresponding comb elements, wherein in the closed state of the panel the comb elements are completely against each other and wherein during the transition from a closed state to an open state the comb elements move apart, whereby also the first and the move the second part apart. The comb elements want to return to their position that they were in the closed state, so that the hinge, and therefore also the panel connected to the hinge, automatically returns to its closed state. During the transition to the closed state, the first part and the second part move back towards each other. The damping mechanism here comprises a damper which is connected to both the first part and the second part, and thus damps the movement of the first and the second part towards each other, whereby the transition to the closed state is also damped. The disadvantage here is that the amount of damping and when there is damping, is completely dependent on the comb elements. The damping is therefore not optimal. Such a damping mechanism can also only be used with this type of hinges, namely self-closing hinges with comb elements.

Other damping systems where the amount of damping can be adjusted are considerably more complex.

It is therefore an object of the invention to manufacture a hinge with damping mechanism, wherein the damping mechanism per se is simple and ensures a desired and optimum damping.

This object is achieved by providing a hinge with the features indicated in the first paragraph of this description, wherein said damping mechanism comprises a control element which is movable away and towards the damping element substantially in the direction of the pivot axis of the damping element, and is provided to control the amount of damping during the transition of the hinge parts from the second to the first position.

Here the control element is used to control the damping. Such hinges are therefore not only limited to self-closing hinges with comb elements. These hinges can, for example, also be other types of self-closing hinges or non-self-closing hinges. The movement of the control element, in the direction of the hinge axis, relative to the damping element, determines here what damping there is. When the control element moves towards the damping element, the control element exerts forces on the damping element. The damping element counteracts these forces exerted by the control element, so that there is damping. The movement of the hinge between the second position to the first position is thus damped, so that this movement is delayed. The precise movement of the control element relative to the damping element can be selected such that the damping of the hinge is always as optimal as possible. The damping mechanism can for instance be arranged such that the entire transition between the second and the first position is damped or that for example only a part of this transition is damped. The amount of damping during this transition is also adjustable. The damping mechanism of the hinge thus ensures a desired and optimum damping during the transition from the second to the first position.

The hinge parts are provided for hingedly connecting a panel to a wall. The one hinge part is then provided to be connected to the panel while the other hinge part is provided to be connected to the wall. The first position of the hinge then normally corresponds to a closed position of the panel and the second position then normally corresponds to an open position of the panel. With an open position, both the maximum open position of the panel can be indicated as a partially opened position. Namely, when the hinge is used to pivotally connect a panel to a wall, in order to pivotally open and close the panel, the panel, and thus the hinge, is not always fully brought to its maximum open position. The gap between the panel and the position of the panel in the closed position can be indicated by the opening angle. This is the angle between the panel and the position of the panel when it is in a closed position. This opening angle normally also corresponds to the rotation of the hinge parts relative to each other around the hinge axis compared to the position of the hinge parts in the first position, since during the pivoting of the hinge parts the hinge parts rotate relative to each other around the hinge axis . Thus, when the hinge parts rotate relative to each other about the hinge axis, the panel normally makes the same rotation relative to the wall around the hinge axis. In the closed position of the panel, the opening angle is 0 °. The maximum opening angle can for example be 180 °, 100 °, 90 ° or ....

Preferably, the control element, viewed in the direction of the hinge axis, is arranged movably with respect to the two hinge parts mentioned.

The damping element preferably makes contact with the control element so that the control element can exert forces on the damping element. In this way a movement of the control element towards the damping element, in the direction of the pivot axis, is simply able to exert forces on the damping element. For example, there may be a physical contact between the control element and a part of the damping element, the damping element then pushing the control element against something, for example. This physical contact can be a direct or indirect contact. Optionally, there may also be a connection between the control element and a component of the damping element.

The damping force exerted by the damping element is preferably substantially directed in the direction of the hinge axis. The control element is preferably movably arranged in one of the two said hinge parts. The damping element preferably extends along the hinge axis, so that both the control element and the damping element can exert forces on each other along the hinge axis.

In a preferred embodiment, during the transition from the second position to the first position, the sense of movement of the control element changes when the angle of rotation between the two hinge parts reaches a certain limit value. During the pivoting / pivoting of the two hinge parts, the two hinge parts rotate relative to each other. This rotation can be expressed as a function of the angle of rotation that the two hinge parts make relative to each other compared to their mutual position in the first position. This rotation angle normally also corresponds to the opening angle of the panel when the hinge connects a panel to a wall.

It is not necessary that the degree of damping during the transition from the second position to the first position is always the same. In fact, it is often better that damping is dependent on the angle of rotation of the hinge, that is, on the opening angle of the panel, which is connected to the hinge on a wall. The amount of damping can therefore be adjusted here as a function of the angle of rotation. For example, if during the transition from the second position to the first position the angle of rotation is first greater than the said limit value, the control element can for instance substantially move away from the damping element. During the said transition this rotation angle then decreases further and when it becomes smaller than the said limit value, the sense of movement changes and the control element will then mainly move towards the damping element. When the control element moves towards the damping element, the control element exerts (extra) forces on the damping element, so that from then on there is damping or extra damping. If the rotation angle is greater than the limit value, that is to say with a relatively large opening angle of the panel, in principle no or little damping is required. Too much damping could even cause the panel to move too slowly to its closed position. Only after a certain limit value is it necessary that the said transition is damped.

In a specific embodiment, the sense of movement of the control element changes back when said rotation angle becomes substantially 0 °. This is to ensure that the damping is not too great at a very small angle of rotation, so that a panel connected to the hinge can still fall into its lock.

Further preferably, the limit value is between 20 ° and 80 °, even more preferably between 30 ° and 50 °. The above limit values are ideal to ensure that there is sufficient damping without the closing of a panel connected to a wall via the hinge becoming too slow.

The control element is preferably rotatable about the hinge axis. During the transition from the second position to the first position, the control element will rotate around the hinge axis. This rotation around the hinge axis will then partly determine whether the control element moves to or away from the damping element. The degree of damping force is also adjustable as a result.

In a very preferred embodiment the first hinge part comprises a first cam surface, the control element is arranged movably in the second hinge part and the control element comprises a second cam surface, the damping element pressing the control element with its second cam surface against this first cam surface, the control element and the control element first cam surface are arranged such that during the transition from the second position to the first position, the control element rotates with respect to the first cam surface, and wherein the cam surfaces have varying dimensions according to the direction of the pivot axis so that a rotation of the control element relative to the first hinge part is converted into a movement of the control element in the direction of the hinge axis.

Due to the dimensions of the cam surfaces varying in the direction of the pivot axis, these cam surfaces cannot but move apart and move back towards each other as they rotate relative to each other about the pivot axis. By choosing the cam surfaces, it is possible to control how far the control element can move away from the first hinge part and which movement distance it travels between certain rotation angles. The amount of damping, during the transition from the second position to the first position, is therefore easily adjustable.

Furthermore, the first cam surface is preferably a fixed part of the first hinge part and the control element is arranged in the second hinge part such that the control element makes substantially the same rotation with respect to the first cam surface around the hinge axis as the second hinge part with respect to the hinge part first hinge part. This is possible, for example, because the second hinge part comprises one or more channels extending in the direction of the hinge axis, and the control element has corresponding protrusions on these one or more channels, so that the control element cannot rotate about the hinge axis relative to the second hinge part. In these channels the control element can move up and down in the direction of the hinge axis. However, this can also be achieved because the control element is located in a cavity of the second hinge part and the shape of the control element is adapted such that no rotation of the control element relative to the second hinge part is possible. For example, the cavity can have a square cross-section and the control element a substantially equal square cross-section. The amount of damping is very easily adjustable here as a function of the angle of rotation, i.e. as a function of the opening angle of the panel, since the cam surfaces make the same rotation relative to each other around the hinge axis as the second hinge part relative to the first hinge part. For example, the cam surfaces can be arranged such that, at a certain angle of rotation, they abut against each other substantially so that the sense of movement changes during the transition from the open to the closed position when this angle of rotation is exceeded.

Also preferred, the first cam surface of the first hinge part is formed by two opposing protruding cam parts comprising oblique edges forming an angle with the hinge axis. With the help of protruding ridge parts and sloping edges, it is possible to ensure that the ridge surfaces are sufficiently spaced during the transition from the second to the first position, so that there is sufficient damping.

The damping element preferably comprises at least one compressible element that makes contact with the control element. This compressible element can for instance be a piston with pin. The piston is then in a damping substance, such as a gas or a liquid, and can then, for example, make contact with the control element via the pin. The control element will then depress the pin when it moves towards the damping element and thus exert forces on the damping element. The control element can for instance comprise a recess into which the pin fits. However, the damping element can also comprise an compressible spring, such as a coil spring.

In a preferred embodiment, the hinge is of the self-closing type and the first hinge part and the second hinge part form cooperating core elements for this purpose, wherein in the first position the opposite comb surfaces of these comb elements are situated almost completely against each other and wherein during the transition of the first position to the second position, said comb surfaces substantially move apart so that the first hinge part and the second hinge part also move apart. A panel, which is connected to a wall via this hinge, is also also self-closing. In the closed position of the panel, the comb surfaces of the comb elements are substantially against each other. During the transition from the closed position to the open position of the panel, the comb elements separate. Due to, among other things, the weight of the door panel, the comb elements will want to come back together, as a result of which the panel closes on its own. The shape of the comb elements can be adapted in such a way that from a certain angle of rotation between the hinge parts, during the transition from the first position to the second position, the comb elements move back somewhat towards each other. When the hinge is beyond this said angle of rotation, it no longer moves from itself to the first position. This is interesting when it is desired that the panel does not always close by itself.

The hinge preferably further comprises holding means open to keep the hinge open from a certain angle of rotation between the two hinge parts. At certain moments it is not desirable that the panel, which is connected to the wall via the hinge, always closes automatically. With these opening means it is possible to keep the panel open. For example, if the panel can be opened 180 °, the holding means ensure that if, for example, the panel is opened beyond 170 °, the panel no longer closes automatically. These opening means can be the comb elements themselves. The comb elements can for instance be arranged in such a way relative to each other that, during the transition from the first position to the second position, the comb elements first separate and move somewhat backwards from a certain angle of rotation. This rotation angle can be, for example, 170 °. This means that when the panel is opened 180 °, the comb elements first have to move back slightly apart to be able to come to the first position of the hinge. Of course, this is not self-evident, so that the panel also no longer self-closes beyond this specific rotation angle. The control element can also help keep the panel open. For example, a greater damping force may have to be overcome beyond a certain angle of rotation in order to be able to return to the first position of the hinge.

The first hinge part or the second hinge part is preferably provided with the hinge for being placed in a finger-safe profile. In this way, fingers cannot be between the panel and the wall while the panel is hinging. Such a finger-safe profile can for instance be a round hollow profile that rotates around the hinge axis during the pivoting of the panel.

Furthermore, the finger-safe profile preferably comprises a hollow profile and the hinge is a hinge of the self-closing type as described above, wherein the hollow profile is provided for being fixedly connected to a panel and is provided for being movably arranged relative to a panel. wall, according to the direction of the hinge axis. The first or the second hinge part is placed in the finger-safe profile and during opening and closing of the panel the first and the second hinge part move away from each other and towards each other, so that also the finger-safe profile must be able to move in the direction of the hinge axis .

In a very preferred embodiment the first hinge part comprises a substantially cylindrical body around which the second hinge part is arranged hingedly, the damping element is fixedly arranged in the second hinge part and the damping element comprises an compressible element, the substantially cylindrical body comprising a first cam surface, the control element a second cam surface and the depressable element presses the control element with its second cam surface against this first cam surface, the control element being arranged in the second hinge part such that the control element makes substantially the same rotation about the hinge axis relative to the first cam surface as the second cam surface hinge part relative to the first hinge part and wherein the cam surfaces, according to the direction of the hinge axis, have varying dimensions whereby a rotation of the control element relative to the first hinge part is converted in a movement of the control element relative to the first hinge part in the direction of the hinge axis. The substantially cylindrical body thus not only ensures that the second hinge part can pivot relative to the first hinge part, but also provides the cam surface against which the control element is pressed. This is a compact way to obtain a hinge with the desired damping effect. The cam surface can for instance be formed by two protruding cam parts.

The hinge is further preferably of the self-closing type and the first hinge part for this purpose comprises a first comb element which extends around the substantially cylindrical body in a fixed position relative to the substantially cylindrical body, and the second hinge part for this comprises a form-fitting second comb element, wherein in a closed position the opposite comb surfaces of these comb elements are situated substantially completely against each other and wherein during the transition from the first position to the second position, said comb surfaces move apart so that also the first hinge part and the second hinge part move apart .

This invention will now be further elucidated with reference to the following detailed description of a preferred embodiment of a hinge according to the present invention. The purpose of this description is to give only illustrative examples and to indicate further advantages and details of this hinge, and can therefore in no way be interpreted as a limitation of the scope of the invention or of the patent rights claimed in the claims.

In this detailed description reference is made by reference numerals to the accompanying drawings, in which figure 1 is a front view of a hinge according to the invention, the angle of rotation between the first and the second hinge part being 0 °; Figure 2 is a front view of the hinge as shown in Figure 1, wherein the angle of rotation between the first and the second hinge part is 170 °; figure 3 represents a cut-away perspective of the hinge as shown in figures 1 and 2; figures 4A-C represent three front views of the hinge as shown in figures 1 to 3, wherein the second hinge part is not shown so that the underlying parts are visible and wherein the angles of rotation between the first and the second hinge part of the three front views from left to right are 0 °, 43 ° and 170 ° respectively; Figure 5 is a perspective representation of the first hinge part; Figure 6 is a perspective representation of the control element; figure 7 is a perspective representation of the comb element of the first hinge part; Figure 8 is a perspective representation of the second hinge part.

The hinge (1) as shown in the figures comprises a first and a second hinge part (2, 3) which are respectively provided for being attached to a wall and a door panel. With the aid of the hinge (1) it is possible to hinge the door panel to the wall.

The first hinge part (2) and the second hinge part (3) are mutually fitting and pivotably connected to each other at the level of a hinge axis (4), so that the second hinge part (3) can perform a rotation around the hinge axis (4) with respect to of the first hinge part (2). The hinge (1) is pivotable between a first position and a second position. Furthermore, the first hinge part (2) comprises a mounting plate (13) with openings (22), the mounting plate (13) being attachable to the wall in a fixed position by mounting screws (18) through the openings (22) in the wall. The second hinge part (3) also comprises a mounting plate (14), which is provided to be arranged in a cavity of the door panel, in a fixed position relative to the door panel. Since the door panel and the wall are each fixed in a fixed position to the second hinge part (3) and the first hinge part (2), the door panel will make the same movement relative to the wall as the second hinge part (3) relative to the first hinge part (2). This means that the door panel, during its hinging, will make a rotation relative to the wall around the hinge axis (4), which is the same as the rotation of the second hinge part (3) relative to the first hinge part (2) around the hinge axis (4). This makes the door panel pivotable between a closed position and an open position, the closed position corresponding to the first position of the hinge (1) and the open position corresponding to the second position of the hinge (1). For the sake of simplicity, the closed and open position are further discussed here.

The position of the door panel is shown here as the angle that the door panel makes with respect to the door panel when it is in the closed position. This angle is further referred to here as the opening angle. The opening angle in the closed position is therefore 0 ° and here in the fully open position it is 180 °. This opening angle also corresponds to the angle of rotation that the second hinge part (3) must make with respect to the first hinge part (2) from the closed position in order to arrive at that opening angle of the door panel. The rotation angle here corresponds to the opening angle, so that, for the sake of simplicity, only the opening angle is referred to below.

When a door panel is attached to a wall with the aid of the hinge (1), the second hinge part (3) is located on and around the first hinge part (2). This is visible in figures 1 and 2. The first hinge part (2) comprises a base (23) on which the mounting plate (13) rests and on which also a substantially cylindrical body (12), with two projecting parts (7) on top, is supported. The axis of symmetry of the substantially cylindrical body (12) extends substantially along the hinge axis (4). The two protruding parts (7) are opposite each other and are situated at a certain distance from the hinge axis (4) and form substantially each other's mirror image with respect to the hinge axis (4). Furthermore, the second hinge part (3) centrally comprises a cavity (15) so that the second hinge part (3) can be arranged around the substantially cylindrical body (12) and can make the rotation around the hinge axis (4). The substantially cylindrical body (12) is therefore the physical part around which the second hinge part (3) rotates.

The first hinge part (2) further comprises also a first comb element (10). This comb element (10) is shown here as a separate part of the first hinge part (2), but the first hinge part (2) could just as well be manufactured as a whole. The first comb element (10) centrally comprises a cylindrical opening so that it can be arranged around the substantially cylindrical body (12) until it rests on the base (23). The base (23) comprises protrusions (21) at the level of the first comb element (10) and the first comb element (10) comprises recesses (20) corresponding to these protrusions (21), so that the protrusions (21) can be arranged in the recesses (20). As a result, the first comb element (10) cannot rotate relative to the substantially cylindrical body (12) around the hinge axis (4). The second hinge part (3) further comprises a second comb element (11) corresponding to the first comb element (10). The second hinge part (3) rests with its lower comb surface (25) of the second comb element (11) on the comb surface (24) of the first comb element (10). These comb surfaces (24, 25) are inclined surfaces that form a certain angle with the hinge axis (4).

In the closed position, that is, at an opening angle of 0 °, the comb surfaces (24, 25) of the two comb elements (10, 11) are almost completely against each other and the second hinge part (3) is in its lowest position with respect to the base surface (23) of the first hinge part (2) (see figure 1). The comb surfaces (24, 25) are not completely against each other. This will be clarified later. During pivoting of the second hinge part (3) relative to the first hinge part (2), from the closed position to a more open position, the second hinge part (3) will rotate relative to the first hinge part (2) about the hinge axis (4). Due to the inclined surfaces (24, 25) of the comb elements (10, 11), the second hinge part (3) cannot move upwards other than according to the hinge axis (4) away from the first comb element (24). During pivoting, the second hinge part (3) will therefore not only rotate relative to the first hinge part (2) around the hinge axis (4). The second hinge part (3) will also perform an up and down movement relative to the first hinge part (2) in the direction of the hinge axis (4). The highest position of the second hinge part (2) relative to the base surface (23) of the first hinge part (2) is obtained here when the opening angle is 170 ° (see figure 2). At an opening angle between 0 ° and 170 °, the comb elements (10, 11) will want to return to the position they had at the opening angle of 0 °. The door panel is therefore self-closing using the hinge (1).

The hinge (1) also comprises a damping mechanism for at least partially damping the closing of the door panel.

The damping mechanism comprises various components. For example, it first of all comprises a damping element (5), namely a hydraulic damper. This damper (5) consists of a cylinder with hydraulic fluid, in which a piston with pin (9) is located, wherein the pin (9) can be moved up and down in cylinder. The damping mechanism further comprises a control element (6) and the projecting parts (7) of the substantially cylindrical body (12) of the first hinge part (2) also form part of the damping mechanism.

The hydraulic damper (5) is located at the top in the cavity (15) of the second hinge part (3) and is connected with its cylinder in a fixed position to the second hinge part (3). The cylinder is connected to the second hinge part (3) in such a way that its axis of symmetry substantially corresponds to the hinge axis (4). As a result, the piston with pin (9) can be moved up and down in the direction of the pivot axis (4). The hydraulic fluid is provided to always push the piston to the bottom position of the cylinder, so that the pin (9) always wants to protrude to the maximum with respect to the cylinder.

The control element (6) comprises at the top a notch in which the pin (9) can be partially fitted so that the hydraulic damper (5) makes contact with the control element (6) via its pin (9) and is thus connected to it. The control element (6) is provided to control the damper (5) so that there is damping when damping is desired. For this purpose, the control element (6) is movably arranged in the cavity (15) of the second hinge part (3) in the direction of the hinge axis (4). Furthermore, the edge of the cavity (15) of the second hinge part (3) at the level of the control element (6) comprises grooves (16) and the control element (6) comprises corresponding protrusions (17), said protrusions (17) are located in the grooves (16), so that the control element (6) cannot rotate relative to the second hinge part (3) around the hinge axis (4). Because the control element (6) can be moved downwards in the second hinge part (3), the control element (6) can push the pin (9) with piston such that the piston moves upwards in the cylinder. Pressing the pin (9) is muted.

The movement of the control element (6) is shown below. The protruding parts (7) of the substantially cylindrical body (12) are protruding cam parts (7) which form a first cam surface at the top. The control element (6) is provided at the bottom with a second cam surface corresponding to this first cam surface. The pin (9) presses the control element (6) against the two cam parts (7). During pivoting of the hinge (1), the control element (6) will make the same rotation relative to the two cam parts (7) around the hinge axis (4) as the second hinge part (3) with respect to the first hinge part (2). This is because the control element (6) cannot rotate relative to the second hinge part (3) around the hinge axis (4) and thus moves with the second hinge part (3) around that hinge axis (4) and because the first cam surface remains stationary with respect to of the wall. To simplify the rotation, the control element (6) is provided at the bottom with a cylindrical part (19) which can be located between the opposite cam parts (7). The cam surfaces include beveled edges (8) that vary in height following the pivot axis (4) whereby the rotational movement of control element (6) relative to the first cam surface is converted into an up and down movement of the control element (6). During the up and down movement, the control element (6) will also cause movement of the pin (9).

The cam parts (7) and the control element (6) are positioned relative to the substantially cylindrical body (12) and the second hinge part (3), respectively, that at an opening angle of almost 43 °, the cam surfaces abut almost completely against each other ( see figures 4A-C). This means that at this opening angle the control element (6) is at its lowest position with respect to the first hinge part (2). This could of course also be with a different opening angle.

During the transition from the open position to the closed position, as soon as the opening angle becomes smaller than 43 °, the control element (6) will move away from the first hinge part (2) and thus move upwards according to the hinge axis (4). During this said transition, the second hinge part (3) also moves to its lowest position with respect to the base surface (23) of the first hinge part (2). Since the cylinder of the damper (5) is fixedly connected to the second hinge part (3), the cylinder will also move downwards. This means that, as the door panel closes, as soon as the opening angle becomes smaller by 43 °, the control element (6) moves towards the cylinder of the damper (5) and also the cylinder moves towards the control element (6) . As a result, the control element (6) hugely presses the pin (9), so that there is much damping. As soon as an opening angle of 43 ° is reached, there is a lot of damping, which means that the closing of the door panel is properly damped. Even when the door panel does not close automatically but is closed, there is sufficient damping to ensure that the door panel does not close too hard. The damping here is also not too great so that the door panel and therefore also the hinge (1) can still effectively return to its closed position. In figures 4A-C it is visible that with a closed state, namely an opening angle of 0 °. The control element (6) is substantially in its highest position and the cylinder of the damping element (5) is in its lowest position. The pin (9) is almost fully depressed.

During closing of the door panel, when the opening angle is even greater than 43 °, the control element (6) moves towards the first hinge part (2). The cylinder of the damper (5) also moves towards the first hinge part (2). The speed of movement of the control element (6) and the cylinder will determine whether or not there is a relative movement of the control element (6) towards the cylinder and whether there is therefore damping when the opening angle is greater than 43 °.

Figures 4A-C show that at a rotation angle of 170 ° the control element (6) and the cylinder of the damping element (5) are in their highest position. Thus, during the transition between the opening angle of 170 ° to the opening angle of 43 °, the control element (6) and also the cylinder will drop. When the opening angle of 43 ° is exceeded, the sense of movement of the control element (6) changes, as a result of which the control element (6) then essentially moves back upwards. As a result, the pin (9) is pressed (extra), so that there is damping from 43 °.

As already stated before, the comb surfaces (24, 25) of the comb elements (10, 11) do not lie fully against each other when the opening angle is 0 °. The opening angle at which the comb elements (10, 11) are furthest away from each other is then not at 180 ° here. During the opening of the door panel, the second hinge part (3) will further move away from the first hinge part (2). At an opening angle of almost 170 °, the comb elements (10, 11) are positioned here relative to each other such that the second hinge part (3) is at its highest possible position relative to the base surface (23) of the first hinge part (2) state. When the door panel is opened even more, the second hinge part (3) will lower somewhat. This means that at an opening angle above 170 °, the second hinge part (2) must first rise a little to be able to close the door panel. The rise of the door panel does not, of course, occur by itself, so that the door panel remains open when the door panel is opened further than 170 °. If the door panel is opened less than 170 °, the door panel will automatically return to its closed position.

The cam surfaces are also adapted so that the cam surfaces prevent the door panel from closing when the opening angle is greater than 170 °. For this purpose, each cam part (7) comprises two sloping edges (8) at the top. During the transition from the opening angle of 43 ° to the opening angle of 170 °, the control element (6) moves upwards from its lowest position along a first said oblique edge (8), said first oblique edge (8) being substantially an angle of 20 ° with the hinge axis (4). When the opening angle becomes even greater than 170 °, the control element (6) sinks back a little downwards along a second said oblique edge (8). In order to then be able to go to the closed position, the control element (6) must first move a little upwards, so that there is some damping. As a result, the door panel is even less inclined to close itself when the opening angle is greater than 170 °.

Said angle of the first oblique edge (8) determines the distance that the control element (6) makes along the hinge axis (4) during pivoting. The smaller this angle, the greater the mentioned distance and the greater the possible damping force. This angle can for instance be between 10 ° and 40 °.

Claims (16)

A hinge (1) for hingedly connecting a panel to a wall comprising a first hinge part (2) and a second hinge part (3), which fit into each other and which can be pivoted relative to each other about a hinge axis (4) between a first and a second position and comprising a damping mechanism with damping element (5) provided for exerting a damping force during the transition from the second position to the first position, characterized in that said damping mechanism comprises a control element (6) which is substantially can be moved away from the damping element (5) in the direction of the pivot axis (4) and towards the damping element (5), and is provided to control the amount of damping during the transition of the hinge parts (2, 3) of the second to the first position. A hinge (1) according to claim 1, characterized in that the control element (6), viewed in the direction of the hinge axis (4), is arranged movably relative to the two said hinge parts (2, 3). Hinge (1) according to claim 1 or 2, characterized in that the damping element (5) extends along the hinge axis (4). Hinge (1) according to one of the preceding claims, characterized in that the sense of movement of the control element (6) changes during the transition from the second position to the first position when the angle of rotation between the two hinge parts (2, 3) ) reaches a certain limit value. The hinge (1) according to claim 4, characterized in that the limit value is between 20 ° and 80 °. A hinge according to any one of the preceding claims, characterized in that the control element (6) is rotatable about the hinge axis (4). Hinge (1) according to one of the preceding claims, characterized in that the first hinge part (2) comprises a first cam surface, the control element (6) is movably arranged in the second hinge part (3) and comprises a second cam surface, wherein the damping element (5) presses the control element (6) with its second cam surface against this first cam surface, the control element (6) and the first cam surface being arranged such that during the transition from the second position to the first position, the control element (6) ) makes a rotation relative to the first cam surface, and wherein the cam surfaces have varying dimensions in the direction of the pivot axis (4) whereby a rotation of the control element (6) relative to the first pivot part (2) is converted into a movement of the control element (6) in the direction of the hinge axis (4). Hinge (1) according to claim 7, characterized in that the first cam surface is a fixed part of the first hinge part (2) and the control element (6) is arranged in the second hinge part (3) such that the control element (6) ) makes substantially the same rotation (4) relative to the first cam surface around the hinge axis as the second hinge member (3) relative to the first hinge member (2). A hinge (1) according to claim 7 or 8, characterized in that the first cam surface of the first hinge part (2) is formed by two opposite protruding cam parts (7) comprising oblique edges (8) forming an angle with the hinge axis (4). Hinge (1) according to one of the preceding claims, characterized in that the damping element (5) comprises at least one compressible element (9) which makes contact with the control element (6). A hinge (1) according to any one of the preceding claims, characterized in that the hinge (1) is of the self-closing type and the first hinge part (2) and the second hinge part (3) form cooperating comb elements (10, 11) for this purpose wherein, in the first position, the opposing comb surfaces (24, 25) of these comb elements (10, 11) are substantially completely abut against each other and wherein during said transition from the first position to the second position, said comb surfaces (24, 25) move substantially apart, so that the first hinge part (2) and the second hinge part (3) also move apart. A hinge (1) according to claim 11, characterized in that the hinge (1) comprises holding means open to keep the hinge (1) open from a certain angle of rotation between the two hinge parts (2, 3). Hinge (1) according to one of the preceding claims, characterized in that the first hinge part (2) or the second hinge part (3) is provided with the hinge (1) for being placed in a finger-safe profile. 14. A hinge (1) as claimed in claim 11 or 12 and claim 13, characterized in that the finger-safe profile comprises a hollow profile, said hollow profile being provided for being fixedly connected to a panel and being provided for being movably arranged for relative to a wall, according to the direction of the hinge axis (4). The hinge (1) according to one of the preceding claims, characterized in that the first hinge part (2) comprises a substantially cylindrical body (12) around which the second hinge part (3) is hingedly arranged, the damping element (5) being fixedly arranged in the second hinge part (3) and the damping element (5) comprises an compressible element (9), wherein the substantially cylindrical body (12) comprises a first cam surface, the control element (6) comprises a second cam surface and the compressible element (9) the control element (6) presses with its second cam surface against this first cam surface, the control element (6) being arranged in the second hinge part (3) such that the control element (6) rotates substantially the same around the hinge axis (4) with respect to the the first cam surface makes, as the second hinge part (3) relative to the first hinge part (2) and wherein the cam surfaces vary in the direction of the hinge axis (4) have a rotation whereby the rotation of the control element (6) relative to the first hinge part (2) is converted into a movement of the control element (6) relative to the first hinge part (2) in the direction of the hinge axis (4). A hinge (1) according to claim 15, characterized in that the hinge (1) is of the self-closing type and the first hinge part (2) for this comprises a first comb element (10) which extends around the substantially cylindrical body (12) in a fixed position relative to the substantially cylindrical body (12), and the second hinge part (3) for this comprises a form-fitting second comb element (11), wherein in a closed position the opposite comb surfaces (24, 25) of these comb elements (10) 11) are substantially completely abutting against each other and wherein during the transition from the first position to the second position, said comb surfaces (24, 25) move apart so that also the first hinge part (2) and the second hinge part (3) move apart.