NL2011582C2 - HINGE. - Google Patents

Description

Hinge

The invention relates to a hinge, in particular a door hinge, which is suitable for use in public spaces, such as changing rooms of swimming pools, toilet rooms of campsites, theater halls and cinemas.

Hinges used in such applications must meet a number of requirements. An important requirement is that such a hinge is finger-safe. This means that no spaces are created or present in the hinge during hinging, in which a finger can get caught.

Furthermore, it is desirable that there are no openings in the hinge, so that a dressing room or toilet stall can be viewed from outside, for example.

In addition, it is preferable that a hinge in such applications is self-closing. This will automatically close a door. However, it is then again not desirable for this self-closing to take place at great speed, as a result of which a door with a loud bang closes.

Finally, there is the aesthetic desire to be able to have a door hinged in the same plane as the surrounding wall with a hinge that meets the above requirements, so that one smooth surface is created. This is in contrast to hinges, where doors are hinged up like cover doors.

Various hinges are known in the prior art for the aforementioned applications, which are also referred to as self-closing hinges.

NL 2000469, for example, describes a self-closing hinge with two hinge blades, each provided with a ramp. When the hinge is hinged open, the hinge leaf connected to the door will move up. As soon as the door is released, the hinge leaf will slide down again along the ramp and due to the weight of the door, causing the door to close automatically.

The disadvantage of this construction is that when the door is closed, the door acquires speed and comes to a stop with a slap against the door frame. In addition, this construction is only suitable for overhead doors and will turn up when the hinge is turned, which is not always aesthetic.

To prevent a finger from getting caught in the hinge of NL 2000469, it is further described that a protective cap is fitted over the hinge. US 2009265889 describes a door hinge with an integrated spring for closing a door. A torsion spring is provided in this hinge, which is coupled via a coupling to the hinge blades of the hinge. Upon opening this hinge, the torsion spring will build up tension until the hinge is opened through a certain angle. Then the link will disconnect.

When the hinge is closed, the spring energy of the torsion spring will only be released within the above-mentioned determined angle. To prevent a door from slamming shut too hard, a hydraulic damper is also incorporated in the hinge.

However, the disadvantage of US 2009265889 is that the self-closing function of the hinge is not available over the entire hinge angle. In addition, the construction of this hinge, due to the large number of parts, is complex and expensive.

Furthermore, WO 2004029395 describes a hinge that is made up of two different tubular extrusion profiles. A flange, with a U-shaped cross section, is attached to each extrusion part, into which a wall plate or door plate can be inserted. The hinge pins of this hinge are arranged at the extreme ends.

The advantage of this hinge is that no viewing opening is present regardless of the position of the hinge.

The disadvantage, however, is that there is no room in the hinge for a self-closing mechanism and that two separate extrusion profiles are used to assemble one hinge.

It is now an object of the invention to provide a hinge, wherein the above-mentioned disadvantages are reduced or even prevented, while the stated wishes can be met as much as possible.

This object is achieved with a hinge according to the invention, which hinge comprises: - a first hinge leaf; - a second hinge blade rotatable with respect to the first hinge blade about an axis of rotation; - run-up means with a first run-on part fixedly attached to the first hinge leaf and a second run-on part, which is arranged coaxially on the first run-on part and on the axis of rotation, * wherein the second run-on part is axially slidable with respect to the first run-on part, * wherein the second run-on part is also slidably coupled to the second hinge blade, and * run-on surfaces cooperating between the first and second run-on parts are provided such that the run-on parts are axially displaced from each other by rotation of the two run-on parts relative to each other; and - spring means arranged between the second hinge leaf and the second run-on part for urging the second run-on part in the axial direction towards the first run-on part.

With the hinge according to the invention, the hinge blades, as seen in the axial direction of the axis of rotation, remain stationary, because the second ramp part can move axially with respect to the second hinge blade. In addition, the spring means ensure that the second run-on part is urged in the axial direction, so that a simple and hence inexpensive construction is created.

Because the second ramp part is urged towards the first ramp part, it will slide along the ramp and thereby rotate. Since the second run-on part is coupled to the second hinge blade, the second hinge blade will thereby also rotate relative to the first hinge blade, whereby a self-closing hinge is obtained.

Moreover, the hinge can easily be provided with a covering housing, because only an axial displacement of the second ramp part takes place relative to the second hinge blade.

In a preferred embodiment of the hinge according to the invention, the spring means comprise a gas spring, which gas spring is provided with a damper for damping the end of the stroke of the gas spring.

Because the spring means act axially on the second ramp, a gas spring can easily be used. In addition, gas springs are known, with a so-called soft-close function being added. This means that the gas spring is damped at the end of its stroke, whereby the gas spring slowly reaches its end position on the last part of the stroke. As a result, the hinge in the last part of the stroke will rotate more slowly and, for example, a door attached to the hinge will close softly, without any significant noise. Rubber stop stops, for example, will also be less taxed because the door closes softer.

In a further preferred embodiment of the hinge according to the invention, the first and the second run-on part are telescopically sliding cylindrical parts, the run-on surfaces being provided as two co-operating spiral grooves, each of which is arranged on a cylindrical surface of the run-on parts.

Due to the telescopic construction in combination with the cooperating spiral grooves, a compact construction of the hinge can be obtained, as a result of which a hinge according to the invention will be comparable in dimensions to known hinges.

An additional advantage of the cooperating spiral grooves is that the first and second run-on part can only be taken apart by rotation. In the case that the hinge is mounted between a wall and a door, this means that the door cannot simply be detached by lifting the door.

In yet another preferred embodiment of the hinge according to the invention, the second hinge blade comprises a cylindrical tubular housing, which cylindrical tubular housing is provided on the inner surface with longitudinal guide grooves and wherein the second ramp part is provided on the outside with longitudinal guide ribs and telescopically in the cylindrical housing slides.

Reliable guidance is obtained through the cylindrical housing with telescopically guided second ramp part therein. Moreover, the cylindrical housing of the second hinge blade shields the moving ramp, so that the hinge is finger-safe at the same time.

By not making the guide ribs of the same thickness and arranging them asymmetrically, it can be ensured that the hinge can only be mounted in one way, so that errors during assembly are minimized.

In a further embodiment of the hinge according to the invention, the first and second hinge blade are formed from an equal extrusion profile with a cylindrical, tubular part and a flange arranged tangentially to the tubular part for fixing the hinge to a wall or door.

By using the same equal extrusion profile for both hinge blades, the production costs for the hinge remain low. The tangential attachment of the flange to the tubular part further ensures that the hinge can rotate through 180 ° while it is arranged between, for example, a wall and a door.

These and other features of the invention are further elucidated with reference to the accompanying drawings.

Figure 1 shows a perspective view of an embodiment of a hinge according to the invention.

Figure 2 shows the hinge according to Figure 1 with exploded parts.

Figures 3A and 3B show the hinge according to figure 1 with partially dismantled parts in two different positions.

Figure 1 shows a perspective view of an embodiment of a hinge 1 according to the invention. This hinge is arranged between a wall part 2 and a door part 3.

The hinge 1 has a first hinge leaf 4, to which the wall part 2 is attached and a second hinge leaf 5, to which the door part 3 is arranged.

As in figure 2, which shows the hinge according to figure 1 with exploded parts, clearly 1, both hinge blades 4, 5 are made of the same extrusion profile. A flange 6 is provided on the tubular body of the extrusion profile 4, 5, with which the hinge blades 4, 5 can be attached to a wall part 2 or door part.

A first run-on part 7 is secured in the end face of the hinge leaf 4, a collar 8 preventing the run-on part 7 from sliding too far into the extrusion profile 4. The protruding part of the run-on part 7 is provided with a spiral-shaped groove 9, which cooperates with the spiral-shaped groove 10, which is arranged on the inside of the second run-on part 11.

Longitudinal ribs 12 are provided on the outside of the second ramp 11. In the second hinge leaf 5 a guide bush 13 is provided in the tubular part of the profile 5, which guide is provided on the inside with longitudinal grooves 14. The second ramp 11 can hereby slide telescopically into the second hinge leaf 5, while it is coupled for rotations with the hinge blade 5. The guide bush 13 is further provided with a collar 16, so that the guide bush 13 cannot slide into the profile 5 too far.

Optionally, the guide bush 13 and the hinge leaf 5 can be made as a whole, but by designing it in two parts, a suitable material can be chosen for the articulation bush 13, which ensures good conductivity, while the extrusion profile 5 is made of, for example, aluminum can become.

Furthermore, a gas spring 15 is provided between the second run-on part 11 and the guide bush, which gas spring urges the second run-on part 11 to the first run-on part 7.

Figures 3A and 3B show the hinge according to figure 1 with partially dismantled parts in two different positions. Since the operation of the hinge cannot be seen from a completely assembled state, the second hinge blade 5 together with the guide bush 13 is axially shifted axially over a fixed distance in figures 3A and 3B. Usually, the collar 16 of the guide bush 13 abuts the collar 8 of the first ramp part 7.

Figure 3A shows the initial position of the hinge 1. The flange 6 of the second hinge blade 5 is directed upwards and the flange 6 of the first hinge blade 4 is directed downwards.

When the door 3 is now opened, the second hinged blade 5 will rotate, whereby the second ramp 11 will also rotate. Due to the spiral grooves 9, 10, the second run-on part 11 will thus also move axially and slide telescopically into the guide bush 13, with which also the gas spring 15 will be pressed.

When the door 3 is released, the gas spring 15 will push the second ramp 11 again and the second hinge leaf 5 will turn back to the position as shown in figure 3A.

By selecting a gas spring 15, wherein the last part of the stroke is damped, a damping of the closing of the door 3 can thus also be obtained.

Claims (5)

A hinge comprising: - a first hinge leaf; - a second hinge blade rotatable with respect to the first hinge blade about an axis of rotation; - run-up means with a first run-on part fixedly attached to the first hinge leaf and a second run-on part, which is arranged coaxially on the first run-on part and on the axis of rotation, * wherein the second run-on part is axially slidable with respect to the first run-on part, * wherein the second run-on part is also slidably coupled to the second hinge blade, and * run-on surfaces cooperating between the first and second run-on parts are provided such that the run-on parts are axially displaced from each other by rotation of the two run-on parts relative to each other; and - spring means arranged between the second hinge leaf and the second run-on part for urging the second run-on part in the axial direction towards the first run-on part. 2. A hinge according to claim 1, wherein the spring means comprise a gas spring, which gas spring is provided with a damper for damping the end of the stroke of the gas spring. 3. A hinge according to claim 1 or 2, wherein the first and the second run-on parts are telescopically sliding cylindrical parts, the run-on surfaces being provided as two co-operating spiral grooves, each of which is arranged on a cylindrical surface of the run-on parts. 4. A hinge according to any one of the preceding claims, wherein the second hinge blade comprises a cylindrical tubular housing, which cylindrical tubular housing is provided on the inner surface with longitudinal guide grooves and wherein the second ramp part is provided on the outside with longitudinal guide ribs and telescopically in the cylindrical housing slides. 5. A hinge according to any one of the preceding claims, wherein the first and second hinge blade are formed from an equal extrusion profile with a cylindrical, tubular part and a flange arranged tangentially to the tubular part for fixing the hinge to a wall or door.