The invention relates to door closer arrangements, which are used when doors are closed and opened.
Door closers are used in order to close doors after the opening operations of the doors. The door closer can be mounted on the surface of a door or on the surface of a door frame. Some door closer arrangements comprise a slide rail. If the door closer has been mounted on the door, the slide rail has been mounted on the door frame, or the installation is vice versa.
When the door is opened the opening force is quite big at the small opening angles of the door. This is due to the structure of the door closer having a spring inside. The spring tensions when the door is opened. The tension of spring moves the piston of the door closer back to its initial position, i.e. moves the door to the closed position, after the opening of the door. So, the user of the door does not need to push or pull the door for closing it.
The user of the door can notice that the force needed to open the door is substantial at the beginning of the opening operation. The force needed may be experienced to be too big and therefore unpleasant. On the other hand, it may occur that when closing the door, the closing power may be not enough to close the door properly in all situations.
The object of the invention is to achieve a door closer arrangement where the force needed for opening the door is not so substantial than in known solutions, and the closing power is improved. The aim of the invention is obtained by a door closer arrangement of an independent claim. Dependent claims illustrate different embodiments of the invention.
A door closer arrangement according to the invention comprises a door closer, a slide rail, and an arm that connects the door closer with the slide rail. The arrangement comprises also a second rail, and a carriage to be attached to the second rail in a sliding manner. The carriage is arranged to form an attachment with the door closer.
The door closer arrangement further comprises a first low-friction arrangement between the second rail and the carriage, and a second low-friction arrangement between the arm and the slide rail. The door closer arrangement also comprises an auxiliary motion arrangement in order to aid movement of the carriage and the door closer along the second rail. The auxiliary motion arrangement comprises a raising part at a first end of the second rail forming a slide slope for the door closer. The first end is the end to be installed nearby a hinge side of a door. The auxiliary motion arrangement comprises also an auxiliary spring arrangement.
The auxiliary spring arrangement comprises a harvesting arm, a carrier and a third rail. The third rail is on the second rail and the carrier being attached moveable on the third rail so that the carrier is capable to move along the third rail. The harvesting arm is turnable attached to the carrier on a first end of the harvesting arm, and is turnable and moveable attached to the slide rail on a second end of the harvesting arm.
The auxiliary spring arrangement further comprises an harvesting spring attached on the second rail and a transmission mechanism between the harvesting spring and the carrier in order to tension the harvesting spring when the carrier and the harvesting arm move towards the first end of the second rail, and also to release energy of the harvesting spring when the carrier and the harvesting arm move away from the first end of the second rail. The auxiliary spring arrangement also comprises a switch mechanism in order to keep the carrier at a first end of the second rail and to release the keeping of the carrier when the door has moved to a closed position.
The door closer arrangement comprises also an attachment part attached on the carriage on the second rail, and the transmission mechanism comprises a connection part having a protruding part. The connection part is arranged to move the carriage through the protruding part towards the first end of the second rail after the release of the keeping of the carrier.
The door closer arrangement comprises also a safety switch arrangement, which comprises a frame part and a pin. The frame part is arranged to drive the pin when the door is opened few degrees. The safety switch arrangement further comprises a shoulder part that is a part of the protruding part, and a guide block on vicinity of the second end of the second rail. The said driving of the pin is arranged to move the protruding part away from a protruding position, and said guide block is arranged to move the protruding part to the protruding position when the connection part moves towards the second end of the second rail.
In the following, the invention is described in more detail by reference to the enclosed drawings, where
The auxiliary motion arrangement comprises a raising part 10 at a first end 9B of the second rail forming a slide slope for the door closer. The first end is the end to be installed nearby a hinge side 4A of a door 2. The auxiliary motion arrangement comprises also an auxiliary spring arrangement 67. See
As can be seen in
The second rail 9 makes it possible that the door closer can move along the second rail. The movement of the door closer when opening and closing the door 2 makes the opening of the door more easy and also improves the closing of the door.
The auxiliary spring arrangement 67 is showed in more detail in
In
When closing the door from the fully opened position to an opening angle of about 20-30 degrees, the door closer remains at the first end 9B of the second rail 9. (The zero angle means that the door is closed.) Depending on an embodiment the door closer 9 and the carriage 17 starts to move towards the second end 9C of the second rail 9, in other words towards the lock side 5 at the opening angle of about 20-30 degrees.
The movement towards the lock side 5, is achieved by aid of the auxiliary motion arrangement. As said the raising part 10 at the first end 9B of the second rail forms the slide slope on the second rail for the door closer. The slide slope can actually be enough to move the door closer towards the lock side 5 of the door, so in which case the auxiliary spring arrangement is used only for moving the door closer back to the hinge side 4A, which is explained more later. As can be noticed the slide slope is a slope in relation to the surface 2A of the door.
When the door closer 6 is at the second end 9C of the second rail 9, i.e. near the lock side 5 of the door, or when moving towards the lock side, the closing power is bigger than keeping the door closer relatively near the hinge side 4A of the door. Therefore, the door closing action is improved in relation to know solutions.
The auxiliary spring arrangement further comprises an harvesting spring 48 attached on the second rail 9 and a transmission mechanism 47 between the harvesting spring 48 and the carrier 43 in order to tension the harvesting spring 48 when the carrier 43 and the harvesting arm 41 move towards the first end 9B of the second rail. The harvesting spring is conveniently attached to the second rail by using an attachment body 63. The opening angle area of the door wherein energy is harvested depends on an embodiment. The door weight, the power of the door closer 6, the slide slope performed by the raising part 10 and the second rail, the power of the harvesting spring and other parameters may vary. So, an energy harvesting range can be from a few degrees of the opening angle to the full opening angle of the door. An extreme embodiment may have the energy harvesting range starting from zero degree, but then user experience is not so good. In the figures the energy harvesting range is about 15-55 degrees. However, other ranges can be implemented as well, like about 10-30 degrees.
After the opening of the door and when the door is not kept open, the door closer 6 closes the door. The door closer is at the first end 9B of the second rail 9 at the beginning of the closing the door until the door has turned enough, let's say for example to an door opening angle a little more than 30 degrees, when the door closer starts to move along the second rail towards the lock side 5 of the door, ie. towards the second end 9C of the second rail 9. The movement towards the lock side is achieved by the slide slope.
The energy of the harvesting spring 48 is released when the carrier 43 and the harvesting arm 41 move away from the first end 9B of the second rail. The auxiliary spring arrangement also comprises a switch mechanism 50, 51, 52 in order to keep the carrier 43 at a first end 9B of the second rail and to release the keeping of the carrier 43 when the door 2 has moved to a closed position.
The switch mechanism embodiment of the examples of the figures comprises a retainer pin 51 to keep the carrier 43 at a first end 9B of the second rail and a release pin 52 to release the keeping of the carrier when the door 2 has moved to a closed position. The switch mechanism further comprises an axis 50 being provided with the retainer pin 51, the release pin 52 and a bias spring 53. The bias spring is arranged to turn the axis 50 in order to keep the retainer pin 51 at a retaining position. In other words, the bias spring turns the retainer pin towards the third rail 45 where the carrier 43 moves.
When the door is closed, at the end of the closing action, the release pin hits to the frame 3 of the door 2 or a specific plate 64 attached to the frame. The frame or the plate turns the release pin 52 which causes the turning of the axis 50 and the retainer pin 51. So, the retainer pin turns away from the retaining position where it keeps the carrier 43 in place. When the retainer pin has turned away from the retaining position the harvesting spring 48 pulls the carrier through the transmission mechanism 47 to move towards the second end 9C of the second rail 9.
As can be seen from the figures the carrier 43 has a guiding surface 44 for the retaining pin 51 for allowing the movement of the carrier towards the first end 9B of the second rail. The guiding surface is a slope in this embodiment. Further, the transmission mechanism comprises a belt, a band, a strip, a chain or a string 47 in the embodiments illustrated in the figures. The transmission mechanism may also comprise an idler 49 in order to direct the belt, a band, a strip, a chain or a string 47 to another direction as showed in the figures. So, the transmission mechanism can have a relatively long linear functioning distance located in a relatively short space. The transmission mechanism also comprises a connection part 54 between the harvesting spring 48 and the belt, band, strip, chain or the string 47. The connection part can make the attachment between the belt etc. and the harvesting spring to be more reliable or easier. The door closer arrangement may also comprise a fourth rail 46 on the second rail 9 forming a slide guide for the connection part 54.
The door closer arrangement comprises also an attachment part 62 attached on the carriage 17 on the second rail 9 and the connection part 54 has a protruding part 58. The connection part is arranged to move the carriage 17 and therefore also the door closer 6 through the protruding part 58 towards the first end 9B of the second rail 9 after the release of the keeping of the carrier 43. In other words, the harvested energy, which has been stored in the harvesting spring 48, is used to move the door closer back to the first end 9B of the second rail.
In addition, the auxiliary spring arrangement can further comprise a second harvesting spring 56 attached on the carriage 17 through the attachment part 62. Since it is convenient to situate the harvesting spring and the second harvesting spring to the other side of the second rail 9, the attachment to the carriage is made via a longitudinal slot 61 as illustrated in the figures. The attachment may utilize screws or bolts. The attachment part 62 performs a support for the second harvesting spring. As can be seen in the figures the third and fourth rails 45, 46 are situated on the other side of the second rail.
The harvesting spring and the second harvesting spring have metal strips 66, 65 in the embodiments of the figures, although the springs can be any suitable spring types.
The end of the metal strip 66 of the second harvesting spring is connected to a second connection part 55, which is arranged to move with the connection part 54 when tensioning the harvesting spring 48. So, the second harvesting spring is arranged to be tensioned at the same time, and to aid movement of the carriage 17 from the first end of the second rail 9. As can be noted the connection parts provide other useful features as well. As said the second harvesting spring 56 can be tensioned at the same time when the harvesting spring 48 is tensioned. The tension of the second harvesting spring may also be used to aid partly the movement of the carrier 43 towards the second end 9C of the second rail.
The second connection part 55 can comprise a projection 57 towards the connection part 54. The projection makes it possible to tension the second harvesting spring at the same time when tensioning the harvesting spring 48. When the connection part 54 moves, the second connection part 55 moves also due to the projection 57.
The connection part can have a protruding part 58 that is arranged to be against the attachment part 62 when the connection part 54 and the second connection part 55, are at the first end 9B of the second rail 9. The protruding part 58 is also arranged to be against the attachment part 62 when the second connection part 55 is at the vicinity of a second end 9C of the second rail and the second harvesting spring 56 have been released from tension, i.e. the door closer is at the second end 9C of the second rail as well. Further, the protruding part 58 is also arranged to be against the attachment part 62 when the tension of the harvesting spring 48 is releasing.
So, at the first case when the both connection parts 54, 55 are at the first end 9B of the second rail kept by the harvesting spring 48 is the situation where the door is closed. The second case is when the second connection part 55 is at the vicinity of a second end 9C of the second rail because the harvesting spring 48 has been tensioned, and the second harvesting spring 56 have been released from tension, so the second harvesting spring has aided the door closer 6 to move to the second end 9C of the second rail 9. The third case occurs when the door closer is moved back to the first end 9B of the second rail by the harvesting spring 48 after the door has been closed.
The door closer arrangement may also comprise a second bias spring 42 at the first end 41B of the harvesting arm 41 in order to keep the harvesting arm in suitable positions. The figures show positions where the second end 41A of the harvesting arm more near the lock side 5 than the first end 41B, but the positions can be designed to second end 41A be others. The first end 41B of the harvesting arm can be more near the lock side 5 than the second end 41A.
Further, the auxiliary motion arrangement may also comprise a second raising part 10A at a second end 9C of the second rail. The height and thus also the angle of the slide slope can be designed by the height of the raising part 10 and/or the second raising part 10A. Therefore, the slide slope can be designed to be suitable for different door closers and different doors. The raising parts 10, 10A can be integral parts with the second rail 9 or separate parts to be fixed with the second rail. The slide slope aids the movement of the door closer 2 (and the carriage 17) along the second rail 9. The second rail 9 can comprise at least one slide guide 9A to form the sliding attachment to the carriage 17.
As said above, in order that the door closer can be moved back the first end 9B of the second rail 9 after the door is closed, the auxiliary spring arrangement is used. So, when the door is back at the closed position, the auxiliary spring arrangement moves the door closer back to the hinge side 4A.
The bearing arrangement can be achieved in many ways. It can be a rolling bearing arrangement in the carriage 17. This arrangement comprising wheels 19A, which are arranged to contact the second rail 9 in a vertical direction, and wheels 19B, which are arranged to contact the second rail 9 in a horizontal direction. In this way the carriage contacts the slide guides via the wheels in the vertical and horizontal directions.
The carriage 17 can comprise four support members 25, which comprise the said wheels 19A, 19B, each support member having at least one wheel 19A in the vertical direction, and at least one wheel 19B in the horizontal direction.
The bearing arrangement can also be a rolling bearing arrangement in the slide guide 9A. See
The bearing arrangement can also be a plain bearing wherein the carriage 17 comprises sliding surfaces 20 and the slide guide/s 9A comprising second sliding surfaces 22, the sliding surfaces and/or the second sliding surfaces comprising friction reducing ingredients. The plain bearing can be achieved by using a suitable material/a material layer like Teflon. It is also possible to combine the plain bearing and the described rolling bearing arrangements.
The second bearing arrangement can comprise a ball bearing 23 or a roller bearing, which ball/roller bearing 23 comprises a ring 24 in order to provide a contact with the slide rail 7. See
The second bearing arrangement can also be a plain bearing. This embodiment comprises third slide surfaces 30, 31 comprising friction reducing ingredients. The third slide surfaces are surfaces of a slide piece 29, which contact with the internal surfaces of the slide rail 7. See
As disclosed above the invention can be obtained by using the harvesting spring 48 only. In this kind of embodiment there is more freedom to construct the inventive arrangement, since there is not the second harvesting spring 56. The harvesting spring can be obtained by different spring types. For example, a spiral torsion spring or a constant torque spring can be placed to the second end 9C of the second rail in which case any idler is not installed, and the transmission mechanism 47 is relatively short between the carrier 43 and the harvesting spring.
The other embodiment disclosed above is the arrangement with harvesting spring 48 and the second harvesting spring 56. In this embodiment the movement of the door closer from the second end 9C of the second rail to the first end 9B is made more reliable by the second harvesting spring.
The door closer arrangement comprises also a safety switch arrangement, which is illustrated in
So, when the door has opened little the driving surface 77 pushes the pin, which in turn pushes a shoulder part 75 that is a part of the protruding part 58. So the safety mechanism comprises also the shoulder part and a guide block 76 on vicinity of the second end 9C of the second rail 9. The driving of the pin 71 is arranged to move the protruding part 58 away from a protruding position. The protruding position is illustrated in
However, if the door is not opened enough, for example 10-20 degrees only, the harvesting spring 48 will not be tensioned.
Further it can be seen in
As can be seen from the figures, the pin 71 comprises a head 72 being arranged to be contact with the frame part 70 when the door is opened few degrees, and a push head 74 being arranged to push the shoulder head 75 due to the said contact with the frame part 70. Further, there is a return spring 78 to bias the pin 71 so that the pin and its head 72 is ready for the contact with the frame part. The safety switch mechanism may also comprise a body 73 attached to the second rail 9B at vicinity of the first end 9B. The body supports the pin 71.
After the partial opening of the door and the closing of the door the next opening of the door is not so easy than normally in this arrangement, because the door closer has not been moved to the first end 9B, but it is at the second end 9C of the second rail 9. When this opening is made properly so that the harvesting spring 48 is going to tension, the safety mechanism is returned to a normal mode. This happens when the connection part 54 moves towards the second end 9C of the second rail and the guide block 76 moves the protruding part 58. See
As can be seen the safety switch mechanism can comprise a holding mechanism 81 in order to keep the protruding part 58 at the protruding position as the case is in
As can be noticed above the invention can be made in many different ways. Further, is can mounted so that the second rail 9 is mountable on the door 2 or on a door frame 3, and the slide rail 7 is mountable on the door or the door frame. The invention performs an easy opening of the door and a safe closing of the door. When the door is closed the function of the tensioned spring of the door closer 6 is improved by the movement of the door closer along the second rail 9 towards the lock side 5 of the door 2. Using the raising part 10 at the first end 9B of the second rail wherein the second rail has a certain angel in relation to the surface of the door or the door frame, and thus the second rail performs the slide slope. The slide slope can reduce power consumption when the door is closed.
It is evident from the above that the invention is not limited to the embodiments described in this text but can be implemented utilizing many other different embodiments within the scope of the independent claims.
Number | Date | Country | Kind |
---|---|---|---|
20151000 | Jan 2020 | EP | regional |
Number | Name | Date | Kind |
---|---|---|---|
3909877 | Christy | Oct 1975 | A |
4419787 | Lieberman | Dec 1983 | A |
4506407 | Downey | Mar 1985 | A |
4759099 | Morano | Jul 1988 | A |
5448798 | Coleman | Sep 1995 | A |
5636476 | Eikmeier | Jun 1997 | A |
6138412 | Rieckmann | Oct 2000 | A |
6253417 | Rusiana | Jul 2001 | B1 |
9238399 | Okuma et al. | Jan 2016 | B2 |
20010007163 | Alonso | Jul 2001 | A1 |
20100223754 | Tomioka et al. | Sep 2010 | A1 |
20150211278 | Moyer | Jul 2015 | A1 |
20160362924 | Fan | Dec 2016 | A1 |
20170081892 | Fan | Mar 2017 | A1 |
20180002965 | Sauter et al. | Jan 2018 | A1 |
20190093407 | Lygin | Mar 2019 | A1 |
20200340280 | Oakley | Oct 2020 | A1 |
20210071458 | Eickhoff | Mar 2021 | A1 |
Number | Date | Country |
---|---|---|
2236717 | Oct 2010 | EP |
2236717 | May 2016 | EP |
Number | Date | Country | |
---|---|---|---|
20210214980 A1 | Jul 2021 | US |