The invention relates to a pivot door hinge.
Pivot door hinges in the art are connected to doors to provide hinge action relative to the ground threshold and an upper door frame head. Pivot door hinges can be provided with a closing mechanism and a braking mechanism. The braking mechanism is usually mechanically coupled to the closing mechanism to damp a closing motion of the door. A door having a pivot door hinge may have at least one preferential position, i.e. a closed position and/or an open position. When released from an open position, or a half open position, the closing mechanism will close the door by exerting a torque to the door to achieve its closed position. This greatly enhances user comfort in using the door for example by preventing undesired draft. Braking entails that whilst the door is in motion, this motion is damped in order to limit closing angular speed and prevent undesired oscillations in the door movements. This greatly improves safety in using the door.
Closing mechanisms are known to involve spring elements such as helical springs and/or pneumatic springs which act for example with a cam follower upon a cam on the pivot axle. Braking can be achieved by hydraulic means such as plungers or pistons connected to the closing mechanism which displace hydraulic fluid in a hydraulic fluid circuit driven by the cam follower. A hydraulic resistance in the hydraulic fluid circuit causes a pivotal braking action proportional to the angular speed for controlling the closing of the door.
A one-way valve disposed within the hydraulic fluid circuit parallel to the hydraulic resistance will be in an open state during an opening movement of the door, which causes the hydraulic fluid to flow through the one-way valve with low resistance. This allows the door to move freely to the open position. At closing the door, the one-way valve closes, and the hydraulic fluid is forced through the hydraulic resistance, thus providing braking action for controlling the closing action.
The combination of closing and braking mechanism as described may not provide sufficient braking torque for heavier doors. Especially in a mid-angle range near the open position and near the closed position the braking torque may be too low to prevent the door from uncontrolled opening and closing. Moreover, braking torque may be required when the door is being opened. The integrated closing and braking mechanisms in the art, providing braking torque while closing alone, i.e. during opening, may not provide the desired safe braking torque and allow a door to slam against end-stops at the end of their swing.
Also while closing the door, additional braking torque may be required when the door reaches its closed position, for preventing the so-called saloon door effect, wherein a door swings undamped back and forth through its closed position in case the door is hinged freely in a doorframe without stops. The combination of closing action and braking torque while opening and closing a door is difficult to achieve in pivot door hinges in the art.
Some pivot door hinges with combined spring based closing and braking mechanisms have their closing and braking mechanisms laterally interconnected and arranged within the hinge housing at opposite sides of the pivot axle, to keep dimensions in a direction parallel to the pivot axle at a minimum. This however causes the pivot door hinge to extend considerably in transverse direction such that the pivot axle is situated away from the door frame closest to the pivot axle, which allows the door portion between the door frame and pivot axis to open and close. Thereby a risk of objects or limbs accidentally being trapped between the door edge and door frame arises when the door is closed. Moreover, the pivot door hinge must be mountable within a cavity of the door. Thus, also thickness or dimensions in a direction perpendicular to the dear leaf surface must be kept minimal.
It is an object of the invention to provide a pivot door hinge having a braking mechanism to allow safe opening and closing of a door with braking torque. The pivot door hinge must be mountable within a cavity of the door, so the pivot door hinge must have minimal dimensions vertically, laterally and in thickness and have minimal distance to a door edge at the hinge side of the door for safety.
The object is achieved in a pivot door hinge, comprising a hinge housing for mounting the pivot door hinge to a door, a pivot axle pivotally supported within the housing, the pivot axle having an end arranged for rotationally anchoring the pivot axle to a structure holding the door, a closing mechanism arranged within the hinge housing, the closing mechanism being cooperatively connected to the pivot axle. The closing mechanism is arranged for providing a closing torque to the pivot axle, according to an angular position-torque profile. The pivot door hinge further comprises a braking mechanism arranged within the hinge housing, cooperatively connected to the pivot axle the braking mechanism being arranged for providing a braking torque for controlling at least one of the closing movement and an opening movement of the door.
The closing mechanism comprises a closing cam connected to the pivot axle arranged in a first buffer chamber of the hinge housing, wherein the closing cam has a closing cam profile corresponding to the angular position-torque profile. The closing mechanism further comprises a closing cam follower element, the closing cam follower element being arranged to contact the closing cam for exerting the closing torque on the pivot axle via the closing cam. The closing mechanism further comprises a first displacement device connected to the closing cam follower element wherein the first displacement device is arranged within a first pressure chamber of the hinge housing, a first spring element arranged within the first pressure chamber of the hinge housing, for exerting a first spring force to the first displacement device. The closing mechanism further comprises a first hydraulic circuit, operatively arranged between the first buffer chamber and the first pressure chamber, wherein the first displacement device is arranged to move a hydraulic fluid between the first pressure chamber and the first buffer chamber.
The braking mechanism comprises a braking cam connected to the pivot axle arranged in a second buffer chamber of the hinge housing, wherein the braking cam has a braking cam profile corresponding, wherein the braking cam profile is different from the closing cam profile, and a braking cam follower element arranged to contact the braking cam for exerting the braking torque on the pivot axle via the braking cam. The braking mechanism further comprises a second displacement device connected to the braking cam follower element wherein the second displacement device is arranged within a second pressure chamber of the hinge housing, a second spring element arranged within the second pressure chamber of the hinge housing, for exerting a second spring force to the second displacement device. The braking mechanism further comprises a second hydraulic circuit, operatively arranged between the second buffer chamber and the second pressure chamber, wherein the second displacement device is arranged to move a hydraulic fluid between the second pressure chamber and the second buffer chamber via at least one of a hydraulic resistance and a one way valve.
The braking cam has a braking profile comprising a first protrusion at an angle corresponding to an open-door position, and wherein the one-way valve is arranged to be open, to allow a hydraulic fluid to flow through the one-way-valve from the second buffer chamber to the second pressure chamber when in use the second displacement device moves towards the pivot axle.
So, when the door in use is closed from the open-door position, the braking cam is rotated and the first protrusion allows the second displacement device to approach the pivot axle. The hydraulic fluid is allowed to flow from the second buffer chamber to the second pressure chamber through the opened one-way-valve with relatively low resistance. The door is now allowed to close with no braking action from the braking mechanism.
The one-way valve is further arranged to block the hydraulic fluid, when in use the second displacement device moves away from the pivot axle to allow the hydraulic fluid to flow from the pressure chamber to the second buffer chamber via hydraulic resistance.
When in use the door is being moved to the open-door position, the first protrusion now pushes second displacement device away from the pivot axle. The hydraulic fluid is pressurized by the second displacement device which causes the one-way-valve to close and the hydraulic fluid is forced by the second displacement device to flow from the second pressure chamber to the second buffer chamber via the hydraulic resistance.
This allows the braking mechanism to provide braking torque in an opening movement of the door, i.e. door hinge, independent from the braking provided by the closing mechanism, thereby preventing the door from being uncontrollably slammed open. This significantly enhances door hinging applications, especially for large and heavy doors which closing and opening movement can now be controlled accurately.
In an embodiment, the braking cam has a braking profile comprising a second protrusion at an angular position corresponding to a closed-door position and an indentation at an angular position in between the first protrusion and the second protrusion.
This allows the braking mechanism to provide additional braking action in closing movement of the door near the closed-door position, i.e. door hinge, independent from the braking provided by the closing mechanism. This prevents the door from being slammed shut.
In an embodiment, the closing mechanism is further arranged for providing a first braking action for controlling a closing movement of the door.
In an embodiment the braking mechanism and the closing mechanism are arranged in the hinge housing on a same lateral side of the pivot axle.
This allows the pivot axle to be arranged close to the door edge near the door post, thus preventing a large opening between door leaf and doorpost near the rotation axis of the door hinge. This enhances safe operation of the door. The braking and closing mechanism can be arranged mutually above one another in axial direction of the pivot axle, thereby allowing a very compact design of the pivot door hinge.
This allows the first spring element, which may be a single heavy-duty spring or a coaxially aligned double spring for extra heavy doors, to provide the required closing torque. The closing cam is designed to provide the required torque for each angular position.
In an embodiment, the first hydraulic circuit comprises a first fluid channel between the first pressure chamber and the first buffer chamber, and a first one-way valve arranged within the first fluid channel. The first hydraulic circuit further comprises a second fluid channel between the first pressure chamber and the first buffer chamber, arranged in parallel to the first fluid channel, and a first fluid resistance arranged within the second fluid channel.
The first displacement device moving the hydraulic fluid with the first one-way valve open in one direction allows braking action in a one way and free movement in the opposite direction.
In an embodiment, the first fluid channel and the first one-way valve are arranged through the first displacement device. This saves space within the housing, as this first fluid channel need not be manufactured within the housing.
In an embodiment, the closing cam has a radius which substantially increases with increasing angular positions. The first one-way valve is arranged to allow a hydraulic fluid to flow from the first pressure chamber to the first buffer chamber when in use the first displacement device moves away from the pivot axle and wherein the first one-way valve is arranged to block the hydraulic fluid flow when in use the first displacement device moves towards the pivot axle.
The radius of the closing cam substantially increasing with increasing angular position causes the closing cam follower element and consequently the first displacement device to take up a position relative to the pivot axle to have a substantially increasing distance with increasing angular position. Thus, when the door opens, the angular position increases and the hydraulic fluid passes through the first one-way valve. When the angular position however decreases, the distance between the first displacement device and the pivot axle decreases substantially, causing the first one-way valve to close. The hydraulic fluid then passes through the first hydraulic resistance.
In an embodiment, the second hydraulic circuit comprises a third fluid channel between the second pressure chamber and the second buffer chamber, a second one-way valve arranged within the second fluid channel, a fourth fluid channel arranged in parallel to the third fluid channel, and a second fluid resistance arranged within the fourth fluid channel.
This allows the second displacement device moving the hydraulic fluid with the second one-way valve open in one direction braking action in one direction and free movement in the opposite direction.
In an embodiment, the third fluid channel and the second one-way valve are arranged through the second displacement device.
This allows flexible design of braking profiles for the pivot door hinge independent of the cam profile of the closing mechanism. Moreover, an angular shift from the first protrusion to another angular position allows free movement, whereas an angular shift from an angular position towards the protrusion allows for braking action due to the movement of the second displacement device away from the braking cam and pivot axle.
In an embodiment, the braking cam has a braking profile comprising the first protrusion at an angle corresponding to a closed-door position and a second protrusion at an angle in a range corresponding to an open-door position, and an indentation at an angular position in between the first protrusion and the second protrusion.
This allows braking in both opening and closing directions starting from the angular position of the indentation between the protrusions.
In an embodiment, the second hydraulic circuit further comprises a fifth fluid channel parallel to the third fluid channel and the fourth fluid channel, the fifth fluid channel comprising a relief valve.
This relief valve prevents overpressure to occur in the second pressure chamber when for a sudden uncontrolled movement involving braking, i.e. with the second one-way valve closed, is to be performed. This prevents all parts in the pivot door hinge to be damaged in such a situation which enhances safety and reliability of the door hinge.
In an embodiment, at least one of the first and the second fluid resistance is adjustable.
This allows independent adjustment of the braking torque.
In an embodiment, the braking cam has a symmetrical profile.
This allows the braking action to be symmetrical, i.e. the door will behave the same when opening or closing in both directions within the door frame.
In an embodiment, the closed-door position corresponds to a cam angle in a range of −20 to +20 degrees relative to a center line of the braking mechanism.
In an embodiment, the open-door position corresponds to an opening angle in a range of plus or minus 70-110 degrees relative to a center line of the braking mechanism.
In an embodiment, the second spring element has a spring constant in a ratio of at least 1 to 10, and preferably 1 to 15, relative to a spring constant of the first spring element. This allows relatively small springs for the braking mechanism to be used resulting in a compact design of the pivot door hinge.
Exemplary embodiments of the invention will be elucidated according the following drawings.
Exemplary embodiments of the invention will be further elucidated according the following detailed description. Throughout the application, where the wording angle or angular position is used, an absolute angle is intended, except where indicated otherwise.
The top 107 can be a lintel for example. The door leaf 101 can swing around the rotation axles 106a,106b is a single direction or preferably in both directions to and in
From
In
Furthermore, braking is to be provided in the zone indicated with D1 while opening the door. In zone D2 braking is provided additional to zone A1 while closing the door.
In
Slight changes in the cam angular position relative to the cam wheel 405 will result in a steep increase in the exerted torque Ta of the pivot axle 106a. This corresponds to the high peek in the torque-angle diagram of
In
The angle α1 in
The braking cam 411 has another protrusion 603 arranged to push cam wheel 410 away from the pivot axle center at angles α corresponding to an open-door position.
In
In
In
When departing from this position, while closing the door the distance D will decrease and become less than d3, going to D=d2 as shown in
The braking spring 408 of the braking mechanism 407 may have a spring constant which is sufficient to keep the cam wheel 410 in touch with the braking cam 411. The closing spring 403 however must be dimensioned with a spring constant sufficiently high enough to provide closing torque when de door is in an open position.
The ratio between braking constant and closing constant can be 1 to at least 5. Preferably the ratio can be 1 to at least 15, more preferably the ratio can be 1 to at least 25.
The plunger 404 is actuated by the cam wheel 405 and closing cam 406 in accordance with
When cam wheel 405 pushes the closing cam 406 against closing spring 403 while opening the door, hydraulic fluid in the pressure chamber 412 is pushed by the plunger 404 through the one-way valve 701. This way easy opening of the door with relatively low resistance is achieved. When on the other hand cam wheel 405 is pushed away from the closing cam 406 while closing the door, the one-way valve 701 closes and hydraulic fluid in the buffer chamber 414a is pushed by the plunger 404 through the channel 716 and hydraulic resistance 705 and hydraulic fluid channel 717 to pressure chamber 412. This way braking torque is achieved for the closing motion of the door. For small opening angles α near 0°, the bypass 707 may direct the hydraulic fluid through hydraulic fluid channel 722 and hydraulic resistance 706 to hydraulic fluid channel 715, thereby creating a lower resistance and corresponding lower braking torque for these angles. This allows the door to move from an open position to a completely closed position. Braking torque is proportional to the angular door speed and proportional to the fluid resistance value of hydraulic resistance 706.
The hydraulic circuit 708 for the braking mechanism 407 comprises the pressure chamber 413 in which the braking plunger 409 and braking spring 408 are arranged. The buffer chamber 414b is the buffer chamber for the hydraulic fluid of the hydraulic circuit 708 for the braking mechanism 407. As discussed, the braking plunger 409 is actuated by the cam wheel 410 and braking cam 411. The hydraulic circuit 708 comprises one-way valve 703 which is arranged in a hydraulic fluid channel 704 through the braking plunger 409. Parallel to the hydraulic fluid channel 704 a hydraulic fluid channel 720 is arranged within the housing 401 which comprises a variable hydraulic resistance 710. Furthermore, the hydraulic circuit 708 comprises a path comprising hydraulic fluid channels 714, 718 having a pressure relief valve 721. For pressures above a threshold value, for example 30 Bar, the pressure relief valve 721 will open to prevent damage to the hydraulic circuit 708 and the mechanical components, i.e. the pressure chamber 413.
When the door is closed in angular range D2 of
In the reverse direction while opening the door in this zone D2, the one-way valve 703 is opened and the hydraulic fluid flows through one-way valve 703 with relatively low resistance or braking torque.
When the door is opened further however corresponding to angular positions in zone D1 in
In the reverse direction while closing the door in this zone D1 of
The door having the door hinge 102 is thus protected against uncontrolled swinging open through its open position at or around 90°.
The bypass 707 of the closing mechanism hydraulic circuit 713 may be formed as a slit in the closing plunger 404.
The one-way valve 703 of the braking mechanism 407 is shown arranged within the braking plunger 409, having its blocking side facing the braking cam 411 which is arranged in buffer chamber 414b, and it's through opening facing hydraulic fluid channel 704. The one-way valve 703 and hydraulic fluid channel 704 may alternatively also be arranged within the housing 401.
The embodiments as described are provided by way of example only. Modifications and deviations are possible without deviating from the scope as defined by the claims set out below.
Throughout this application, the wording fluid channel may involve one or more fluid channel segments arranged in series optionally including a fluid resistance or valve. Moreover a fluid channel or channel segment may be a duct or a hidden channel bored or cast into the hinge housing.
Furthermore, where the wording plunger is used, also the wording piston can be used. Pistons and plungers can be categorized as positive displacement devices.
It will be clear to a person skilled in the art that the scope of the present invention is not limited to the examples discussed in the foregoing but that several amendments and modifications thereof are possible without deviating from the scope of the present invention as defined by the attached claims. In particular, combinations of specific features of various aspects of the invention may be made. An aspect of the invention may be further advantageously enhanced by adding a feature that was described in relation to another aspect of the invention. While the present invention has been illustrated and described in detail in the figures and the description, such illustration and description are to be considered illustrative or exemplary only, and not restrictive.
The present invention is not limited to the disclosed embodiments. Variations to the disclosed embodiments can be understood and effected by a person skilled in the art in practicing the claimed invention, from a study of the figures, the description and the attached claims. In the claims, the word “comprising” does not exclude other steps or elements, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference numerals in the claims should not be construed as limiting the scope of the present invention.
Number | Date | Country | Kind |
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17176622 | Jun 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/066275 | 6/19/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/234313 | 12/27/2018 | WO | A |
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Chinese Office Action dated May 25, 2020 for family member Application No. 201880046777.8. |
Number | Date | Country | |
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20200408019 A1 | Dec 2020 | US |