This invention relates to hinge and damper assemblies, and more particularly, to hinge assemblies comprising toggle type hinges, of the sort that are typically used on kitchen cupboards, together with a damping device.
The invention provides a hinge assembly comprising a toggle type hinge, a linear damping device arranged with its longitudinal axis parallel to the axis of movement of the hinge, first and second actuating devices for operating the damping device, and means to activate the first and second actuating devices in response to movement of the hinge.
By way of example, embodiments of the invention will now be described with reference to the accompanying drawings, in which:
The hinge assembly seen in
The hinge mechanism 10 comprises at one end a hinge cup flange (not seen in
The hinge assembly also comprises a damper assembly 12 to interact with the hinge mechanism 10. The damper assembly 12 is mounted on the hinge cup flange, here by means of a snap-fit connection.
As seen in
The hinge assembly further comprises two actuating devices. The first actuating device comprises a wing 19 which extends laterally out from the cylinder 15. The wing 19 is designed to protrude through an opening 22 in the housing 18 so as to be engagable with the hinge mechanism 10. Specifically, the wing 19 is designed to engage a striker plate 20 which extends laterally from the arm assembly 11, as seen in
The first actuating device also includes an external rib 21 that is arranged to extend part way around the circumference of the cylinder 15 in a helical path. The housing 18 is provided with a corresponding rib 23 on its inner surface (see
In this embodiment, the first actuating device is provided as an integral part of the damper construction. However, it could instead be provided as a separate element and be designed to receive a standard damper.
The second actuating device is in the form of a generally cylindrical body 31 from which a wing 30 extends laterally out. Like the first actuating device, the body 31 is mountable in the radiused groove 17 in the guide plate 16 for rotation about its longitudinal axis (arrow A) and for axial movement (arrow B). The wing 30 is arranged to protrude through the opening 22 in the housing 18 in order to engage the hinge mechanism 10. Specifically, the wing 30 is designed to engage a second striker plate 32 which extends laterally from the arm assembly 11. As seen in
The wing 30 makes sliding contact with its striker plate 32 and its contact surface is contoured so as to act as a camming mechanism. In particular, the interengagement between the wing 20 and its striker plate 32 is such that in the closing movement of the door 50, the actuator body 31 will be caused to rotate by the camming action between striker plate and the wing.
The second actuating device also includes an external rib 33 that extends part way around the outer circumference of the actuator body 31 in a helical path. The housing 18 is provided with a corresponding rib 34 on its inner surface (see
The guide plate 16 with its radiused groove 17 is arranged to be mountable on the hinge cup flange of the hinge assembly by suitable means. Alternatively, the radiused groove 17 could be provided as an integral part of the hinge cup flange itself.
The helically extending ribs 23, 34 arranged in the housing 18 could instead be provided on the guide plate 16, or even as an integral part of the hinge cup flange. Furthermore, instead of using interengaging abutting ribs as a mechanism for converting rotary motion into linear motion, it would be possible instead to use a rib and groove arrangement. The rib would be provided on one of the elements, whilst a corresponding groove to engage the rib would be provided on the other element.
The actuator body 31 is aligned with the damper 13 so that it acts as an abutment for the free end of the piston rod 14, having a seat 35 for this purpose. An adjustable end stop 36 is mounted in the housing 18 to allow for axial adjustment of the position of the actuating body 31.
The axial displacement of the actuator body 31 generated by movement of the hinge is arranged to cause compression of the damper 13. The compressing action of the second actuating device will be supplementary to the compressing action of the first actuating device described earlier. The two actuating devices thus operate together on the damping device from opposite directions. They also effectively act independently of each other, since each has its own activating mechanism.
One of the advantages of this arrangement is that the helical paths of the two actuating devices can be designed with much smaller pitches, ie lower gearing, than would be the case with just a single actuating device acting on the damper, for the same amount of travel. This is advantageous, because it means that in operation the radial component of the force transmitted by movement of the hinge onto the damper assembly will be significantly less. There will therefore be less tendency for the housing to deform or possibly burst open.
The amount of damping force generated by a linear piston and cylinder damper is essentially proportional to its rate of compression: the higher the rate of compression, the higher the damped resistance. Having two independently acting actuating devices thus enables a wide range of adjustment in terms of tailoring the damping charateristics of the hinge assembly. Firstly, it is possible to arrange for the two striker plates to come into engagement with their respective actuating devices at different stages of the closing movement of the hinge, eg for one of the devices to operate before the other. The adjustable end stop in the housing allows for adjustment of this. If one of the actuating devices initially acts alone, this would give a relatively “soft” damping response to movement of the hinge. When the other actuating device kicks in, however, the result is an increased or “harder” damping response to the hinge movement. This helps to avoid the problem of door bounce in a slam test.
The actuating devices could also be arranged to act over different ranges of movement of the hinge and/or at different rates. This sort of adjustment could be achieved by altering the pitch and/or profile of their respective helical paths.
The double acting damper actuation mechanism described above can be applied to different hinge assemblies. As an example, a second form of hinge assembly is seen in
As with the assembly described above, the two actuating devices each comprise a mechanism for converting rotary motion into linear motion so that the closing movement of the door will cause the two actuating devices to move towards each other, thus compressing the damping device and creating the damped resistance to the closure. It will be seen that the wings of the two actuating devices 51, 52 are spaced apart in the open position of the door: this is to allow for their movement towards each other in the door closing cycle. The wings make sliding contact with the arm assembly 55, initially towards its outer edges, but moving towards its midpoint as the door closes. The width of the arm assembly 55 in a standard hinge of this nature provides enough room for travel of the actuating devices 51, 52, and hence enough compression of the damping device, to provide a suitable damped resistive force to the closing of the door.
The assembly seen in
In the embodiments described above, the actuating devices incorporate mechanisms for converting rotary motion into linear motion. These include cams with a helically extending path and in the examples shown, take the form of interengaging ribs and/or interengaging ribs and grooves. Such arrangements are fine where the helical path is to be of constant pitch. However, there might be occasions where it is helpful for one or both of the movement converting mechanisms to have a variable pitch. A variable pitch would enable the rate of linear displacement of the actuating mechanism to be variable over the course of the closing movement of the door. This could be achieved, for example, by using a pin instead of a rib to engage the rib or helical groove. Since the amount of damping resistance produced by a linear damper is essentially proportional to its rate of compression, this would allow an additional degree of adjustment for tailoring the damping characteristics of a hinge assembly.
Number | Date | Country | Kind |
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1218563.3 | Oct 2012 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/071522 | 10/15/2013 | WO | 00 |