DE29518172U1 - Device for damped movement of a component pivotally mounted about an axis - Google Patents

Description

Device for the dampened movement of a component pivoted about an axis

The invention relates to a device for the damped movement of a component pivotably mounted about an axis according to the preamble of claim 1.

In automotive engineering in particular, small damping devices are used in many different ways to dampen the movement of certain moving components, such as ashtray lids, glove compartment lids or similar. They prevent the spring-loaded components from moving against a stop at too high a speed after being unlocked, which leads to unwanted noise and also to wear.

Patent Attorneys ■ European Patent Attorneys Representatives at the European Patent Office

Lawyer?&gejai&sn beijjertüämljixrger Gerjc?hlB*n*·

Deutsche Bank AG Hamburg, No. 05 284,^jBL*2i200 Tt)O (J)) JPoätbaiJk Hamijur«, >"r*28 42 206 &igr; BLZ 200 100 20) Dresdner Bank AG Amburs, No*r*^33*?iO 3ST ¹ BLZ 2D0 WOO)

It is known to use so-called rotary dampers. Rotary dampers typically consist of a rotor and a housing that supports the rotor so that it can rotate, with a gap filled with a viscous fluid being formed between the rotor and the housing. A movement of the rotor relative to the housing therefore requires overcoming the friction that occurs in the gap due to the viscous medium. The movement of the component is usually transferred to the rotary damper using a toothed segment that interacts with a pinion that is in turn mounted on the rotor shaft.

The invention is based on the object of creating a device for the damped movement of a component pivotably mounted about an axis, which can be arranged in a particularly space-saving manner and in which a drive for the component is integrated.

This object is solved by the features of claim 1.

The device according to the invention provides an elongated housing with a cylindrical cavity, which is closed at one end and open at the other end.

The housing is arranged coaxially to the axis of the component or forms the axis itself. A cylindrical rotor is arranged in the housing, which forms a circumferential annular gap with the housing wall, which is filled with a viscous medium. The rotor is, however, shorter than the cylindrical cavity. A helical spring is arranged in the remaining gap, which is fixed both at the closed end of the housing and at the rotor. A stop on the housing, which interacts with the rotor, limits the rotary movement of the rotor in a predetermined rotary position. Finally, a provision is also made to seal the open end of the housing. According to one embodiment of the invention, this can be done in that the rotor has a flange, the outside diameter of which corresponds approximately to the inside diameter of the cylindrical cavity and the flange has an annular bead or the like in its circumference, which interacts with an annular groove in the wall of the cavity. This creates a seal for the cavity on the one hand and a bearing for the rotor at one end on the other.

The spring is preferably pre-tensioned. It can be used to hold the component in place after it has been

force has taken a certain position, it is easier to move it back to the other position. This movement is supported by the spring. Conversely, after the component is released from a lock, the spring can support the first adjustment using spring force, although this movement is slowed down by the damping effect of the rotary damping element. The component is then returned to its original position against the spring force and also against the damping.

To enable effective engagement between the stationary component and the moving component, both ends of the device, namely the closed end of the housing and the outer end of the rotor, have sections with which a coupling is possible. Square sections can therefore be provided, for example.

According to a further embodiment of the invention, axial ends of the spring are arranged in corresponding recesses in the closed end or the rotor. This not only effectively fixes the spring ends to the corresponding parts, but also centers the rotor, which therefore no longer needs to be radially supported or mounted in this area.

The invention is described in more detail below with reference to a drawing.

The single figure shows a section through a device according to the invention.

The figure shows an elongated cylindrical housing 10 which is open at one end and closed at the other end. At the closed end it has a section 12 with a smaller transverse dimension which is shaped as a square. A recess 14 is formed in this section. A cylindrical cavity 16 is provided in the housing 10.

A cylindrical rotor 18 is arranged in the housing, which forms an annular gap 20 with the wall of the cavity 16. At the open end of the housing 10, the rotor 18 has a cylindrical flange 22, on the outer circumference of which an annular bead 24 is formed, which sits in a correspondingly shaped groove 26 of the cavity 16. The outer end of the rotor 18 is shaped as a square section 28. In the rotor, on the other side of the square 28 next to the flange 22, an annular groove 30 is formed to accommodate a sealing ring 32. The sealing ring can, however, be omitted.

since the flange 22 and the bead 24 provide sufficient sealing for a viscous medium which is filled into the cavity 16 and which is indicated by dots in the drawing.

The rotor 18 is spaced from the closed end of the housing 10. A coil spring 34 is arranged in the space between them with axial end sections 36, 38. The axial section 36 sits in the recess 14, which prevents it from rotating. The end section 38 sits in an axial recess 40 which is formed into the rotor 18 from the free end. The axial end 38 is curved and is fixed with the aid of a pin 42 which is inserted radially into a corresponding bore 44 in the rotor 18.

A stop 46 in the cavity serves to limit the rotation of the rotor. When inserting the rotor together with the spring, before the stop 46 is reached, the spring is pre-tensioned by appropriate rotation of the rotor 18. The rotor 18 is then completely inserted, as shown. This allows a component to be driven by the spring 34 in one direction or the other, depending on how the complete assembly is inserted.

The entire assembly may form the axis of a component or be arranged coaxially to the axis of the component. Sections 12 and 28 serve as coupling sections.

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Claims (4)

Expectations : 1. Device for the damped movement of a component pivoted about an axis, characterized by the following features - an elongated housing (10) having a cylindrical cavity (16) which is closed at one end and open at the other end - a sealing closure for the housing (10) - a cylindrical rotor (18) in the cavity (16), which forms a circumferential annular gap (20) with the housing wall - a helical spring (34) between the closed end of the housing (10) and the facing end of the rotor (18), the ends of which are fixed to the housing (10) and the rotor (18) - a stop (46) in the housing (10) which limits the rotor (18) in a predetermined rotational position - one coupling section (12, 28) each on the closed end of the housing (10) and at the outer end of the rotor (18) and - a viscous medium in the cavity (16). 2. Device according to claim 1, characterized in that the rotor (18) has a flange (22) whose outer diameter corresponds approximately to the inner diameter of the cylindrical cavity (16) and the flange (22) has an annular bead (24) on its outer circumference which cooperates with an annular groove (26) in the wall of the cavity (16). 3. Device according to claim 1 or 2, characterized in that the spring (34) has axial end sections (36, 38) which engage in corresponding recesses in the closed housing end and the rotor (18). 4. Device according to claim 3, characterized in that the bent end (38) is fixed in the rotor (18) by means of a radial pin (42).