IT201800003265A1 - Rotary cartridge damper including a linear damper. - Google Patents

Description

DESCRIPTION OF THE INDUSTRIAL INVENTION TITLE: "Rotary cartridge damper including a linear damper"

DESCRIPTION

The present invention refers to a cartridge rotary damper able to be interposed between two elements hinged to each other and able to apply a braking force in at least one direction of rotation of one element with respect to the other.

More precisely, the present invention relates to a cartridge rotary damper comprising

an elongated casing having a first and a second end, said casing having a thread obtained on its internal surface, a rotor rotating with respect to the casing, which protrudes axially outwards from the first end of the casing,

a slider mounted inside the casing for an alternative sliding motion, said slider being integral in rotation with the rotor and being connected with helical coupling to the internal surface of the casing, and

a linear damper mounted inside the casing, said linear damper comprising a base, a movable piston of reciprocating sliding motion with respect to the base, damped in at least one direction of the reciprocating sliding movement, and elastic means configured to urge the piston towards a position of maximum advancement with respect to the base,

in which in a direction of the reciprocating sliding movement of the piston the piston is pushed by the cursor against the action of said elastic means.

Preferred embodiments of the invention are defined in the dependent claims, which are to be understood as an integral part of the description.

Features and advantages of the cartridge rotary damper according to the invention will become clearer with the following detailed description of an embodiment of the invention, made with reference to the attached drawings, provided for illustrative and non-limiting purposes only, in which:

- Figure 1 is a perspective view of a cartridge rotary damper according to the invention;

Figure 2 is an exploded view of the rotary cartridge damper of Figure 1;

- Figures 3 and 4 are sectional views of the rotary cartridge damper, in two different operating positions;

Figure 5 is a cut-away view of the rotary cartridge damper, in an operating position different from that of Figure 1;

- Figures 6-9c represent the stages of assembling a door on a glove box of a dashboard, with the cartridge rotary damper of Figure 1;

Figure 10 is a perspective view of the cartridge damper of Figure 1; And

- Figures 11a and 11b are perspective views of a damper control rod, according to a modified embodiment.

With reference to Figures 1-5, a rotary cartridge damper according to the invention is indicated as a whole with 1. The damper 1 comprises an elongated tubular casing 10 (shown in transparency in Figure 1), comprising a first end 11 and a second end closed 12. In the illustrated example, the second end 12 of the casing 10 has a bottom portion which forms a single piece with the side wall of the casing. The first end 11 is instead closed by a lid 13 mounted on the casing 10, for example snap-mounted.

Near the first end 11, the casing 10 has an internal thread 14 obtained on one of its internal side surfaces. The internal thread 14 has at least two principles, and preferably has a square thread profile, or a profile in which the sides of the thread are substantially perpendicular to the axis of the thread.

The damper also comprises a rotor 20 mounted rotatably with respect to the casing 10, which protrudes axially outwards from the first end 11 of the casing 10 (for example through a hole made in the lid 13).

The rotor 20 comprises a driving portion 20a arranged inside the cavity of the casing 10 and a protruding portion 20b which projects outside the casing 10. The driving portion 20a of the rotor 20 has a prismatic shape designed to form a prismatic coupling with a slider, as will be explained below. The rotor 20 also comprises a flange portion 20c interposed between the driving portion 20a and the protruding portion 20b, and provided to axially anchor the rotor 20 to the casing 10.

In the example shown, the first end 11 of the casing 10 exerts an axial retaining action on the rotor 20, thanks to the lid 13. Other methods of closing the first end 11 of the casing 10 are however possible.

The rotary damper contains an internal slider 30 driven into rotation by the rotor 20, and whose rotary motion is transformed into roto-translational motion by means of a screw coupling (helical coupling) between slider and casing. This rotary damper has compact dimensions and, with an adequate choice of materials, has a high strength and is able to provide a high resistant torque.

The slider 30 has an internal cavity 31 which has a section with a shape corresponding to that of the driving portion 20a of the rotor 20. This driving portion 20a is inserted inside the cavity 31 of the slider 30, thus realizing a prismatic coupling between the rotor 20 and slider 30. The slider 30 is therefore integral in rotation with the rotor 20, but sliding along the dragging portion 20a of the latter. According to alternative embodiments of the invention (not shown), the prismatic coupling between rotor and slider can be obtained with an inverted male / female relationship with respect to the illustrated example, and therefore with a protruding part of the slider inserted in a corresponding cavity of the rotor.

The slider 30 comprises a side surface which has an external thread 32 adapted to engage the internal thread 14 of the casing 10, and whose configuration is therefore complementary with respect to this internal thread 14.

By means of the internal thread 14 of the casing and the external thread 32 of the slider, a helical coupling is then created between the slider 30 and the casing 10, which allows to transform the rotary motion of the rotor 20 into the roto-translational motion of the slider 30.

Adjacent to the slider 30 is a connecting element 40, the function of which will be described below. The connecting element 40 includes an appendix 41, which protrudes laterally towards the outside through an opening 15 obtained through the side wall of the casing 10.

A linear damper 50 of a per se known type is finally arranged in correspondence with the bottom wall of the casing 10. The linear damper 50 comprises a base 51 and a piston 53 movable with reciprocating sliding motion with respect to the base 51, damped in at least one direction of the reciprocating sliding movement. In particular, the linear damper 50 can be of the type containing a viscous fluid inside a cavity obtained in the base 51, which fluid, by means of conventional valve means also arranged inside the base 51, influences the dynamic behavior of the piston 53 by damping its reciprocating sliding movement with respect to the base 51, in at least one direction.

The linear damper 50 also comprises elastic means, for example a helical spring 55, configured to urge the piston 53 towards a position of maximum advancement with respect to the base 51 (shown in Figures 4 and 5).

The linear damper 50, the connecting element 40, the slider 30 and the rotor 20 are held between the bottom of the casing 10 and the lid 13.

In the direction of the sliding movement of the piston 53 which goes from the first end 11 towards the second end 12 of the casing 10, the piston 53 is pushed towards its position of maximum retraction by the slider 30 (Figures 1 and 3) which advances against the action of the spring 55. In the direction of the sliding movement of the piston 53 which goes from the second end 12 towards the first end 11 of the casing 10, the piston 53 is brought towards its position of maximum elongation by the spring 55, due to the fact cursor 30 retracts. At least in this latter direction of movement, the linear damper is expected to act by braking the movement of piston 53.

The casing 10 further comprises an extension 16 extending from the second end 12 of the casing 10. An electric switch 60 is fixed, for example snap-fastened, on the extension 16 of the casing 10. The electric switch 60 comprises a movable member 61 , for example a button, which serves to close and alternatively open an electric circuit incorporated in or connected to the switch 60 (not shown). This electric circuit can be, for example, a power supply circuit for a lighting source.

A control rod 70 is mounted on the extension 16 of the casing 10 for an alternative sliding motion. In the illustrated example, the control rod 70 is inserted in a guide formed partly on the lateral surface of the casing 10 and partly on the extension 16. The control rod 70 comprises a first end 71 and a second end 72. At least in correspondence with the second end 72, the control rod 70 is configured for a prismatic coupling with the bottom of the guide obtained on the extension 16 of the casing.

The first end 71 of the control rod 70 is configured to receive motion from the slider 30, in particular through the connecting element which is held between the slider 30 and the piston 53 of the linear damper 50. To this end, the first end 71 of the control rod 70 is fixed, for example snap fastened to the appendix 41 of the connecting element 40.

The second end 72 of the control rod 70 is configured to control the movable member 61 of the electrical switch 60.

The switch 60 and the control rod 70 are in particular arranged on opposite sides of the extension 16 of the casing 10. The movable member 61 of the electric switch 60 projects on the side of the extension 16 of the casing 10 facing the control rod 60 through a window 17 made on the extension 16 of the casing 10.

A window 73 is also obtained on the control rod 70. As can be seen in Figures 3 and 4, the window 73 of the control rod 70 has an edge 74 facing the movable member 61 which is shaped like a ramp.

By virtue of the configuration described above, the movable member 61 of the switch 60 is able to assume a first operating position (Figure 3) when the window 73 of the control rod is positioned above the movable member 61, and a second operating position (Figure 4) when the window 73 of the control rod is moved away from the movable member 61. With reference to the stroke between the position of maximum retraction and the position of maximum advancement of the piston, the point at which the moving member 61 switches over depends on the position of the edge 74 of the window 73 along the control rod 70.

Figures 1 and 3 illustrate the rotary damper according to the invention in the position of maximum retraction of the piston, while Figures 4 and 5 illustrate the damper in the position of maximum advancement of the piston.

In the position of figures 1 and 3 the window 73 of the control rod 70 is arranged superimposed on the movable member 61 of the electrical switch 60, which is therefore in the first operating position. This operating position can be, for example, a position in which a lighting source connected to the switch 60 is off.

If a relative rotation is produced between the rotor and the damper casing, this is transformed into a roto-translational movement of the slider 30.

As a result of the retraction of the slider 30, the connecting element 40 and the piston 53 are moved towards the first end 11 of the casing 10, thanks to the thrust of the spring 55. The overall movement of the system is damped by the effect of the damping devices provided in the linear damper 50. The control rod 70 moves integrally with the connecting element 40 thus bringing the edge 74 of the window 73 to engage the movable member 61 of the electric switch 60. The movable member is then brought into the second operating position. This operating position can be, for example, a position in which the lighting source connected to the switch 60 is on.

The rotation movement of the rotor stops once the piston's maximum advancement point is reached (corresponding to the slider's maximum retraction point), illustrated in figure 4.

If a relative rotation is produced between the rotor and the damper casing (contrary to that previously described), this is transformed into a roto-translational advancement movement of the slider 30.

As a result of the advancement of the slider 30, the connecting element 40 and the piston 53 are moved towards the second end 12 of the casing 10, thanks to the thrust of the slider 30. The control rod 70 moves integrally with the connecting element 40 thus causing the window 73 to overlap the movable member 61 of the electric switch 60. The movable member is then brought into the first operating position.

The rotation movement of the rotor stops once the maximum retraction point of the piston is reached (corresponding to the maximum advancement point of the slider), illustrated in figure 3.

With the present invention it is possible to produce small rotary dampers, able to operate even in the presence of high external loads, and which allow to integrate all the functions (elastic thrust, damping effect) on the hinge axis between the two elements. among which it is required to obtain the damping function.

With reference to figures 6-9c, a stationary structure 80 of a dashboard of a motor vehicle is illustrated, inside which a glove compartment 81 is obtained.

A pair of supports 85 are arranged on an edge 83 of the glove compartment 81 which define an axis of rotation y for a door. On the edge 83 there is also obtained a tab 87 extending from the edge 83.

The damper 1 is approached to the edge 83, in such a way as to pass the tab 87 in a space between the second end 12 of the casing 10 and the switch 60 (Figures 7a and 7b).

The damper 1 is then moved parallel to the edge 83 of the glove compartment 81 so as to bring the anti-rotation tab 87 inside a slot 19 (shown in Figure 10) obtained on a front surface of the second end 12 of the casing 10 (figures 8a and 8b). The damper 1 is now mounted on the edge 83 of the glove compartment 81, between the two supports 85, and with the rotor 20 arranged coaxially with the rotation axis y defined by these supports. Of course, other mounting configurations are possible, for example configurations in which the male (tongue) and female (slot) parts are inverted with respect to the one described above, or configurations in which there is a coupling between a lateral surface of the casing and the edge. of the glove box.

A door 90 is then coupled to the stationary structure 80, by means of a pair of pins 88 inserted in the supports 85 and in corresponding supports obtained on the door 90. One of the two pins 88 is shaped to create a prismatic coupling with the door 90 and with the rotor 20 of the damper 1. In this way the hinging of the door 90 to the stationary structure 80 is obtained, with the rotor 20 made integral with the door 90 and the casing 10 made integral with the stationary structure 80. It is however possible to conceive an embodiment alternative (not shown), in which the rotor is made integral with the stationary structure, and the casing is made integral with the door.

With reference to Figures 11a and 11b, a modified embodiment provides for the possibility of adjusting the point at which the moving member 61 of the switch 60 switches. This adjustment is possible by modifying the position of the window 73 and of the edge 74 with respect to the first end 71 of the control rod 70. In the illustrated example, this is achieved by providing that the control rod 70 comprises a first rod section 70a and a second rod section 70b separated and coupled between them by means of coupling means 70c (for example a toothing) which define a plurality of mutual longitudinal positioning arrangements of the two sections 70a and 70b. Of course, other configurations of the control rod 70 are conceivable which similarly allow the adjustment of the position of the window 73.

Claims (8)

CLAIMS 1. Rotary cartridge damper (1) comprising an elongated casing (10) having a first and a second end (11, 12), said casing having a thread (14) formed on one of its internal surfaces, a rotor (20) rotating with respect to the casing (10), which protrudes axially outwards from the first end (11) of the casing (10), a slider (30) mounted inside the casing (10) for an alternative sliding motion, said slider being integral in rotation with the rotor (20) and being connected with helical coupling to the internal surface of the casing (10), And a linear damper (50) mounted inside the casing (10), said linear damper comprising a base (51), a piston (53) movable with reciprocating sliding motion with respect to the base (51), damped in at least one direction of the reciprocating sliding movement, and elastic means (55) configured to urge the piston (53) towards a position of maximum advance with respect to the base (51), in which in a direction of the reciprocating sliding movement of the piston (53) the piston (53) is pushed by the cursor (30) against the action of said elastic means. Damper according to claim 1, wherein the housing (10) further comprises an extension (16) extending from the second end (12) of the housing (10), wherein an electrical switch (60) is fixed on the extension ( 16) of the casing (10), in which a control rod (70) is mounted on the extension (16) of the casing (10) for an alternative sliding motion, said control rod comprising a first end (71) configured to receive motion from said slider, and a second end (72) configured to control a movable member (61) of the electrical switch (60). Damper according to claim 2, in which the electric switch (60) and the control rod (70) are arranged on opposite sides of the extension (16) of the housing (10), and in which the movable member (61) of the electric switch (60) protrudes on the side of the extension (16) of the casing (10) facing the control rod (70) through a window (17) made on the extension (16) of the casing ( 10). 4. Damper according to claim 3, in which a window (73) is formed on the control rod (70), and in which the movable member (61) of the switch (60) is able to assume a first position operative when the window (73) of the control rod (70) is superimposed on the movable member (61), and a second operative position when the window (73) of the control rod (70) is moved away from the member mobile (61). Damper according to one of claims 2 to 4, wherein a connecting element (40) is held between the slider (30) and the piston (53) of the linear damper (50), said connecting element having a appendix (41) protruding through an opening (15) obtained through a side wall of the casing (10), to which the control rod (70) is fixed. Damper according to claim 4, wherein the control rod (70) is configured such that the longitudinal position of the window (73) relative to one end (71) of the control rod (70) is adjustable . 7. Dashboard of a motor vehicle, comprising a stationary structure (80) inside which a glove compartment (81) is defined, a door (90) hinged to the stationary structure (80) at an edge (83) of the compartment object holder (81) and rotatable about an axis of rotation (y), and further comprising a rotary cartridge damper (1) according to one of the preceding claims, in which the rotor (20) of the rotary cartridge damper (1) is arranged coaxially with the axis of rotation (y) of the door (90) and fixed to one of said stationary structure and door, and the casing (10) of the rotary cartridge damper (1) is fixed to the other of said stationary structure and counter. Dashboard according to claim 7, wherein the stationary structure (80) comprises an anti-rotation tab (87) protruding from the edge (83) of the glove box (81), and wherein the housing (10) of the rotary damper The cartridge has a slot (19) formed on a front surface of the second end (12) of the casing (10) and receiving the anti-rotation tab (87).