Abstract
A seat actuating element for a motor vehicle seat has an element head (9) and a guide rod (10) that is received movably in a seat wall (7) of the motor vehicle seat (1). The element head (9) is arranged on the seat wall (7) and can be actuated. The seat actuating element (6) has an adjustment protector (11) to avoid inadvertent actuation of the seat actuating element (6).
Claims
1. A seat actuating element for adjusting a position of a motor vehicle seat, the seat actuating element mounted on a seat wall of the motor vehicle seat and comprising: a guide rod received movably in an opening in the seat wall, the guide rod having an axis arranged substantially normal to the seat wall, the guide rod being movable in at least one direction normal to the axis of the guide rod to adjust the position of the motor vehicle seat; an element head mounted on the guide rod, the element head having a facing surface spaced from and facing the seat wall, and a pressing surface opposite the facing surface, at least one indentation provided in the facing surface of the seat actuating element and extending towards the pressing surface, the at least one indentation having a cross-section that narrows from the facing surface towards the pressing surface; and at least one protrusion projecting from the seat wall at a position facing the at least one indentation and configured to be inserted into the at least one indentation, wherein the at least one protrusion is received in the at least one indentation to prevent movement of the guide rod normal to the axis of the guide rod to form a non-positive connection to prevent inadvertent actuation of the seat actuating element.
2. The seat actuating element of claim 1, wherein the guide rod (10) has a blocking element (17) of the adjustment protector (11), the blocking element (17) being of complementary configuration with respect to a receiving opening (20) of the seat wall (7), the receiving opening (20) receiving the guide rod (10) movably.
3. The seat actuating element of claim 2, wherein the blocking element (17) tapers toward an end (19) of the guide rod (10) that faces away from the element head (9).
4. The seat actuating element of claim 1, wherein the guide rod (10) is of telescopic configuration.
5. The seat actuating element of claim 1, wherein the adjustment protection means (17) has a first blocking element part (22) on a first blocking element face (25) and a second blocking element part (23) and a second blocking element face (25) that is opposed to the first blocking element face (25), the first and second blocking element parts (22, 23) being configured in a complementary and positively locking manner, and the first blocking element part (22) or the second blocking element part (23) being fixed on the guide rod (10).
6. The seat actuating element of claim 1, wherein a face (14) of the element head (9) that faces the seat wall (7) has a friction lining (29).
7. The seat actuating element of claim 1, wherein the adjustment protector (11) has a blocking element (17) that spans the element head (9) in its axial extent while maintaining a further spacing (B).
8. The seat actuating element of claim 1, wherein the motor vehicle seat is electrically adjustable.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
(1) FIG. 1 shows a basic view of a motor vehicle seat and a vehicle door.
(2) FIG. 2 shows a basic view of the motor vehicle seat with a view of the seat actuating elements thereof and an enlarged illustration of the seat actuating elements.
(3) FIG. 3 shows a basic view of a seat actuating element according to the invention in a first exemplary embodiment.
(4) FIG. 4 shows a basic view of the seat actuating element according to the invention in a second exemplary embodiment.
(5) FIG. 5 shows a basic view of the seat actuating element according to the invention in a third exemplary embodiment.
(6) FIG. 6 shows a basic view of the seat actuating element according to the invention in a fourth exemplary embodiment.
(7) FIG. 7 shows a basic view of the seat actuating element according to the invention in a fifth exemplary embodiment.
(8) FIG. 8 shows a basic view of a detail of an inner face of the vehicle door with seat actuating elements in a sixth exemplary embodiment.
DETAILED DESCRIPTION
(9) FIG. 1 shows a basic view of a motor vehicle seat 1 of a motor vehicle 2 and a vehicle door 3 of the motor vehicle 2. An object (not shown in greater detail) may be received on an inner face 5 of the vehicle door 3 in an inner tray. Such an object that is wider than the distance between the seat actuating element 6 and the inner tray may contact the seat actuating element 6 when closing of the vehicle door 3, and may exert a force from the direction of the arrow 4 on the seat actuating element 6 of the motor vehicle seat 1. This contact and force could trigger the seat actuating elements 6.
(10) The seat actuating elements 6 are arranged on a seat wall 7 of the motor vehicle seat 1 that faces the vehicle door 3. FIG. 2 shows the motor vehicle seat 1 with a view of its seat actuating elements 6 and an enlarged illustration of the seat actuating elements 6 in an outline arrangement on the seat wall 7. The seat actuating elements 6 generally can be rotated about a rotational point, and can always be moved along a wall surface 21 of the seat wall 7, as shown with the aid of the movement arrows 8.
(11) FIG. 3 shows a first embodiment of the seat actuating element 6 of the invention. The seat actuating element 6 comprises an element head 9 and a guide rod 10. The element head 9 is connected fixedly to the guide rod 10 at a first end 18 of the guide rod 10. The guide rod 10 is received movably in a receiving opening 20 in the seat wall 7. The element head 9 can be actuated in the direction of the movement arrow 8, and the guide rod 10 likewise is moved. As a result, a corresponding electric motor (not shown in greater detail) of the motor vehicle seat 1 is operated.
(12) The seat actuating element 6 has an adjustment protection means 11 to prevent inadvertent actuation of the seat actuating element 6. The adjustment protection means 11 prevents a movement of the seat actuating element 6 if the seat actuating element 6 is loaded by a force 13 axially along a longitudinal axis 12 of the guide rod 10. The adjustment protection means 11 is configured to produce a positively locking connection and/or a non-positive connection between the seat wall 7 and the seat actuating element 6.
(13) The seat actuating element 6 has an indentation 15 on a lower face 14 of the element head 9 that faces the seat wall 7, and a bulge 16 is formed on the seat wall 7 to oppose the indentation 15. The bulge 16 and the indentation 15 have complementary shapes to bring about a positive locking connection. A force 13 that acts along the longitudinal axis 12 of the seat actuating element 6 presses the seat actuating element 6 toward the seat wall 7. Thus, the indentation 15 and the bulge 16 form a positively locking connection so that an adjusting movement along the wall surface 21 is not possible.
(14) FIG. 4 illustrates a second embodiment where the guide rod 10 has a blocking element 17 of the adjustment protection means 11. The blocking element 17 spans the guide rod 10 in the region of the seat wall 7. The blocking element 17 is configured to form a positive locking and non-positive connection with the seat wall 7. To produce the positively locking connection, the blocking element 17 has a greater cross section Q in its region that faces the element head 9 than in its region that faces away from the element head 9. In other words, the blocking element 17 is conical, and a tip of the cone faces away from the element head 9 and toward a second end 19 of the guide rod 10. The receiving opening 20 is configured to be complementary to the blocking element 17. As a result, the blocking element 17 forms a positively locking connection and a non-positive connection due to friction with the receiving opening 20 in the case of a force that acts on the seat actuating element 6 along the longitudinal axis 12. As a result, movement of the seat actuating element 6 along the wall surface 21 is prevented.
(15) FIG. 5 shows a third embodiment of the seat actuating element 6 where the guide rod 10 partially has the blocking element 17 of the adjustment protection means 11. The blocking element 17 includes a first blocking element part 22 that is fixed on the seat wall 7 and a second blocking element part 23 that is fastened to the guide rod 10. The two blocking element parts 22, 23 are spaced from one another by a spacing A. The second blocking element part 23 spans the guide rod 10 completely over its circumference. However, the second blocking element part 23 might also be configured to span the guide rod 10 only partially over its circumference.
(16) The first blocking element part 22 has a first blocking face 24 that is configured to oppose the second blocking element part 23. The second blocking element part 23 has a second blocking face 25 that opposes and is complementary to the first blocking face 24. In this third embodiment, the blocking faces 24, 25 are of tooth-like shape and block movement of the seat actuating element 6 along the wall surface 21 when the individual teeth of the blocking faces 24, 25 engage one another. Teeth of the first blocking face 24 lie opposite tooth bases of the second blocking face 25. In this way, a positively locking connection and a non-positive connection are achieved here if the seat actuating element 6 is loaded with a force that acts in the direction of the longitudinal axis 12. In one exemplary embodiment that is not shown in greater detail, the two blocking faces 24, 25 are of undulating configuration and are positioned so that a positively locking and non-positive connection also are made possible.
(17) FIG. 6 shows a fourth embodiment. The guide rod 10 is of telescopic design and has a first rod section 26 that is configured to face the element head 9. The first rod section 26 has a first diameter D1 that is greater than a second diameter D2 of a second rod section 27 that is received partially in the first rod section 26. A third diameter D3 of a third rod section 28 is smaller than the second diameter D2, the third rod section 28 is received partially in the second rod section 27. With the aid of the guide rod 10 of telescopic configuration or with the aid of the diameters D1, D2, D3 which are configured in the manner of a cascade, a locking action of the seat actuating element 6 is achieved if the seat actuating element 6 is loaded with a force that acts in the direction of the longitudinal axis 12. The rod sections 26, 27, 28 are coaxial, the adjustment protection means 11 is configured to produce a positively locking connection in the direction of the longitudinal axis 12 due to the decreasing diameter of the individual rod sections 26, 27, 28.
(18) FIG. 7 shows a fifth embodiment of the seat actuating element 6 according to the invention. The element head 9 has a lower face 14 with friction lining 29 that has a high coefficient of friction. In other words, the friction lining 29 is rough at least on the surface 30 that can be positioned to face the wall surface 21, or a surface roughness of the surface 30 can bring about a non-positive connection between the wall surface 21 and the surface 30 if the seat actuating element 6 is loaded with a force in the direction of the longitudinal axis 12. The surface 30 may have an uneven or serrated profile relative to the wall surface 21 to further increase the non-positive connection. The friction lining 29 may be made from an elastomer, such as ethylene-propylene-diene rubber.
(19) FIG. 8 shows a sixth embodiment of the seat actuating element 6. The adjustment protection means 11 is a guard hoop 17 that spans the element head 9 in its axial extent while maintaining a further spacing B. As a result, the guard hoop 17 is loaded with a force, and the seat actuating element 6 is protected against erroneous actuation by the spacing B between the guard hoop 17 and the element head 9.
