Belt lock

Abstract

A belt buckle for a vehicle seat belt. The belt buckle includes a frame in which at least one locking element adapted to lock a plug-in tongue insertable into the belt buckle and an ejection element adapted to eject the plug-in tongue are provided. Each of the ejection element and the locking element is adapted to adopt a locked position and a home position. The locking element is adjacent to a web of the ejection element in the home position and thus blocked in its home position. The front end of the web has a ramp-like bearing surface against which the locking element slidingly engages.

Claims

1. A belt buckle (10) for a vehicle seat belt comprising a frame (14) in which at least one locking element (16) adapted to lock a plug-in tongue (36) insertable into the belt buckle (10) and an ejection element (18) adapted to eject the plug-in tongue (36) are provided, wherein each of the ejection element (18) and the locking element (16) is adapted to adopt a locked position and a home position, the locking element (16) being adjacent to a web (28) of the ejection element (18) in the home position and thus being blocked in its home position, and wherein the front end of the web (28) has a ramp-like bearing surface (28a) against which the locking element (16) slidingly engages, the locking element being spaced from the entire ramp-like bearing surface in the home position.

2. The belt buckle (10) according to claim 1, wherein the ejection element (18) can be transferred by the plug-in tongue (36) into the locked position in which the ejection element (18) releases the locking element (16) so that the locking element (16) may arrive at the locked position and lock the plug-in tongue (36).

3. The belt buckle (10) according to claim 1, wherein the locking element (16) is biased via a spring element (30) against the ejection element (18).

4. The belt buckle (10) according to claim 1, wherein the ejection element (18) has an H-shaped cross-section.

5. The belt buckle (10) according to claim 1, wherein a damping element (32) which is adapted to interact with the locking element (16), by decelerating the movement of the locking element (16) in a damping manner, is provided.

6. The belt buckle (10) according to claim 5, wherein the damping element (32) is arranged on an inner surface of a casing (12).

7. The belt buckle (10) according to claim 5, wherein the damping element (32) is provided in an indentation (34) within a casing (12) in an indentation (34) facing the locking element (16).

8. The belt buckle (10) according to claim 5, wherein the damping element (32) is a rubber or foam element.

9. The belt buckle (10) according to claim 5, wherein the damping element (32) is formed of an injection molding material that has been injected directly into a casing (12).

10. The belt buckle (10) according to claim 1, wherein the ejection element (18) is biased via a spring element (30).

11. A belt buckle into which a plug-in tongue can be inserted, the belt buckle comprising: a locking element moveable between a home position and a locked position, the locking element permitting the plug-in tongue to be withdrawn from the belt buckle when the locking element is in the home position, the locking element locking the plug-in tongue in the belt buckle when the locking element is in the locked position; a casing that houses the locking element and the ejection element; a damping element provided on an inner surface of the casing, the damping element decelerating movement of the locking element during movement of the locking element from the home position to the locked position; and an ejection element being moveable from a first position to a second position to eject the plug-in tongue from the belt buckle, the ejection element retaining the locking element in the home position.

12. The belt buckle according to claim 11, wherein the locking element is in direct contact with the ejection element when the locking element is in the home position.

13. The belt buckle according to claim 11, wherein insertion of the plug-in tongue into the belt buckle moves the ejection element from the second position to the first position to release the locking element and allow the locking element to move from the home position to the locked position.

14. The belt buckle according to claim 11, wherein a spring element biases the locking element into contact with the ejection element.

15. The belt buckle according to claim 11, wherein the ejection element has an H-shaped cross-section.

16. The belt buckle according to claim 11, wherein the ejection element is biased by a spring element.

17. The belt buckle according to claim 11, wherein the damping element is provided in an indentation of the casing that faces the locking element.

18. The belt buckle according to claim 11, wherein the damping element is a rubber or foam element.

19. The belt buckle according to claim 11, wherein the damping element is formed of an injection molding material that is directly injected into the casing.

Description

BRIEF DESCRIPTION OF THE DRAWING

(1) Further characteristics and advantages of the invention will be evident from the following description and the drawings which are referred to and in which:

(2) FIG. 1 shows a cross-sectional view of a belt buckle according to the invention in the home position;

(3) FIG. 2 shows the ejection element,

(4) FIG. 3 shows another cross-sectional view of the belt buckle according to the invention in a first intermediate position while a plug-in tongue is inserted,

(5) FIG. 4 shows another cross-sectional view of the belt buckle according to the invention in a second intermediate position with the plug-in tongue being further inserted, and

(6) FIG. 5 shows the belt buckle of FIG. 1 with a plug-in tongue being locked therein.

DESCRIPTION

(7) In FIG. 1 a belt buckle 10 is shown in a cross-sectional view in its home position. The belt buckle 10 includes a casing 12 formed of two casing shells 12a, 12b. In the casing 12a locking mechanism is provided in a frame 14 constituting the self-supporting structure of the belt buckle 10. The locking mechanism comprises at least one locking element 16 as well as one election element 18.

(8) The ejection element 18 illustrated in detail in FIG. 2 is arranged to be movable within the frame 14 and serves for ejecting a plug-in tongue inserted in the belt buckle from the same after pressing a release button at the belt buckle. For this purpose, the ejection element 18 interacts with a spring element 20 which loads the former into its home position (to the left in FIG. 1). The spring element 20 rests on a support surface 22 of the ejection element 18 and is supported on a casing part 23.

(9) A stop surface 24 serving as stop for a plug-in tongue not shown here is formed at the ejection element 18 opposite to the support surface 22. The ejection element 18 further includes two webs 26, 28 projecting from the stop surface 24 while facing each other. When a plug-in tongue is inserted in the belt buckle, its front end is located between the two webs 26, 28.

(10) One of the two webs 28, 28 is assigned to the locking element 16 so that it retains the locking element 16 in the home position when the ejection element 18 is provided in the home position.

(11) On the front end of the webs 26, 28 ramp-like bearing surfaces 26a, 28a are formed. The webs 26, 28 in total have a pitch circle cross-section, wherein the surface assigned to the stop face 24 is planar.

(12) The spring element 20 is adjacent the ejection element 18, namely at the bottom of a receiving sleeve 29 which is integrally formed with the ejection element 18 on the side facing away from the webs 26, 28. The webs 26, 28 directly merge with the wall of the receiving sleeve 29 which receives the spring element 20.

(13) The locking element 16, too, is biased into its looked position by means of a spring, namely by means of a spring element 30 (FIGS. 3 to 5). By virtue of the bias the locking element 16 is pressed against the web 28 of the ejection element 18 assigned to the locking element 16 so that the locking element 16 is in direct contact with the ejection element 18. The locking element 16 is retained in its home position against the bias by the ejection element 18. For the purpose of contact the locking element 16 exhibits a contact face 31 that is inclined relative to its longitudinal orientation (FIG. 2).

(14) The spring element 30 may be in the form of a spiral spring, leaf spring or resilient member. In the illustrated embodiment the spring element 30 is in the form of a resilient metal strip.

(15) Furthermore, a damping element 32 arranged in an indentation 34 of the casing shell 12b is provided within the casing 12. The damping element 32 is positioned opposite to the locking element 16, wherein, in the home position of the belt buckle 10, the ejection element 18 is located between the locking element 16 and the damping element 32.

(16) The damping element 32 may be a rubber or foam element which may have been injected into the indentation 34 during manufacture of the casing shell 12b. As an alternative, it is provided that the damping element is in the form of an insertion member being glued into the casing shell.

(17) When inserting a plug-in tongue 36 (FIGS. 3 to 5) the front end 38 of the plug-in tongue provided with a recess 40 for the locking element 16 enters into contact with the ejection element 18, causing it to be displaced by the plug-in tongue 36 inside the casing 12. In this way, the belt buckle 10 in general, the locking element 16 and the ejection element 18 are transferred from their home positions into their locked positions as shown in FIG. 5.

(18) The belt buckle further includes, for releasing the plug-in tongue 36, a push-button 42 adapted to be actuated for moving the locking element 16 via a link guide 44 against the bias of the spring element 30.

(19) The transition from the home position (FIG. 1) to the locked position (FIG. 5) takes place as follows, wherein the FIGS. 3 and 4 illustrate intermediate positions representing a sectional plane different from that of FIGS. 1 and 2:

(20) The plug-in tongue 36 is inserted into the belt buckle 10 (FIG. 3). The plug-in tongue 36 enters into contact with the end 38 at the stop face 24 of the ejection element 18 and then pushes the election element 18 inside the belt buckle 10 to the right toward the casing part 23.

(21) During displacement of the ejection element 18 within the belt buckle 10 the spring element 20 arranged at the ejection element 18 is compressed. The locking element 16 first continues being adjacent to the ejection element 18, especially to the web 28, during displacement of the ejection element 18.

(22) When the election element 18 is displaced so far that the looking element 16 has arrived at the end of the web 28, the looking element 16 slides over the contact face 31 inclined relative to its longitudinal orientation along the end of the web 28 into its locked position (FIGS. 3 and 4). The sliding is further improved by the fact that the ramp-like bearing surface 28a is configured to correspond to the contact face 31 at the end of the web 28 so that smooth sliding of the locking element 16 is resulting.

(23) After the locking element 16 has slipped along the end of the web 28, it is pressed through the recess 40 which then is arranged below the locking element 16 by the spring element 30 so that the plug-in tongue 38 is locked in the belt buckle 10.

(24) This movement is ensured by virtue of the bias by the spring element 30 so that it takes place independently of the mounting position. The movement of the locking element 16 during locking is reduced by the sliding at the end of the web 28 as, compared to the state of the art, the distance covered by the locking element 18 from the home position into the locked position without deceleration and under the effect of the spring element 30 is reduced. In this way the impact energy of the locking element arriving at the locked position is reduced. Thus the related noise is reduced.

(25) At the end of the stroke into the locked position, the locking element 16 impinges on the damping element 32, thus causing the impact energy to be partly taken up and absorbed by the damping element 32. The occurring noise is further reduced in this way as the locking element 16 does not directly impinge on the casing 12.

(26) Upon actuation of the push-button 42 the locking element is moved over the link guide 44 and is disengaged from the recess 40 of the plug-in tongue 36 again. Due to the bias of the spring element 20, then the ejection element 18 is loaded into its home position (FIG. 1) again and the socking element 16 is adjacent to the ejection element 18.