FR2708689A1 - Device for absorbing axial energy - Google Patents

Abstract

The device for absorbing axial energy of a mechanical system includes: - a telescopic assembly consisting of a shaft (11) mounted in a tube (12) so that one can slide in the other along a first longitudinal part (12a) of the tube (12); - a deformable element (13) mounted so that it can slide in the first longitudinal part (12a) of the tube, between the end of the shaft and the second longitudinal part (12b) of the tube; - the second longitudinal part (12b) of the tube being equipped with a narrowed portion (14), the passage of which is smaller than the transverse size of the deformable element (13); - the various characteristics of the narrowed portion (14) and of the deformable element (13) being chosen and matched to one another so that in the event of an axial impact, axial energy is absorbed according to the desired law given by the matching of the transverse interference as a function of the longitudinal travel of the deformable element (13) in the narrowed portion (14).

Description

 The present invention relates to an axial energy absorption device of a mechanical system.

 Axial energy absorption systems of mechanical system are known which apply to fixed sets in rotation with respect to the longitudinal axis of the mechanical system, or to systems which comprise a transmission of rotational movements with respect to this longitudinal axis. These types of known system, generally include an energy absorption which relates to one of the principal elements of the mechanical system, so that in the event of shock, the deformation of one of these elements or more of these elements allow energy absorption. One of these types of system is the object of FIG. 1 which represents a tube in which a shaft engages by means of a ring mounted by force in this tube. This ring is provided in a material generally of the plastic material type so that in the event of an impact in an axial direction, the shaft forcibly moves in this ring, and thereby allowing energy absorption. This type of device does not make it possible to have an energy absorption curve which corresponds exactly to that requested as will be seen later.

 The object of the present invention is to avoid the drawbacks mentioned above, and to propose an axial energy device which exactly responds to the energy absorption curve requested in the event of an impact, while easily adapting on existing mechanical systems.

According to one embodiment of the invention, the axial energy absorption device of a mechanical system comprises:
- A telescopic assembly constituted by a shaft mounted in a tube so as to be able to slide one into the other along a first longitudinal part of the tube;
- a non-metallic deformable element mounted so that it can slide in the first longitudinal part of the tube, between the end of the shaft and the second longitudinal part of the tube;
- The second longitudinal part of the tube being provided with a narrowing whose passage is smaller than the transverse size of the deformable element;
- the different characteristics of the narrowing and of the deformable element being chosen and adapted with respect to each other so that in the event of an axial shock, the absorption of axial energy takes place according to the desired law given by the adaptation of the transverse interference as a function of the longitudinal displacement of the deformable element in the constriction.

In order to make the most of the structure of the invention, the different characteristics of the deformable element on which one acts to obtain the desired axial energy absorption law are:
- the material constituting the deformable element,
- the longitudinal shape and dimensional characteristics,
- the transverse shape and dimensional characteristics,
- structural features.

In order to further improve the advantages of the structure of the invention, the various characteristics of the shrinkage of the tube on which one acts to obtain the desired axial energy law are:
- the longitudinal shape and dimensional characteristics,
- the transverse shape and dimensional characteristics.

According to one embodiment of the invention:
the telescopic assembly comprises a shaft and a tube, the shaft and the recess of the tube having a cross section of conjugate profile with two diametrically opposite circular parts and connected by two flat parts so as to be integral in rotation,
the deformable element has a cross section of substantially constant profile and dimensions which is combined with the cross section of the tube recess with two diametrically opposed circular parts connected by two flat parts,
the narrowing of the second longitudinal part of the tube comprises two indentations made in the middle of each of the two flat parts so as to be diametrically opposite,
- the longitudinal shape and dimensional characteristics, as well as the transverse shape and dimensional characteristics of each of the two cavities being determined to obtain the required axial energy absorption law.

According to another embodiment of the invention:
the telescopic assembly comprises a shaft and a tube, the shaft and the recess of the tube having a circular or complementary section relative to one another, the shaft and the recess of the tube having means of joining in rotation constituted by a grooved system or any other system,
the deformable element has a circular or complementary section of the narrowing in profile and of substantially constant dimensions,
the narrowing of the second longitudinal part of the tube has a circular or complementary section of the deformable element of profile and of substantially constant dimensions,
- the longitudinal shape and dimensional characteristics, as well as the transverse dimensional characteristics of the narrowing being determined to obtain the required axial energy absorption law.

 Finally, according to another embodiment of the invention, the shaft and the deformable element constitute a single piece.

 According to different variants of the invention, the deformable element is either made of elastomer or of plastic.

 In addition, the deformable element may include a chamfer for entry into the narrowing, the shape and dimensional characteristics being determined to obtain the required axial energy absorption law.

 The axial energy absorption device of a mechanical system according to the invention thus has the advantage of being able to determine exactly the structure of the various organs so that the axial energy absorption is carried out according to law desired.

Other advantages will emerge from the invention, which will be better understood with the aid of the description given above of specific embodiments, described without limitation with reference to the appended drawings, in which:
Figure I is an axial section of a known energy absorption device.

 Figure 2 is an axial section of an energy absorption device according to the invention.

 Figure 3 shows the energy absorption curves.

 Figure 4 is an axial section of an energy absorption device according to another embodiment of the invention.

 Figure 5 is an axial section of the device shown in Figure 4 during energy absorption.

 Figure 6 is an axial section of the device shown in Figure 4 after energy absorption.

Figure 7 is a longitudinal section of a deformable element according to the embodiment of the invention of the
Figure 4.

Figure 8 is a section along VIII-VIII of the
Figure 7.

 Figure 9 is a longitudinal axial section of the tube with the narrowing corresponding to Figure 4.

 Figure 10 is a section along X-X of Figure 9.

 The axial energy absorption device, known in the state of the art and represented in FIG. 1, makes it possible to absorb the energy in a first phase with an increase in the very rapid effort as a function of a relatively small stroke, then after a slight fall in this force as a function of a slight extension of the stroke, a second phase in which the force is substantially constant as a function of the stroke. This energy absorption curve of the known system is shown in Figure 3 and is referenced A.

The axial energy absorption device of a mechanical system according to the invention, which is shown in the
Figure 2, includes a telescopic assembly and a deformable element 3.

 The telescopic assembly according to the invention consists of a shaft 1 which is mounted in a tube 2, so as to be able to slide one inside the other in the direction of the longitudinal axis. This shaft 1 slides in a first longitudinal part 2a of the tube 2.

 The deformable element 3 is slidably mounted in this first longitudinal part 2a of the tube 2, that is to say it is placed between the end of the shaft l, and the second longitudinal part 2b of the tube 1.

 The second longitudinal part 2b of the tube 1 is provided with a narrowing referenced 4, the passage of which is smaller than the transverse size of the deformable element 3.

 According to the invention the different characteristics of the constriction 4 and of the deformable element 3 are chosen and adapted with respect to each other so that, in the event of an axial shock, the absorption of axial energy takes place according to law desired. This damping law is given by the adaptation of the transverse interference as a function of the longitudinal displacement of the deformable element 3 in the constriction 4, the transverse interference being a function of the transverse contour of the deformable element 3 and of the constriction 4.

 In the embodiment of the invention shown in Figure 2, the telescopic assembly comprises a shaft 1 which has a circular section, and a tube 2, the recess 6 of which also has a circular section, the transverse dimensions of which depend on the transverse dimensions of the shaft I allow this shaft 1 to slide in the tube 2; the shaft and the recess 6 having means for securing in rotation constituted by a grooved system or any other system.

 The deformable element 3 also has a circular section of substantially constant profile and dimensions, the transverse size of which is related to the section of the recess 6 of the tube 1, so that this deformable element 3 can slide in the first part longitudinal 2a of the tube 2.

 The narrowing 4 arranged in the second longitudinal part 2b of the tube 2 has a circular section of profile and of substantially constant dimensions which are smaller than the circular section of the deformable element 3.

 The longitudinal shape characteristics, the longitudinal dimensional characteristics, as well as the transverse dimensional characteristics of the constriction 4 are determined as a function of the characteristics of the deformable element 3, in order to obtain the required axial energy absorption law, and vice versa. deformable element 3 as a function of the narrowing 4.

 Without departing from the scope of the invention, the different parts described in Figure 2 can have a complementary section relative to each other, instead of having a circular section.

 In the embodiment shown in Figure 2, the deformable element is preferably constituted by an elastomer.

 In the device according to the invention, the energy absorption curve is represented in FIG. 3 and referenced B. In this device, the force as a function of the stroke in a first phase increases relatively rapidly, then in a second phase, it is established at a value which increases relatively little as a function of the continuation of the axial energy absorption curve.

 The embodiment of the axial energy absorption device according to the invention shown in Figures 4, 5, 6, 7, 8, 9 and 10 comprises a telescopic assembly, and a deformable element 13.

 The telescopic assembly consists of a shaft 11, which is mounted in a tube 12, so as to be able to slide one inside the other along a first longitudinal part 12a of the tube 12.

 The deformable element 13 is slidably mounted in the first longitudinal part 12a of the tube 12, and it is located between the end of the shaft 11, and the second longitudinal part 12a of the tube 11.

 The second longitudinal part 12b of the tube 12 is provided with a narrowing 14, the passage of which is smaller than the transverse size of the deformable element 13.

 The different characteristics of the constriction 14 and of the deformable element 13 are chosen and adapted with respect to each other, so that in the event of an axial shock the absorption of axial energy takes place according to the desired law. This axial energy absorption law is given by the adaptation of the transverse interference as a function of the longitudinal displacement of the deformable element 13 in the constriction 14.

 The shaft 11 and the recess 16 of the tube 12 of the telescopic assembly have a cross section of profile conjugated with two diametrically opposite circular parts 17, which are connected to each other by two flat parts 18 so as to be united in rotation.

 The deformable element 13 shown in Figures 7 and 8 has a section of substantially constant profile and dimensions, which is conjugate with the section of the recess 16 of the tube 12. This section of the deformable element 13 has two circular parts 19 which are diametrically opposite one another, and which are connected by two flat parts 20.

 The constriction 14 more precisely represented in FIGS. 9 and 10, is located on the second longitudinal part 12b of the tube 12. This constriction 14 comprises two indentations 21 made in the middle of each of the two flat parts 20, so as to be diametrically opposite, that is to say to face each other.

 According to a variant of the invention, the constriction 14 can be an injected element or a deformation of the outer tube.

 The longitudinal shape characteristics, the longitudinal dimensional characteristics, as well as the transverse dimensional shape characteristics of each of these two indentations 21 are determined as a function of the deformable element 14, in order to obtain the required axial energy absorption law, and conversely the deformable element 13 as a function of the narrowing 14.

 In the embodiment shown in the Figures, the deformable element 13 is made of plastic.

 The absorption process during an axial impact is shown in FIGS. 4, 5 and 6. In the event of an impact, there is first of all an approach stroke until the deformable element 13 comes at the end of the first longitudinal part 12a of the tube 12, that is to say so as to appear before the constriction 14. Then, as can be seen in FIG. 5, under the effect of the shock, the deformable element 13 pushed by the shaft 11 forcibly engages in the narrowing 14. Finally, after the crossing of this narrowing, the deformable element 13 is located on the other side of the narrowing 14, in the second longitudinal part 12b of the tube 12, as shown in Figure 6.

 One of the determining aspects of the invention is that one can act on the different characteristics of the deformable element 3 or 13, as well as on the different characteristics of the shrinkage 4 or 14 of the tube 2 or 12.

As regards the deformable element 3 or 13, the various characteristics which can be acted upon to obtain the desired axial energy absorption law are:
- the material constituting the deformable element,
- the longitudinal shape characteristics and the longitudinal dimensional characteristics,
- the transverse shape characteristics and the transverse dimensional characteristics, and
- structural features.

The different characteristics of the shrinkage 4 or 14 of the tube 2 or 12 on which one can act to obtain the desired axial energy law are:
- the shape characteristics and the longitudinal dimensional characteristics,
- the transverse shape characteristics and the transverse dimensional characteristics.

 It is thus possible by acting on one or more of these different characteristics of the deformable element and of the narrowing with respect to each other to rigorously adapt the energy absorption of the device according to the desired law.

 Finally, in order to improve the engagement of the deformable element 3 or 13 in the narrowing 4 or 14, this deformable element comprises an input chamfer respectively referenced 5 and 15. It must be observed that the shape and dimensional characteristics of this chamfer are determined to obtain the required axial energy absorption law.

 According to a variant of the invention, the deformable element 3 can be mounted to slide with more or less play, but also mounted clamped with suitable clamping, or even be injected directly into the tube 2.

 According to another variant of the invention, the shaft and the deformable element constitute a single piece.

 The reference signs inserted after the technical characteristics mentioned in the claims, have the sole purpose of facilitating the understanding of the latter, and in no way limit their scope.

Claims (9)

 1. Axial energy absorption device of a mechanical system characterized in that it comprises:  - a telescopic assembly constituted by a shaft (1, 11) mounted in a tube (2, 12) so as to be able to slide one inside the other along a first longitudinal part (2a, 12a) of the tube ( 2, 12); the shaft (1, 11) and the tube (2, 12) having means for securing in rotation.  - the different characteristics of the narrowing (4, 14) and of the deformable element (3, 13) being chosen and adapted with respect to each other so that in the event of an axial shock, the absorption of axial energy s 'performs according to the desired law given by the adaptation of the transverse interference as a function of the longitudinal displacement of the deformable element (3, 13) in the constriction (4, 14).  - The second longitudinal part (2b, 12b) of the tube being provided with a narrowing (4, 14) whose passage is smaller than the transverse size of the deformable element (3, 13);  - a deformable element (3, 13) mounted so as to be able to slide in the first longitudinal part (2a, 12a) of the tube, between the end of the shaft and the second longitudinal part (2b, 12b) of the tube;  2. Absorption device according to claim 2, characterized in that the different characteristics of the deformable element (3, 13) on which one acts to obtain the desired axial energy absorption law are:  - the material constituting the deformable element,  - the longitudinal shape and dimensional characteristics,  - the transverse shape and dimensional characteristics.  - structural features.  3. Absorption device according to any one of the preceding claims, characterized in that the different characteristics of the narrowing (4, 14) of the tube (2, 12) on which one acts to obtain the desired axial energy law are :  - the longitudinal shape and dimensional characteristics,  - the transverse shape and dimensional characteristics.  4. Absorption device according to any one of the preceding claims, characterized in that:  - The telescopic assembly comprises a shaft (11) and a tube (12), the shaft (11) and the recess (16) of the tube (12) having a profile section conjugated with two circular parts (17, 19 ) diametrically opposite and connected by two flat parts (18, 20) so as to be integral in rotation,  - the deformable element (13) has a section of substantially constant profile and dimensions which is combined with the section of the recess (16) of the tube (12) with two diametrically opposed circular parts (19) connected by two flat parts (20),  the narrowing (14) of the second longitudinal part (12b) of the tube (12) comprises two indentations (21) made in the middle of each of the two flat parts (20) so as to be diametrically opposite,  - the longitudinal shape and dimensional characteristics, as well as the transverse shape and dimensional characteristics of each of the two indentations (21) being determined according to the deformable element (14) to obtain the required axial energy absorption law .  5. An absorption device according to claim 4, characterized in that the deformable element is made of plastic.  6. Absorption device according to any one of claims 1 to 3, characterized in that:  - The telescopic assembly comprises a shaft (1) and a tube (2), the shaft (1) and the recess (6) of the tube (2) having a circular section with means for securing in rotation;  the deformable element (3) has a circular cross section of substantially constant profile and dimensions,  the narrowing (4) of the second longitudinal part (2b) of the tube (2) has a circular section of profile and of substantially constant dimensions,  - the longitudinal shape and dimensional characteristics, as well as the transverse dimensional characteristics of the narrowing (4) being determined as a function of the deformable element (3) to obtain the required axial energy absorption law.  7. Absorption device according to claim 6, characterized in that the deformable element is made of elastomer.  8. Absorption device according to any one of the preceding claims, characterized in that the deformable element (3, 13) comprises an inlet chamfer (5, 15) in the narrowing (4, 14), the characteristics of shape and dimensions being determined to obtain the required axial energy absorption law.  9. Absorption device according to any one of the preceding claims, characterized in that the shaft (1, 11) and the deformable element (3, 13) constitute a single piece.