This application claims priority to French Patent Application No. 2112416 filed Sep. 23, 2021, the entire contents of which are hereby incorporated by reference.
The present invention relates to elastic compression devices for storing, thanks to a composite spring, large elastic energies under a small mass, for the following applications fields:
It is known that steel springs have relatively modest energy densities of 250 or even 300 Joules per kilogram (J/kg).
Metal springs are sensitive to corrosion and notching, which leads to explosive rupture of these.
Composite coil springs, which we invented, manage to achieve energy densities of 600 J/kg.
Composite springs have a fibrous glass structure that allows them to be immune to corrosion and notch shocks (they are said to be damage tolerant).
All the springs of the prior art suffer from the serious problem called creep; that is, they lose load, gradually, when compressed for a long time.
The European patent 94401868.8 of 18 Aug. 1994 under priority of the patent FR 9310146 of 20 Aug. 1993 (of the author) describes a spring in the shape of a “C”, this spring uses a ribbon having a width substantially equal to the width of the spring and a thickness perpendicular to said spring significantly less. The said composite reinforcement tape is wound continuously around the spring circling the central spacer and the fixing eyes uninterruptedly. In other words, said ribbon travels for example the extrados of the spacer, then turns around the eye of one end and returns to the other eye by going through the intrados of the spring, it then turns around the second eye and leaves on the extrados (for a finite number of turns). When loading the eyes, i.e., when applying a force to bring them closer together. In the configuration claimed by the FR 9310146 patent, the following phenomena are observed: the eyes grow on the area of the ribbon located on the side of the intrados. The tape, under load, peels off the spacer, this inevitably causes the total delamination of the tape layer and the ruin of the spring. In addition, the spacer being of constant section the quadratic moment applied to the spring is not mastered. This is our very first spring and is therefore very far from mature. Such a spring is not able to store interesting energy.
Patent FR 85 13960 of 20 Sep. 1985 (applicant National Renault Authority) this patent deals with a leaf spring and how to fix its ends. There is absolutely no common ground between such a spring and an omega spring! In addition, putting an eye inside the spring blade is likely to cause delamination of the composite. Placing an eye between layers of composite is therefore also a very bad idea!
Patent JP 2015187459 A of 29 Oct. 2015, this patent in hairpin spring, with constant thickness and moreover the ends of said spring are pinched. This patent has no prior art to the invention.
Patent EP 0132 048 A1 of 23 Jan. 1985 this patent presents zig-zag springs consisting of ribbons with constant thickness and therefore without spacer to manage the moment applied along the said zigzag; moreover, the ends of the zigzag are not treated, nor clearly claimed as shown in FIG. 1 of the said patent.
Patent 1910754 of 28 Sep. 2019 (of the author) this patent describes a composite spring in the shape of “C” (see
Patent DE 10 2015 012334 B3 of 16 Feb. 2017 of Hoffmann, this patent presents a series of zigzag springs placed in circle around a centerline. These springs being independents each other. In addition, the zigzag springs do not have spacer in their apex; so, this patent is out of the scope of our patent: no spacers and independent zigzag
Patent DE 10 2019 109554 A1 of 15 Oct. 2020 of Danto invent GMBH, this patent presents a single zigzag spring having spacers in their apex; so, this patent is out of the scope of our patent having spacers on a single zigzag.
The present invention relates to compression springs, it aims to achieve a device, damage tolerant, offering a perfect immunity to sag, shocks, corrosion, and notch, while reaching levels of considerable stored energy density namely 1,400 J/kg or even more!
The present invention is intended to make it possible to carry out a mastered loading of the composite.
The present invention aims to offer the benefits of the spring in “C”, more than 75% gain in mass and 50% gain in cost compared to a steel coil spring, while housing in the same volume as a coil spring.
The present invention removes the objections of vehicle platform managers, who wish to keep the possibility, at any time, to have the choice between the composite spring and a conventional coil spring.
The invention will be described in connection with the following drawing figures, in which:
In order to achieve our goals, we have designed a composite bellows spring called BELLOWSPRING.
The bellows itself is obtained by “rotating” the axis (5) around the axis (8); we then obtain a bellows of revolution. See
Let's analyze how this spring works:
The working area is defined as the area from the loading point (11) to the opposite point (11′) in the case of a “C” spring (also called omega spring) (see
So, we have a self-tightening structure [tape (1)/spacer (3)/tape (2)] absolutely unique and perfectly impossible to delaminate.
Omega springs, of our design, have been tested, under nominal load, for 20 years, without presenting any creep.
“Didactic” springs were provided with a layer of Teflon between the tape (2) and the spacer (3), these springs had the same compression properties as a spring without Teflon . . . .
The present invention is characterized by the so-called “C” shape of its elastic element; this precise shape, is drawn on the basis of portion(s) of ellipse, as shown in
The immaterial line, passing through the loading areas respectively (11), (11′) is designated by the marker (5).
The omega spring consists of unidirectional composite ribbon sheets (composed of fibers (or stratifils) and matrix) running uninterruptedly from the end (11) of the spring to the opposite end (11′), said spring.
We designate by extrados, the outer side of the omega, where the composite tablecloth is located (1), and by intrados the inner side of the omega where the composite tablecloth is located (2).
In the case of the spring of
In the case of the spring of
In the case of the spring in
Is designated by axis of symmetry (4) of the elementary spring of
Apex means the point of the extrados of the spring furthest from the axis (5), in the plane of the spring of
In the case of
In other words, in the case of
The spacer (3), in the case of
On the same principle, in the case of the BELLOWSPRING in
In the case of the BELLOWSPRING of
In order to reinforce the bonding between the composite tablecloth of type (1) and (2) of the bellows, it is advantageous to extend these by a ring (A) ranging from (10 to 9) so from (10′ to 9′) from (10″ to 9″) from (10″′ to 9″′).
Such a ring (A) also makes it possible to constitute a base of support of the bellows.
Note that it is possible to close both ends of the bellows, which is to say that the two bottoms ranging from (10 to 10′) and (10″ to 10″′) are closed airtight and fluid tight.
It is then possible to introduce a fluid, for example air or a gas compressed from water or oil into the bellows; one then has the possibility of having a suspension benefiting from the mechanical rigidity of the bellows and for example the pressure of the compressed gas. Thus, with a constant attitude, it is possible to withstand very different loads or to change the vehicle's attitude, depending on the terrain.
The present invention is characterized by an extreme ease of industrial realization, requiring only modest investments; it is also of a relatively simple and easy-to-use structure.
In particular this bellows can be mounted in place of a coil spring.
The spring, as described is cylindrical, it can be drawn in barrel, conical, single, or double “pig's tail”
The spring as described develops a perfectly axial thrust, which is to say aligned with the axis (8) (Z), because it consists mainly of the two layers of type (1) and (2) of revolution. It is possible to decenter, the said push, by adding a local overthickness. this thickness occupies the entire height of the bellows but only on an area defined by the angle (α) in
It is specified that adverbs preferentially, and optionally mean that one can preferably use a solution or that one can does not use it while remaining within the scope of the invention
It is well specified that, on the figures, the same references designate the same elements, whatever the figure on which they appear and whatever the form of representation of these elements. Similarly, if elements are not specifically referenced on one of the figures, their references can be easily found by referring to another figure.
The applicant also wishes to specify that the figures represent an embodiment of the object according to the invention, but that there may be other embodiments that meet the definition of this invention. For example, composite tablecloths or tubes of type (1) and type (2) can be: either being purely unidirectional (UD) ranging from (ES) to (EI) or being a mix of fibers (UD) going from (ES) to (EI), and fibers forming a non-zero angle with said fibers (UD), and in particular this angle can be 90°.
It further specifies that, where, according to the definition of the invention, the object of the invention comprises “at least one” element having a given function, the embodiment described may comprise several of these elements.
It also specifies that, if the embodiments of the object, according to the invention, as illustrated comprise several elements of identical function and that if, in the description, it is not specified that the object according to this invention must necessarily comprise a particular number of these elements, the object of the invention may be defined as comprising “at least one” of these elements.
It is specified that where, in this description, an expression alone defines, without any specific reference to it, a set of structural characteristics, those characteristics may be taken, for the definition of the object of protection sought, where technically possible, either separately or in total and/or partial combination.
It is specified that the invention relates to BELLOWSPRINGs, as described, that is to say having spacers of type (3 and 3′).
Finally, it is specified that by varying the value of the angle (β) at the points of type (6), we can adjust the evolution of the law of stiffness of the spring. Thus if (b) is less than 90° (for example 70°) at the beginning of compression and it reaches 90° in maximum compression, the spring will have an increasing stiffness.
It also clarifies that; the term substantially can mean that the property so qualified can be understood either as being exactly or as almost defined. For example, the property “fibers arranged substantially in sinusoids” can mean either that the fibers are arranged exactly in sinusoid, or that they are arranged according to a repetitive irregular arrangement, for example in “zigzag” or cross folds.
Finally, it is specified that the expression “type” makes it possible to design all points of the same type, which is to say similar. Thus, in
Note that, in the case of the end of the bellows of type (10), namely (10 and 10′ and 10″ and 10″′), it is desirable to adopt locally the same angle adjustment (β)
Pig's tail: in the case of a coil spring, it is one or more whorls whose winding diameter is less than the diameter of the main body of the spring, in order to interface with a spring seat of smaller diameter
Extrados: convex bulging part
Intrados: concave hollow part
Curvilinear abscissa: abscissa measured on the line equidistant between the layers of type (1) and (2) for example in
UD: unidirectional fibers.
CE: Sequence of Elementary Cells.
AM: part furthest from the axis (5) of the elementary elastic part called “C” spring Composite tablecloth, or layers or layers of fiber-matrix composite materials is a composite tape made of fibers impregnated by resin
Spring in particular for motor vehicles, comprising
That chamber comprises a side wall consisting of two layers of fibre-matrix composite materials, separated from the top to the feet by a thick composite spacer at the top and which refines towards the two feet of the half-period in such a way that the thickness, at the top of the half-period, is greater than the thickness taken at the feet and is continuously decreasing from the said apex to the two feet of the said half-period.
Spring whose shape of the annular chamber seen from the side is chosen from the following options: rectilinear, curve
Spring whose shape of the annular chamber seen at the end, or in a plane parallel to the ends of said chamber has a shape chosen from the following geometric figures: cylindrical, elliptical
Spring whose annular chamber, has a shape chosen from the following options: of constant diameter over its entire height, of variable diameter over all its height
Spring whose ripples of the annular chamber, are chosen from the following options: constant pitch ripples, variable pitch ripples.
Spring whose ripples of the annular chamber have a shape similar to a half-ellipse
Spring of which the two corrugated layers of “matrix-fiber” composite extending from one end of the annular chamber to the other consist of: on the one hand “fibers”, the fibers being made of one of the following materials: glass, basalt, carbon, aramid, high-density polyethylene and on the other hand a “matrix”, which is a substance intended to bind the fibres together, the matrix chosen from the following options: thermosetting, thermoplastic, rubber and can be of one of the following chemical types: epoxy, polyester, vinylester, polyamide, polyethylene, polyetherimide, polyimide, rubber.
Spring whose spacer, placed between the corrugated membranes, arranged at the top of the half period and extending towards the feet of each half period may according to one of the following options: be molded before placement, be deposited in situ, during the manufacture of the composite annular chamber, said spacer may be constituted, partially, of a part of “fibers”, chosen from the following configurations: continuous, chopped, the said fibers can be on the one hand of one of the following reinforcement fibers: glass, basalt, carbon, aramid, high-density polyethylene, and on the other hand, a matrix, the said spacer can be chosen from the following configurations: only pure “matrix”, a mixture of matrix fibers, said matrix can be of nature: thermosetting, thermoplastic, rubber and be of one of the following chemical types: epoxy, polyester, vinylester, polyamide, polyethylene, polyetherimide, polyimide, rubber.
Spring such that the upper and lower ends of the annular chamber are closed, by two seals located at the level of the said ends, said chamber being thus made watertight, it is then possible to introduce at choice: a fluid, a gas under pressure to vary the height under load and the stiffness of said spring.
Number | Date | Country | Kind |
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2112416 | Sep 2021 | FR | national |