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Title:
SPRING STIFFNESS AND PRETENSION ADJUSTING SYSTEM
Document Type and Number:
WIPO Patent Application WO/2011/051884
Kind Code:
A1
Abstract:
A spring adjustment system having an inner leading element (1,18) receiving the rotary motion externally given through an adjustment nut (2, 19) placed upon a cap (3, 14), and a body element (6, 16) - receiving the rotation of said inner leading element (1, 18) - with a grooved surface (12, 35) having a thread pitch bearing all or only a portion of the spring coils and having a machined surface (8, 36) with a thread pitch - a guidance element (11, 15), having a machined surface (10, 17), coupled with the machined surface (8, 36) of said body element (6, 16); wherein said guidance element forces said body element (6, 16) into an helical path, once set in rotation by said leading element (1, 18), said guidance element (11, 15) being fixed to said cap (3, 14) of said adjusting system.

Inventors:
CORSO MATTEO (IT)
Application Number:
PCT/IB2010/054846
Publication Date:
May 05, 2011
Filing Date:
October 26, 2010
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
CORSO MATTEO (IT)
International Classes:
F16F1/04; F16F1/12
Foreign References:
US20080099968A12008-05-01
EP1843058A12007-10-10
US6471197B12002-10-29
US5553836A1996-09-10
US5044614A1991-09-03
DE102007011325A12008-09-11
DE202007017158U12008-02-28
US20080210842A12008-09-04
JPH10267062A1998-10-06
US5553836A1996-09-10
EP1843058A12007-10-10
US20060180419A12006-08-17
US5409248A1995-04-25
US5044614A1991-09-03
DE202007017158U12008-02-28
DE102007011325A12008-09-11
US20080099968A12008-05-01
Download PDF:
Claims:
Claims

[Claim 1] A springs stiffness adjusting system for adjusting the stiffness k of the spring (9, 13, 21) of a mechanical system, preferably a suspension or a fork, k being defined by the formula F=k*x (where F stands for the force generated by the spring as a result of a compression x thereof), comprising a plurality of inactivation elements (1, 6, 11), (18, 16, 15), (29, 20, 25), wherein at least one of said inactivation elements (1, 6, 11), (18, 16, 15), (29, 20, 25) slides along said spring (9, 13, 21) coils, and wherein the insertion of at least one of said inactivation elements (1, 6, 11), (18, 16, 15), (29, 20, 25) allows said spring (9, 13, 21) being compressed at different position along the length of said spring (9, 13, 21) in order to inactivate an entire number or a portion of spring coils of said spring (9, 13, 21).

[Claim 2] The system as recited in claims 1, further comprising:

- an inner leading element (1, 18) receiving the rotary motion externally given through the adjustment nut (2, 19) placed upon the cap (3, 14), said cap (3, 14) remaining fixed throughout the adjustment, said cap being connected by a thread (4, 33) to the outer tube (5, 34) of said adjusting system;

- a body element (6, 16) receiving the rotation of said element (1, 18), generated by said rotary motion, said body element characterised in that it comprises:

a grooved surface (12, 35) having a thread pitch preferably equal to the pitch of said spring (9, 13), for bearing an entire number or a portion of spring coils;

a machined surface (8, 36), preferably threaded or grooved, having a thread pitch preferably equal to the pitch of said spring (9, 13);

- a guidance element (11, 15), having a machined surface (10, 17), preferably threaded or grooved, coupled with the machined surface (8, 36) of said body element (6, 16); wherein said guidance element forces said body element (6, 16) into an helical path, once set in rotation by said leading element (1, 18), said guidance element (11, 15) being fixed to said cap (3, 14) of said adjusting system.

[Claim 3] The system as recited in claims 1 and 2, characterized in that the

stiffness adjustment of said spring (9, 13) ranges continuously between the maximum and minimum values defined by the design of said spring (9, 13) or by the specific application of said adjusting system.

The system as recited in claims 1 or 2, characterized in that said spring (9, 13) does not reach the cap (3, 14) of the outer tube (5, 34) of said adjusting system.

The system as recited in claims 1, characterized in that said spring (13) rests directly onto the cap (14) and is pushed during the stroke of said fork by the same said cap (14).

The system as recited in claims 1 further comprising:

- a inner leading element (29) receiving the rotary motion externally given through the adjustment nut (27) placed upon the cap (28), wherein said inner leading element (29) comprises a machined surface (30), preferably threaded or grooved , having a thread pitch preferably equal to the pitch of said spring (21), for blocking said spring (21) to said inner leading element (29); wherein said cap (28) remains fixed throughout the stiffness adjustment, said cap (28) being connected by a thread (37) to the outer tube (26) of said adjusting system;

- a body element (20) receiving the rotation of said element (29), generated by said rotary motion, said body element

(20)characterised in that it comprises:

a grooved surface (38) having a thread pitch preferably equal to the pitch of said spring (21), for bearing an entire number or a portion of spring coils;

a machined surface (22), preferably threaded or grooved, having a thread pitch preferably equal to the pitch of said spring (21), said machined surface (22) being coupled with the machined surface (30) of said inner leading element (29);

two appendices (23) protruding from the outer surface of said body element (20);

- a guidance element (25), having a machined surface (24), preferably as vertical grooves coupled with said two appendices (23) of said body element (20).

The system as recited in one or more of the preceding claims, characterised in that the stiffness adjustment is manual.

The system as recited in one or more of the preceding claims, characterised in that the stiffness adjustment is actuated by an electric engine or device.

The system as recited in claim 1 wherein said suspension is a vehicle suspension such as cars, trucks, campers, bicycles, quads, and motorcycles or the like.

The system as recited in claim 1 characterised in that said mechanical system is any mechanical system comprising one or more springs wherein said springs require stiffness adjustment.

The system as recited in claim 1, characterised in that said mechanical system is a mechanism for adjusting independently both the preload of said spring or the spring stiffness by means of a modified cap of said outer tube.

The springs stiffness adjusting system for adjusting the stiffness k of the spring of a mechanical system, preferably a suspension, as recited in one or more of the preceding claims, characterised by what is described and showed with reference to the attached invention drawings.

Description:
Description

SPRING STIFFNESS AND PRETENSION ADJUSTING SYSTEM

Technical Field

[1] This patent application relates to a springs stiffness adjusting system i.e. a system for adjusting the stiffness K of springs which is suitable of being advantageously applied as shock-absorber or fork to any mechanical system involving the use of springs such as cars, trucks, campers, bicycles, quads, and motorcycles of any kind.

Background Art

[2] It has been well known that the mechanical work of a suspension or a fork is given by two systems that slide over each other. More specifically, as far as the motorcycle field is concerned, the upper system, e.g. the bike frame, is directly connected to the bike, while the lower system is directly connected to the wheel. The mechanical mean that connects the two systems is the spring which is compressed during the stroke of the fork. The maximum stroke occurs when an appropriate element of the upper system rests upon an equally appropriate element of the lower system. Figure 1 shows a shank of the fork in the condition called 'extended position' and the configuration of said shank for any value of the stroke of said spring.

[3] Likewise, it is known that springs are characterized by an elastic constant called k

(for which it is valid the formula F=k*x with F equal to the force generated by the spring after a compression x of said spring) that represents the stiffness of the spring. The bigger the value of k, the greater the external force to obtain a given compression of the spring. Given the stiffness k of a spring, it is possible to plot a straight line, or a curve, that represents its elastic behaviour on a plane called ' External Force vs. Compression'. This plot is the well-known characteristic curve of the spring.

[4] In this technical field several solutions have been proposed by different inventors. A first solution is described, for instance, in US Patent 5 553 836 which discloses an adjustable vehicle suspension system comprising a geared adjustment mechanism that allows levelling of a motorised vehicle body. In this solution, no means for spring stiffness and spring preload adjustment are provided. Particularly, under working conditions, the stiffness of the spring within this system is not modified. Moreover this system is too big and therefore not suitable for application as a fork, for instance, as a motorbike fork. The system is therefore useful only when transporting a heavy load because it allows manual or automatic adjustment to raise or lower the body of the vehicle.

[5] In a second patent document EP1843058 (Neotek Co. Ltd) an adjustable spring coefficient system of a helical spring is described, but the spring adjustment mechanism works only with large diameter helical springs and is suitable only for application in a shock absorbing device. The application in a fork of this claimed solution is not possible.

[6] The use of forks or shock absorber employing the preload to modify the characteristic curve of the spring is particularly widespread in the motorcycle field. In general t he preload is obtained through a disk with a vertical motion placed at one end of the spring. This adjusting system can be recognized in patents US 2006/0180419 and US 1995/5409248 for instance. Even Ohlins®, one of the world's best known fork manufacturers, adopts this type of adjustment for its products. Acting from the cap of the fork, it is possible to move the disk and to increase or decrease the load which the spring is subject to without compressing the shank.

[7] The adjustment of the characteristic curve through the preload has some restrictions due to the fact that if you want to increase the value of force to a specific stroke, you must increase with the same value all the points of the characteristic curve. Therefore, the user is often forced to replace the spring with another one having a different stiffness. As a consequence, this type of adjustment is considerable both work and time consuming.

[8] In another patent document namely US 5044614 ('Shock absorber spring adjuster') a shock absorber permitting simple and rapid alteration of length of coil spring is described. During adjustment of the shock absorber the stiffness of the spring is not modified. The same mechanism of shock adjuster setting is also described in several other documents such as DE202007017158 ("Damping adjustable front wheel fork for a bicycle"). The front wheel fork is designed such that the fork permits adjustment of a damping path without changing an elongation rate of the compression spring.

Therefore, in this solution the stiffness of the spring within this system is not modified under working conditions. Moreover, the solution disclosed is based on a spring having a very complex shape and characterized by a specially machined upper end.

[9] DEI 02007011325 describes a spring holding part for fixing screw tension spring which has external thread basic diameter larger than spring's internal diameter when compressed and/or external thread pitch greater than spring pitch when compressed. The solution is suitable for fixing a screw tension spring. Also in this solution the stiffness of the spring within this system is not modified under working conditions.

[10] Lastly, US patent 0099968 describes an adjustable and progressive coil spring

damping system for use in shanks of mountain bicycle fork. The disclosed damping system is based on two coupled springs whose length changes as a function of to user setting. Therefore also the pre-load changes accordingly.

[11] The solutions known in the art comprise one or more springs inside a fork which are compressed by a disk that rests onto the end coils that are generally closed and ground to provide a flat plane. [12] The springs stiffness adjusting system herein disclosed introduces a novel element of thrust on the spring which relies on a new type of bearing surface composed of a helical groove having the same pitch of the coils of the spring. Thanks to this new element, the spring can be pushed from different heights inactivating some coils.

Disclosure of Invention

Technical Problem

[13] In several demanding applications and technical fields, for instance the motorcycle industry, and more specifically during competitions, a key factor for best results achievement is quickness during the setting-up operations of the bike or, more generally, of the vehicle. This may happen during the qualifying sessions or during the races themselves, should the weather conditions suddenly change causing a need for a sudden modification of the set-up of the bike. The adjustable mechanism object of this invention directly tackle this technical problem and concerns both the front and rear suspensions of the bike.

[14] Currently to achieve the right set-up you must act on the spring preload, leading the translation of its characteristic curve to the x-axis on the 'Force vs. Compression' plane. Nevertheless, if both the minimum and maximum preload do not lead to the

achievement of the optimum setting, for instance for a front suspension in a given race track and with given weather conditions, the spring must be replaced.

[15] According to what above-described, there exists a need for identifying an improved system capable of either solving or overcoming the problems just mentioned. This invention describes and claims a new mechanism for adjusting the characteristic curve of the spring, saving a considerable amount of time when finding the right setting of a mechanical suspension. The invention allows the variation of the stiffness of a spring and, as a consequence, once inserted into the fork, the spring is no longer replaced. Technical Solution

[16] This invention describes and claims a springs stiffness adjusting system conve- nientely designed for changing the value of stiffness of the spring used in a suspension. Its main purpose is to disclose a new method for adjusting suspensions possible, and, at the same time, dramatically reduce the time needed for the set-up. The mechanism is meant to substitute or support the spring preload, the current way to set up racing bikes.

[17] The new system described herein, acts on coils enabling the variation of the stiffness of the spring in the fork or of the spring in the shock absorber, thus avoiding its replacement. Therefore, the gradient of the curve is modified as to provide the adjustments with a higher influence on the motorcycle set-up at any racing value of the suspension. Advantageous Effects

[18] The object of this invention consequently avoids spring replacement, granting a considerable saving of effort and time, key factors to achieving good performance in competitions.

[19] One of the most surprising features of this invention is that the adjustment of the stiffness is continuous. This means that it is possible to get any value of stiffness included between the minimum and maximum values defined by the design of the spring or the specific application of the system.

[20] Below are described a preferred or best mode and two other embodiments of the springs stiffness adjusting systems according to the invention herein disclosed. The embodiments of the invention are set forth without any loss of generality to, and without imposing limitations upon, the claimed invention.

Description of Drawings

[21]

Best Mode

[22] Embodiment - Short spring

[23] The following is the example of a system that can continuously modify the stiffness of a spring. It well explains the work of the mechanism (Table 2).

[24] This example refers to the case where the spring inside the shank of the fork does not reach the cap, thus requiring an additional mean.

[25] The inner leading element (1), preferably an hexagonal section bar, described in

detail in Figure 6, is the innermost part of the mechanism and receives the rotary motion externally given by the user through the adjustment nut (2) placed upon the cap

(3) . Said cap (3) remains fixed throughout the adjustment, being screwed by a thread

(4) to the outer tube (5) of the shank, i.e. the connecting element between the fork and the bike.

[26] The body element (6), described in detail in Figure 4, is the central element of the mechanism and receives the rotation by said element (1) through the hexagonal hole (7) crossing it. On its outer surface there is a thread (8) having the same pitch of the spring (9) inside the fork. Said thread (8) must be coupled with the helical groove (10) on the inner surface of the third element (11), herein named the guidance element (11) and described in detail in Figure 5, and its aim is to give said body element (6) an helical path, once set in rotation by said hexagonal element (1). This trajectory is not prevented by said hexagonal mean (1) since said body element (6) is free to slide along its external surface. In its lower part said body element (6) has an helical groove that provides said spring (9) with a bearing surface. Said guidance element (11) is fixed to said cap (3) of the shank and has said helical groove (10), preferably a thread on its inner surface having a pitch substantially equal to the pitch of said spring (9). When adjusting the stiffness, said spring (9) maintains its position and does not rotate.

[27] The work of the mechanism starts with the rotation of said adjustment nut (2) placed upon said cap (3) of the shank that sets said body element (6) in rotation. Said body element (6), driven by said guidance element (11), makes a helical path placing at a certain height of said spring (9), fitting in the coils and avoiding them.

[28] The size of the pieces depends upon the type of fork in which they are mounted. Said body element (6) and said guidance element (11) have, without no loss of generality, a length preferably included between 50 and 200 mm, at least for motorcycle applications. The outer diameter of said body element (6) must be minimized so that no excessive weight overload the suspension. Without no loss of generality, the outer diameter can ranges preferably between 18 and 40 mm. The diameter of the lower part of said body element (6) should be almost equal to the outer diameter of said spring (9) in order to obtain a good bearing surface. The length of said inner leading element (1) depends on the maximum stroke of said spring (9) taken into account. For applications, for instance, in the bicycle industry, the size can decrease considerably compared to what above-described. On the contrary, it can remarkably increase in the automotive industry.

[29] Moreover, the system lends itself to be used as a mechanism of variation of the

preload of said spring (9) if the individual means are properly used. If said body element (6) was made translate vertically without rotating, it would compress said spring (9) modifying the preload. This condition is achieved by rotating said guidance element (11) and fixing said adjustment nut (2). Acting this way, said body element (6) slides along said inner leading element (1) without rotating. This use of the mechanism involves, however , a reassessment of the geometric structure of said cap (3).

Mode for Invention

[30] Embodiment 2 - Long spring

[31] This embodiment (Figure 7) discloses a springs stiffness adjusting system wherein the spring (13) does reach the cap (14) and there is no room on the top of it for the means mentioned in the previous preferred mode.

[32] The guidance element (15), described in detail in Figure 10, is fixed while adjusting and it acts as a guide to the motion of the body element (16), described in detail in Figure 9, through a thread (17) with the same pitch of said spring (13). Said body element (16) rotates thanks to the motion of the inner leading element (18), the innermost element of the mechanism, set in motion by the internal part of the cap (19) and, at the same time, it slides along its surface making a helical path as described in embodiment 1 'The short spring'. While adjusting the stiffness, the spring maintains its position and does not rotate. [33] The size of the elements depends on the field of application which the fork is intended for and what has been said in relation to Embodiment 1 remains effective.

[34] Again it is possible, with appropriate modifications to the geometry of said cap (14), to use the mechanism in order to modify the preload of said spring (13).

[35] Embodiment 3 - No body element rotation

[36] In this embodiment of the invention (Figure 12), a body element (20), described in detail in Figure 14, is simply considered as the element giving support to the spring (21) thus not including, as in the previous embodiment, said thread (8) or groove (35). The thread (22) that controls the helical motion of said body element (20) is obtained in the inner surface of the hole made axially in said body element (20). In order to stop the rotation of said body element (20) it is necessary to use two appendices (23) that fit into suitable grooves (24) made in an outer pipe (25), described in detail in Figure 16, to be connected to the shank. Said appendices (23) run vertically only. The initial rotation of the adjustment always starts with the adjustment nut (27) placed on the cap (28). This motion sets the rotation of the internal element (29), described in detail in Figure 15, directly connected with said adjustment nut (27). Said element (29) has on its outer surface a thread (30) having the same pitch of that of said spring (21).

[37] This element is also meant to determine the maximum stroke of said spring (21) and its unique motion is rotation. The operation principle, therefore, iworks as follows: the rotation of said adjustment nut (27) makes the rotation of the element (29) which, as a consequence, sets said spring (21) in rotation. The thread (30) is likely to set said body element (20) in rotation. On the contrary, said body element (20) is bound to run along the two vertical grooves (24). Said spring (21) rotates integrally with said element (29) thanks to a suitable appendix of said element (29).

[38] Again, it is possible, with appropriate modifications to the geometry of said cap (28), to modify the preload of said spring (21).

Industrial Applicability

[39] This innovative system herein disclosed can be conveniently applied to suspensions of any kind of vehicle based on springs such as cars, trucks, campers, bicycles, quads, and motorcycles of all types especially when stiffness modification is required.

Moreover, the system is suitable to be operated by electric engines.