DE2329038A1 - COMPRESSION SPRING MADE OF ELASTOMERAL MATERIAL - Google Patents

Description

The Firestone Tire & Rubber Company,
Akron / Ohio Wl7, USA

Compression spring made of elastomeric material.

The invention relates to a one-piece compression spring with a body portion made of elastomeric material.

Compression springs in vehicle suspensions are problematic the control of the deflection rate or the hardness with regard to the load deflection curve. A high spring rate is made possible by stiffness recognizable by the suspension, which consists of the ratio of a particular load and the static deflection, and by the Tangent to the deflection curve of the special load marked

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net is. A high suspension rate results in a steep tangent, a steep deflection curve and a hard suspension; in contrast In addition, a low spring rate results in a soft suspension, i.e. a greater deflection.

The softness of a suspension is generally determined by its static Deflection or measured by the natural frequency. The natural frequency of a system varies with the reverse Function of the static deflection: The greater the static deflection, the lower the natural frequency and the more the system is softer.

At a constant suspension rate, e.g. a spiral spring off Metal, the softness of the suspension system increases with increasing load; this creates problems, especially where a there is a large difference in weight between an empty vehicle and a fully loaded vehicle: the spring must be dimensioned to to be able to carry a maximum load, but that results in a hard suspension and a rough driving style with light loads.

In addition, with a spiral spring in order to achieve a lower Suspension rate and a higher deflection increase the length considerably, making them unstable in the transverse direction and leads to impractical construction methods. An enlargement of the The length of known elastonic springs would be limiting Factors result.

From US Pat. No. 3,081,993 springs made of elastomeric material are already known, which are surrounded by separate metal bands in order to limit the bulging when loaded. Such an arrangement is actually a rubber spring within a steel spring and is not suitable for narrowly limiting the deflection curve.

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It has also been suggested to use springs which have a substantially cylindrical core made of elastomeric material, which is woven along its entire axial length or knitted reinforcing material is provided, and consists of one piece with this. Such arrangements result however, only a limited control of the properties and only have a short life under bending stress as a result the separation of the reinforcement material from the core.

According to the invention, a rubber spring with a variable spring rate which has essentially the same properties under all loads, while having a Sufficient lateral stability to achieve the high static deflection has the necessary height.

Such a spring is transversely stable in spite of its slimness, and it has a narrowly limited load deflection curve with a natural frequency that is as low and constant as desired, regardless of the load, so that a balance is achieved between a good driving style with light loads and a sufficient load capacity together with transverse stability with increased lengths.

The spring according to the invention consists of a rubber body with a curved outer surface, which includes rubberized fabric material, the cords of which extend at an angle to the axis of the spring and the one surface of decreasing area which extends axially from the end of the body.

In the following the invention is illustrated by means of embodiments and the drawing explained in more detail.

Fig. 1 shows a comparison of load deflection curves;

Figures 2, H and 5 are cross-sections through a preferred embodiment of a spring according to the invention shown in various stages of compression;

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Fig. 3 is a perspective view, partly in section and broken away, a spring according to Fig. 2;

FIGS. 5 to 13 are sectional views of modification forms of FIG Spring according to the invention.

In FIG. 1, the diagram shows the deflection along the abscissa and the load along the ordinate.

In relation to the curves, represents the horizontal distance from the actual deflection to the intersection of the spring rate tangent with the horizontal (deflection) line the equivalent static deflection "D" for a given load Formula 188 defines the natural frequency for a particular load.

At 10 a typical curve for a conventional steel spring with constant spring rate is shown. Its static deflection d * at 4530 kg is 21.6 mm, which corresponds to a natural frequency of 20 ¹ I oscillations per minute; At 31.7 tons, the static deflection d _{9 is} 15.24 cm, which corresponds to a natural frequency of 77 oscillations per minute.

Thus, the steel spring shows a large change in the natural frequencies under light and heavy loads, what is undesirable; Furthermore, the suspension rate is constant at about 5.26 tons per 2.54 cm, calculated by dividing the load due to the static deflection; this rate is too high for light workloads and too low for high workloads.

The spring according to the invention satisfies the claims for a suspension which is relatively soft and has a large deflection at low loads, but which quickly increases its support from higher loads without excessive deflection; a curve characteristic of a spring according to the invention is shown at 11 in FIG.

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At 4.52 tons, a spring according to the invention has a static deflection D. of 5.08 cm, and thus a suspension rate of about 2.26 tons per 2.5 cm. The natural frequency with this load is 133 vibrations per minute. With a load of 13.59 tons the deflection Dp is 5.59 cm and the spring rate is 6.16 per 2.54 cm at a natural frequency of 127 vibrations per Minute. With a load of 31.71 tons the same spring has a static deflection D, of 5.59 cm, which corresponds to a suspension rate of about 14.4l tons per 2.5 ^ cm corresponds to a natural frequency of 127 Vibrations per minute. It can thus be seen that the spring of the invention is a desirable, substantially constant natural one Has frequency, regardless of the load.

The curve HA represents the load deflection curve for a spring which was developed for stiffer properties under load. The corresponding static deflection at 4.53 tons is essentially same as for curve 11, and it gives the same smooth driving style at low loads; the corresponding static The deflection D at 31.71 to is only 4.31 cm. Corresponding a natural frequency of 144 vibrations per minute, so that a stiffer suspension results, which results in greater stability for devices that must have this under load.

In Figs. 2 and 3, the spring according to the invention is in unloaded or uncompressed state described in the curves discussed above. The spring 20 consists of a hollow, substantially cylindrical body 21 with an inner zone or core 22 of elastomeric material, see above such as an outer zone or layer 23 of fabric-reinforced elastomer. As Fig. 3 shows, the zone 23 consists of layers, e.g. 24 and 25 of elastomer-coated cords 26, which are parallel to each other within a certain position. The cords 26 extend at angles to the body axis 3 ^> the angles in adjoining layers, e.g. 24 and 25, being the same but extending in opposite directions.

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Extending axially from ends 27 and 28 of body 21 frustoconical surfaces 29 and 30 with decreasing diameters.

The spring 20 ends in end faces 31 and 32, which are designed to absorb compressive forces that are generated by parts 33 and 36 are shown.

When the spring is loaded in the direction of its axis 3 ^ is the reaction is a tendency to flatten the inclined surfaces 29 and 30 and an expansion of the body portion 21 in the radial direction Direction. The radial restoring force exerted by the inner zone 22 through the inclined cords 26 of the zone 23 is minimal during this initial axial deflection of the spring. However, as the load increases, the spring will deflected further, the beveled end surfaces 29 and 30 have the tendency to flatten, whereby they have a greater resistance oppose; at the same time, the angle of inclination of the cords 26 becomes larger with radial expansion of the body, whereby a greater resistance is opposed to the deflection.

The condition at this increased load is shown in Fig. 4, where the inclined surfaces 29, 30 are now substantially flat, the spring is shortened and its diameter is smaller has enlarged.

A further enlargement of the diameter and a shortening of the spring length result with even greater loads. if the spring expands radially, the deflection of the elastomer is limited by the cord, so that they substantially retains a cylindrical shape as shown in FIG. This prevents and allows the elastomer to deflect transversely producing springs with aspect ratios (i.e. length / diameter) greater than 2: 1.

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Another control of the spring properties is by changing the shape and size of the hole 35 in the core of the spring given or by leaving it out. The larger the hole, the larger the existing deformation area and hence the softness of the feather. A gradual decrease in the hole diameter also affects the spring properties, which can also be influenced by a specially shaped hole, e.g. in the shape of a star, as in 13 is shown at 111.

The load deflection curve 11 of FIG. 1 shows properties of an actual spring 20 which is constructed according to FIGS. 2 and 3. Its axial length in the unloaded state was 56 cm and its outer diameter was 33 cm. Zone 22 had a rubber hardness of 70 durometers; the surfaces 29, 30 were inclined at an angle of 28 ° to the radial plane of the spring and extended in the axial direction 1.27 cm beyond the body ends 27, 28. The cords 26 of the zone 23 extended at angles of about 60 ° to Spring axis J> k in alternating directions.

The state in FIG. K occurs at a load of about 5.44 tons, and FIG. 5 shows the state at a load of about 33.1 tons.

Fig. 6 shows a spring 40 with surface 41 with decreasing diameter, which is curved in contrast to a truncated cone shape.

Fig. 7 shows a spring 50 with a surface 51 the opposite is curved to that in Fig. 6.

8 shows a spring 60, the surface 61 of which, with decreasing diameter, extends axially inward from the end 62 of the spring body 63 extends.

Figure 9 shows a spring 70 having an axially outwardly extending surface 71 at one end and an inwardly extending surface extending surface 72 at the opposite end.

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FIG. 10 shows a spring 80 in which the reinforcement zone 81 extends radially inward at a maximum.

Fig. 11 shows a spring 90 which is conical with inclined end surfaces 91 and 92.

12 shows a barrel-shaped spring 100 with end surfaces 101 and 102.

Fig. 13 shows a spring 110 with an oval cross-section and a star-shaped opening 111.

The invention provides a spring whose mode of operation is controlled by a suitable ratio of various factors can be controlled. For example the type, the dimensions and the angle of inclination of the cord reinforcement, as well as the number the locations thereof can be varied to produce a spring with greater or lesser stiffness, in particular in the area of higher loads.

The fabric reinforcement also makes it possible with high axial length / diameter ratios to work, resulting in a slimness without buckling. Ratios of more than 2: 1 and 3: 1 are easily achievable. As a result, one can create systems with natural frequencies of less than one Generate oscillation per minute.

In certain applications, the cord reinforcing fabric may be wound several times in the same direction and be balanced with other wraps in the opposite direction, as opposed to alternating layers of cord with opposite angles. The reinforcement can also use opposite angular ratios, but not necessarily of the same angle, or the angles of the cords can all extend in a single direction, such as with a continuous wrapping.

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The shape of the main body may be substantially cylindrical as shown in FIGS. 1 to 10, frustoconical as in FIG FIG. 11, barrel-shaped, as in FIG. 12, or oval, as in FIG. 13.

A change in the overall length of the spring also changes its Characteristic, e.g. a shortening makes the spring stiffer.

A spring with a softer characteristic at the low-load end To generate the curve, the axial extent of the surfaces can be increased as the diameter decreases, furthermore if a change in the shape of this area changes the rate, with which the low load end of the curve rises.

It should be noted that the springs have two shaped ends can, or just a shaped end if so for a particular one Intended use is required.

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Claims (13)

Patent claims: One-piece compression spring with a body portion made of elastomeric material, characterized in that the body portion is reinforced against transverse expansion and that its cross-sectional area is reduced at least at one end of the axis. 2. Compression spring according to claim 1, characterized in that the body portion has a circular cross-section. 3. Compression spring according to claim 1, characterized in that the body portion has an oval cross section. Ί. Compression spring according to claim 1 to 3> characterized in that the boundary surface of the body portion on one or on both ends of the axis is frustoconical. 5. Compression spring according to claim 1 to 4, characterized in that that the boundary surface of the body portion is designed to be curved in axial section at one or both ends of the axis. 6. Compression spring according to claim, characterized in that the boundary surface of the body portion on one or both Axial ends have the shape of a cut cup in axial section. 7. Compression spring according to claim 1 to 6, characterized in that the boundary surface of the body portion on one or both Axis ends is a radially inner surface of the body portion. 8. Compression spring according to claim 1 to 7, characterized in that the outer of the body portion between its end portion or End portions is cylindrical. 309881/041 1 9. Compression spring according to claim 1 to 8, characterized in that a hole extends axially through the body portion. 10. Compression spring according to claim 1 to 9, characterized in that the body portion has an elastomeric core which is surrounded by a reinforcing layer which is made in one piece with the core. 11. Compression spring according to claim 10, characterized in that the reinforcing layer consists of a plurality of layers, each of which comprises parallel cords which extend at an angle to the axis of the body portion . 12. Compression spring according to claim 11, characterized in that the cord threads in mutually adjacent layers extend at the same but opposite angles to the axis of the body portion. 13. Compression spring according to claim 10 to 12, characterized in that the core consists of rubber and the reinforcing layer consists of reinforced rubber. 309881/0 A11 Blank page