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    • 专利摘要:
    SUSPENSION STOP, METHOD FOR MANUFACTURING A SUSPENSION STOP AND METHOD FOR ABSORBING SHOCK IN AN AUTOMOBILE SUSPENSION The present invention relates to vehicle suspension systems, and more particularly, suspension stops made of thermoplastic elastomeric material that has enhanced design to maximize energy absorption.
    公开号:BR112013003274B1
    申请号:R112013003274-0
    申请日:2011-08-10
    公开日:2021-02-17
    发明作者:Peter Laszlo Szekely;Damien Van Der Zyppe
    申请人:E.I. Du Pont De Nemours And Company;
    IPC主号:
    专利说明:

    [0001] [001] The present invention relates to the field of vehicle suspension systems and, more particularly, to suspension stops. BACKGROUND OF THE INVENTION
    [0002] [002] A suspension stop (also called a suspension stop, ricochet stop, limit stop, impact stop, suspension stop, or compression stop) is a shock absorption device positioned in an ordinary way on the top of vehicle suspensions. Suspension stops for use in motor vehicle suspension systems have long been used to absorb the impact between two suspension system components, such as the axle and a portion of the frame, as well as to attenuate noise and vibration to increase the passenger comfort. Since a displacement of the vehicle chassis causes displacements of the support, the support is subjected to compression and extension cycles in response to the displacement of the vehicle chassis. Protection of the support assembly and the vehicle body must be provided from the bumping forces associated with severe irregularities on the track surface, which leads to an extreme displacement of the suspension. For this reason, a suspension stop is attached to the suspension system at a point where an impact is likely to occur when the shock absorber fails to absorb the forces created by extraordinary driving conditions. Particularly, during jerk motions of the support, the heatsink "hits the bottom" and the suspension stop moves in contact with the suspension stop plate and compresses to dissipate energy resulting in an impact absorption, which reduces noise and the feeling of impact for passengers and reduces possible damage to the vehicle suspension system. Suspension stops are elongated, usually cylindrical or tapered, members with or without convolutions, made of a compressible and elastomeric material that extends around the piston rod. As taught in US Patent No. 4,681,304, convoluted stops work by progressively stacking convolutions to provide resistance to bumping forces.
    [0003] [003] The materials suitable for this application must be resilient, that is, capable of withstanding a shock without undue deformation or permanent rupture, and must have an excellent useful life of flexibility. Conventional suspension stops are formed of foamed polyurethane and vulcanized rubber. For example, suspension stops are often formed of microcellular polyurethane (MCU). A microcellular polyurethane suspension stop is made by molding polyurethane precursors in a suspension stop mold. Microcellular foam is obtained from the reaction of diisocyanate glycol with a blowing agent or with water that produces carbon dioxide gas for foaming. This technology is time-consuming since foaming requires prolonged mold times due to the slow release of carbon dioxide. Although suspension stops made of foamed polyurethane have good driving characteristics, they are costly to produce as they require technology that consumes time and energy due to cross-linking.
    [0004] [004] In order to improve durability, inertia for automotive fluids and resistance to tear propagation of the material used to form the suspension stop, patent document No. US5.192.057 reveals an elongated hollow body formed of an elastomer , preferably of a copolyester ester polymer. As revealed therein, such parts, including suspension stops that have bellows-shaped sections and with a constant thickness profile, are manufactured by blow molding techniques. An alternative method for forming suspension stops, i.e., corrugated extrusion, is described in published patent application No. U.S.2008 / 0272529.
    [0005] [005] In a typical blow molding operation to manufacture hollow plastic articles, an extruded tube (PARSON) of plastic material that has been produced by extrusion or injection molding and that is in a heated moldable condition is positioned between two halves of an open blow mold having a mold cavity of a shape suitable for the required external shape of the article to be manufactured. The extruded tube moves and gradually stretches under the influence of gravity. When the extruded tube reaches the appropriate length, the mold halves are closed around it and pressurized air or other compressed gas is introduced into the extruded tube to inflate it to the shape of the mold or to expand it against the sides of the mold. mold cavity. After a cooling period, the mold is opened and the final article is ejected.
    [0006] [006] In extrusion-blow molding, the extruded tube is produced by extruders. Extrusion-blow molding is less costly than foaming / casting, but leads to less accurate dimensions and also leads to limitations in the wall thickness of the part. The stiffness of a suspension stop is directly related to its thickness. Thus, a small variation in thickness (be it a variation from article to article, along the longitudinal geometric axis of a suspension stop made of one attempt, or along the convolution radius of a suspension stop made in a single stop of suspension), for example, 0.2 mm, will significantly change the stiffness of the suspension stop and its energy absorption capacity and dissipation performance.
    [0007] [007] Blow-injection molding provides more precise dimensions than a blow-extrusion molding. In this technique, the extruded tube is formed by injection molding, the inner core of the mold is removed and the extruded tube is quickly inflated while being embedded in two mold halves as in an extrusion-blow molding. The extruded tube can be injection molded to have a non-constant cross-section which results in a uniformity of the wall thickness of the final part better than from an extrusion blow molding. Blow-injection molding allows for more precise details in the final blown structure, but is more expensive than blow-extrusion molding.
    [0008] [008] In general, it is desired to maximize the energy absorption in a suspension stop. The energy-absorbing behavior of a suspension stop can be measured, for example, by measuring deformation versus applied force. Normally, a deformation is plotted on the geometric X axis (in mm), and an applied load (force) is plotted on the geometric Y axis (in N). The area below the curve represents the energy absorbed by the suspension stop according to the formula: displacement X Force = energy.
    [0009] [009] Thermoplastic suspension stops made by any of the techniques mentioned above may exhibit different responses depending on the design, including specific configuration details, and manufacturing materials. There is still a need to improve the design of thermoplastic suspension stops in order to improve the forced displacement behavior, thus increasing the absorbed energy. BRIEF DESCRIPTION OF THE INVENTION
    [0010] [010] In a first aspect, the invention provides a suspension stop made of an elastomeric thermoplastic material, which comprises: an elongated hollow tubular body that has a wall, where the tubular body has at least two bellows, where each bellows is defined by a peak and a valley, where the peak has a sweetening radius of rs, and the valley has a rc sweetening radius and a maximum valley wall thickness being at one point in the valley and a designated Tmax; where rc is greater than rs, and where the ratio of Tmax, the maximum wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, is greater than or equal to 1 , 2, and where the valley is defined by an arched wall that has end points Tm.
    [0011] [011] In a second aspect, the invention provides a suspension stop made of elastomeric thermoplastic material, which comprises: an elongated hollow tubular body that has a wall, where the tubular body has at least two bellows, and each bellows is defined by a peak and a valley, where the peak has a sweetening radius of rs, the valley has a radius sweetening of rc and a wall thickness in the valley of Tc (where Tc is Tmax if Tmax falls substantially in the middle of the valley); where rc is greater than rs, and where the ratio of Tc (Tmax), the wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, is greater than or equal to 1.2.
    [0012] [012] In a third aspect, the invention provides a method for the manufacture of a suspension stop, which comprises the step of: molding an elastomeric thermoplastic material into an elongated hollow tubular body that has a wall, where the tubular body has at least two bellows, each bellows is defined by a peak and a valley, where the peak has a sweetening radius of rs, where the valley has a rc sweetening radius and a maximum valley wall thickness that is at one point in the valley and a designated Tmax; where rc is greater than rs, and where the ratio of Tmax, the maximum wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, is greater than or equal to 1 , 2, and where the valley is defined by the arched wall that has end points Tm.
    [0013] [013] In a fourth aspect, the invention provides a method for the manufacture of a suspension stop, which comprises the step of: molding an elastomeric thermoplastic material into an elongated hollow tubular body that has a wall, where the tubular body has at least two bellows, each bellows is defined by a peak and a valley, the peak has a sweetening radius of rs, the valley it has a sweetening radius of rc and a wall thickness in the valley of Tc (where Tc is Tmax if Tmax falls substantially in the middle of the valley); where rc is greater than rs, and where the ratio of Tc (Tmax), the wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, is greater than or equal to 1.2.
    [0014] [014] In a fifth aspect, the invention provides a method for absorbing shocks in an automobile suspension which comprises using a suspension stop to absorb energy from a displacement of the suspension, wherein the suspension stop is made of an elastomeric thermoplastic material and comprises an elongated hollow tubular body that has a wall, in which the tubular body has at least two bellows, each bellows is defined by a peak and a valley, in which the peak has a sweetening radius of rs, the valley has a sweetening radius of rc and a maximum wall thickness of the valley that is at a point in the valley and a designated Tmax; where rc is greater than rs, and where the ratio of Tmax, the maximum wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, is greater than or equal to 1 , 2, and where the valley is defined by the arched wall that has end points Tm.
    [0015] [015] In a sixth aspect, the invention provides a method for absorbing shocks in an automobile suspension which comprises using a suspension stop to absorb energy from a displacement of the suspension, wherein the suspension stop is made of an elastomeric thermoplastic material and comprises an elongated hollow tubular body that has a wall, in which the tubular body has at least two bellows, each bellows is defined by a peak and a valley, the peak has a sweetening radius of rs, the valley has a radius of sweetening of rc and a wall thickness in the valley of Tc (where Tc is Tmax if Tmax falls substantially in the middle of the valley); where rc is greater than rs, and where the ratio of Tc (Tmax), the wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, is greater than or equal to 1.2. BRIEF DESCRIPTION OF THE DRAWINGS
    [0016] [016] Figure 1 is a schematic broken view of an inward suspension stop, where Re designates the outer radius at a peak, Ri designates the outer radius at a valley, and P represents the distance from peak to peak (the clearance).
    [0017] [017] Figure 2a is an enlarged schematic cross-sectional view of Figure 1, where the dashed line represents the longitudinal geometric axis of the suspension stop, where rs designates the sweetening radius of an outward convolution, and rc designates the radius of sweetening of sweetening in an inward convolution, Ts designates the wall thickness at the peak of an outward convolution, Tc (also Tmax) designates the wall thickness in the valley (inward convolution) in the event that the maximum wall thickness Tmax occurs in the middle of the valley, and Tm designates the intermediate wall thickness at the point of tangency between a circle that has a radius rc and a circle that has a radius rs. The valley is defined by the arched wall that has Tm end points.
    [0018] [018] Figure 2B is an enlarged schematic cross-sectional view of a suspension stop showing the case where circles of radius rs and rc are not tangent. The dashed line represents the longitudinal geometric axis of the suspension stop, rs designates the sweetening radius of an outward convolution, and rc designates the sweetening radius of an inward convolution, Ts designates the wall thickness at the peak of a convolution for outside, Tc (Tmax) designates the wall thickness in the valley (convolution inward) in the event that the maximum wall thickness Tmax occurs in the middle of the valley, and Tm designates the intermediate wall thickness at the midpoint of a line drawn in tangent to both a circle that has a radius rc and a circle that has a radius rs.
    [0019] [019] Figure 3 illustrates a percentage deformation (deflection) (%) on the geometric axis X versus applied force (N) on the geometric axis Y for suspension stops according to the invention, that is, E1 and E2, and a stop comparative suspension, that is, C1. Percentage deformation is defined as the current deformation ratio in mm to the initial height in mm of the suspension stop (after 2 to 4 preconditioning compressions). The curve for E1 is designated with triangles, the curve for E2 is designated with circles and the curve for C1 is designated with diamonds.
    [0020] [020] Figure 4 shows a partially cut-away view of an example of a suspension stop as installed in an automobile suspension. DETAILED DESCRIPTION OF THE INVENTION
    [0021] [021] All documents referred to in this document are incorporated by reference.
    [0022] [022] The inventors found that in a suspension stop made of an elastomeric thermoplastic material, when the ratio of (Tmax / Tm) of the maximum wall thickness in a valley (Tmax) to the wall thickness at an intermediate point between the peak and valley Tm is greater than or equal to 1.2, superior energy absorption is obtained, as measured, for example, by deformation versus applied force. In a preferred embodiment, the maximum wall thickness in the valley occurs substantially in the middle of the valley, in which case Tmax is designated Tc.
    [0023] [023] The inventors found that in a suspension stop made of an elastomeric thermoplastic material, when the ratio (Tc / Tm) of wall thickness in a valley (Tc) to the wall thickness at an intermediate point between the peak and the valley (Tm) is greater than or equal to 1.2, a higher energy absorption is obtained, as measured, for example, by deformation versus applied force. As used in this document, the term superior energy absorption means both a high force along the displacement, that is, at least 550N for 50% relative deformation and, at the same time, a high level of deformation when the force is very high, that is, at least 65% relative deformation in 10 kN. The level of energy absorption can be estimated by the level of force at 50 and / or 60% relative strain and the relative strain at 10 kN.
    [0024] [024] Tc (Tmax) and Tm are often measured for all convolutions in one suspension stop and the average values are taken as Tc (Tmax) and Tm, due to small variations from convolution to convolution.
    [0025] [025] The invention relates to inward suspension stops, which are those in which the peak sweetening radius, rs, is smaller than the valley sweetening radius, rc (ie, rc> rs), as exemplified in Figures 2A and 2B.
    [0026] [026] The principle of the invention can be better understood by examining Figures 1, 2A and 2B. Figure 1 shows a typical inward suspension stop. The same is an article in the form of a hollow tube, which has outward and inward convolutions. The geometry will be defined by a spacing (P) which is the distance from one peak to the next, the external radius at a peak (Re), and the external radius at a valley (Ri). Both Re and Ri are measured from the longitudinal geometric axis of the suspension stop (that is, the imaginary line that passes longitudinally through the center of the suspension stop). The outermost point in an outward convolution is referred to as a peak, and the farthest inward point (regardless of the thickness of the convolutions) is referred to as a valley.
    [0027] [027] Figure 2A shows a widening of bellows that consists of an outward convolution and an inward convolution. The outward convolution (upper) is defined by a radius rs, and the inward convolution (lower) is defined by a radius rc. An inward suspension stop is any suspension stop in which rc is greater than rs. If circles are drawn as having radii rs and rc, the point of tangency of these two circles is an intermediate point on the wall of the suspension stop between a peak and a valley. The wall of the suspension stop, at this point, has a thickness Tm. As shown in Figure 2B, in cases where there is no tangency point between circles rs and rc, Tm is defined as the middle of the tangent segment for the circles rs and rc. A valley is defined by the arched wall that has Tm end points. The maximum wall thickness in the valley is called Tmax. In cases where Tmax occurs substantially in the middle of the valley, Tmax is referred to as Tc. The inventors found that when the ratio (Tmax / Tm) of maximum wall thickness in a valley (Tmax) to the wall thickness at an intermediate point between the peak and the valley (Tm) is greater than or equal to 1.2, a suspension stop is obtained which shows superior energy absorption.
    [0028] [028] In preferred embodiments, Tmax / Tm is greater than 1.3, more preferably, greater than 1.5, for example, 1.62 or 2.03. The upper value of Tmax / Tm is not particularly limited, although in practice it is rare that Tmax / Tm is greater than 10.
    [0029] [029] In all cases where Tmax occurs substantially in the middle of a valley, Tmax can be designated Tc.
    [0030] [030] The suspension stops according to the invention maximize the absorbed energy, as measured by displacement (or formation) versus applied force. In a preferred embodiment, the suspension stops also maximize the displacement achieved for a given applied force, and maximize the displacement at maximum force (that is, when the suspension stop is completely compressed). The displacement at maximum force (maximum compression) is often measured at the force of ten kilo newtons (10 kN) and is referred to as X10KN, for the relative strain X at an applied force of ten kilo newtons. To maximize energy absorption and maximize X10KN, the inventors found that it is desirable not only that Tmax / Tm is greater than or equal to 1.2, but also that the ratio of the maximum wall thickness in a valley, Tmax, to the thickness of wall at the intermediate point, Tm, is greater than a certain value, where the given value depends on the spacing, P, maximum wall thickness in a valley, Tmax, and the external radius in a valley, Ri. This can be expressed by the following combination of features: Tmax / Tm>1.2; and (Tmax / Tm)> (Tmax / Tm) i where (Tmax / Tm) i = 3.43 - 0.05 P - 0.222 SQRT (95 - 4.19 P + 0.05P2–0.23Ri). On what: Tmax is the maximum wall thickness in a valley; Tm is the wall thickness at the point of tangency between a circle of radius rc and a circle of radius rs, or in cases where rs and rc are not tangent, Tm is the wall thickness at the midpoint of a line drawn tangent to the rs and rc circles; SQRT is square root; P is the distance; and Ri is the external radius in a valley.
    [0031] [031] Alternatively, in cases where Tmax occurs substantially in the middle of a valley, this can be expressed: Tc / Tm>1.2; and (Tc / Tm)> (Tc / Tm) i where (Tc / Tm) i = 3.43 - 0.05 P - 0.222 SQRT (95 - 4.19 P + 0.05P2 - 0.23Ri). On what: Tc is the maximum wall thickness in a valley; Tm is the wall thickness at the point of tangency between a circle of radius rc and a circle of radius rs, or in cases where rs and rc are not tangent, Tm is the wall thickness at the midpoint of a line drawn tangent to the rs and rc circles; SQRT is square root; P is the distance; and Ri is the external radius in a valley.
    [0032] [032] The spacing, P, can be constant, which means that the distance from peak to peak (or from valley to valley) is always the same, or it can be non-constant.
    [0033] [033] Preferably, it is constant.
    [0034] [034] For use in automobiles, a typical spacing, P, is between or about 10 and 30mm, more preferably, between or about 13 and 23mm, thicknesses Tc and Tm are typically chosen between or about 2 and 5mm, more preferably, between or about 2 and 4mm, and Ri is typically between or about 10 to 40 mm, more preferably, between or about 15 to 25 mm.
    [0035] [035] The number of convolutions and the average height of the suspension stop can be chosen depending on the size and weight of the vehicle.
    [0036] [036] The suspension stop of the invention can be made of or comprise any thermoplastic elastomer. Preferably, a thermoplastic elastomer that has a relatively high melt viscosity (i.e., a melt flow rate between 0.5 and 8 g / 10m, more preferably between 1 and 8 g / 10m, more preferably , between 2 and 6 g / 10m, more preferably between 3 and 5g / 10m, in particular, preferably 4 g / 10m at 230 ° C under 5 kg load according to ISO1133) is used. Preferably, the elastomer has a hardness between or about 45 and 60D, more preferably, between or about 47 to 55D (at 1 s according to ISO868). Particularly, preferably, the elastomer is a segmented copolyether that has soft segments of polytetramethylene ether glycol (PTMEG).
    [0037] [037] Examples of thermoplastic elastomers useful for the suspension stop of the present invention include those defined in ISO 18064: 2003 (E), such as thermoplastic polyolefinic elastomers (TPO), styrenic thermoplastic elastomers (TPS), thermoplastic polyether polyester or polyester ( TPU), vulcanized thermoplastics (TPV), thermoplastic polyamide block copolymers (TPA), copolyester thermoplastic elastomers (TPC) such as copolyesters or copolyesterester, and mixtures thereof; Suitable materials are thermoplastic polyesters and mixtures thereof.
    [0038] [038] Thermoplastic polyolefin elastomers (TPOs) consist of thermoplastic olefinic polymers, for example, polypropylene or polyethylene, mixed with a thermo adjusted elastomer. A typical TPO is a melt or reactor blend of a polyolefinic plastic, usually a polypropylene polymer, with an olefinic copolymer elastomer, typically a propylene-ethylene (EPR) rubber or an ethylene-propylene-diene rubber ( EPDM). Normal olefin copolymer elastomers include EPR, EPDM, and ethylene copolymers such as ethylene-butene, ethylene-hexene, and ethyleneocene copolymer elastomers (for example, an Engage® polyolefin elastomer, which is commercially available from Dow Chemical Co.) and ethylene-butadiene rubber.
    [0039] [039] Styrene thermoplastic elastomers (TPSs) consist of polystyrene block copolymers and rubberized polymeric materials, for example, polybutadiene, a mixture of hydrogenated polybutadiene and polybutadiene, poly (ethylene-propylene) and hydrogenated polyisoprene. Specific styrene / conjugated diene / styrene block copolymers are block copolymers of SBS, SIS, SIBS, SEBS and SEPS. Such block copolymers are known in the art and are commercially available.
    [0040] [040] Thermoplastic polyurethanes (TPUs) consist of linear segmented block copolymers composed of hard segments comprising a diisocyanate, a short chain glycol and soft segments comprising a diisocyanate and a long chain polyol, as represented by the general formula:
    [0041] [041] Vulcanized thermoplastics (TPVs) consist of a continuous thermoplastic phase with a vulcanized elastomer phase dispersed in it. Both vulcanized and the phrase "vulcanized rubber", as used herein, are intended to be generic to cured or partially cured, crosslinked or crosslinkable rubber as well as curable crosslinked rubber precursors and, therefore, include elastomers, gum rubbers and so-called soft vulcanizers. TPVs combine many desirable characteristics of cross-linked rubbers with some characteristics, such as processability, of thermoplastic elastomers. There are many commercially available TPVs, for example, Santoprene® and Sarlink® (TPVs based on ethylene-propylene-dienoepolypropylene copolymers) that are respectively commercially available from Advanced Elastomer Systems and DSM; Nextrile ™ (TPV with nitrile-polypropylene rubber base) which is commercially available from Thermoplastic Rubber Systems; Zeotherm® (TPV based on acrylate and polyamide elastomer) which is commercially available from Zeon Chemicals; and DuPont ™ ETPV by EI du Pont de Nemours and Company, which is described in International Patent Application Publication No. WO 2004/029155 (thermoplastic blends comprising 15 to 60% by weight of polyalkylene phthalate polyester polymer or copolymer and 40 to 85% by weight of a crosslinkable poly (meth) acrylate or dispersed phase of polyethylene / (meth) acrylate, in which the rubber crosslinked dynamically with a free radical initiator of peroxide and an organic diene coagent).
    [0042] [042] Thermoplastic polyamide block copolymers (TPAs) consist of linear and regular polyamide chain segments and soft flexible polyether or polyester segments or segments with either ether bonds or ester bonds as represented by the general formula
    [0043] [043] Suitable examples of thermoplastic polyamide block copolymers for use in the present invention are commercially available from Arkema or Elf Atochem under the trademark Pebax®.
    [0044] [044] For an excellent balance of grease resistance, durability at high temperature and flexibility at low temperature, the suspension stop according to the present invention can be made of thermoplastic polyester compositions. Preferred thermoplastic polyesters are typically derived from one or more dicarboxylic acids (where, in this document, the term "dicarboxylic acid" also refers to derivatives of dicarboxylic acid such as esters) and one or more diols. In preferred polyesters, dicarboxylic acids comprise one or more of terephthalic acid, isophthalic acid, and 2,6-naphthalenedicarboxylic acid, and the diol component comprises one or more of HO (CH2) nOH (I); 1,4-cyclohexanedimethanol; HO (CH2CH2O) mCH2CH2OH (II); and HO (CH2CH2CH2CH2O) zCH2CH2CH2CH2OH (III), where n is an integer from 2 to 10, m on average is 1 to 4, and z is on average, about 7 to 40. Note that (II) and (III) they can be a mixture of compounds in which m and z, respectively, can vary and which, since m and z are averages, they do not need to be whole numbers. Other dicarboxylic acids that can be used to form the thermoplastic polyester include sebatic and adipic acids. Hydroxycarboxylic acids such as hydroxybenzoic acid can be used as comonomers. Specific preferred polyesters include poly (ethylene terephthalate) (PET), poly (trimethylene terephthalate) (PTT), poly (1,4-butylene terephthalate) (PBT), poly (ethylene 2,6-naphthoate), epoli (1, 4 -cyclohexyldimethylene terephthalate) (PCT).
    [0045] [045] Copolyester thermoplastic elastomers (TPC) such as copolyester esters or copolyesterester are copolymers that have a multiplicity of long-chain ester units and recurring short-chain ester units joined head-to-tail by means of ester, in which said long-chain ester units are represented by formula (A):
    [0046] [046] And the said short chain ester units are represented by the formula (B): ODO- CR C-
    [0047] [047] G is a divalent radical that remains after the removal of hydroxyl groups of terminal poly (alkynene oxide) glycols that preferably have a numerical average molecular weight between about 400 and 6,000; R is a bivalent radical that remains after removal of carboxyl groups from a dicarboxylic acid that has a molecular weight less than about 300; and D is a divalent radical that remains after removal of hydroxyl groups from a diol that has a molecular weight preferably less than about 250; and wherein said copolyesters preferably contain from about 15 to about 99% by weight of short chain ester units and from about 1 to about 85% by weight of long chain ester units.
    [0048] [048] As used herein, the term "long chain ester units" as applied to the unit without a polymer chain and refers to the reaction product of a long chain glycol with a dicarboxylic acid. Suitable long chain glycols are poly (alkynene oxide) glycols which have hydroxy-terminal groups (or as close to the terminal as possible) and which have a numerical average molecular weight of about 400 to 6,000, and preferably about 600 to 3,000. Preferred poly (alkynene oxide) glycols include poly (tetramethylene oxide) glycol, poly (trimethylene oxide) glycol, poly (propylene oxide) glycol, poly (ethylene oxide) glycol, copolymer glycols of these alkylene oxides, and block copolymers such as poly (propylene oxide) glycol treated with ethylene oxide. Mixtures of two or more of these glycols can be used.
    [0049] [049] The term "short chain ester units" as applied to a unit without a polymer chain of copolyethers refers to low molecular weight compounds or polymer chain units. They are done by reacting a low molecular weight diol or a mixture of diols with a dicarboxylic acid to form ester units represented by the formula (B) above. Included among the low molecular weight diols are reacted to form short chain ester units suitable for use to prepare aromatic acyclic, alicyclic and aromatic dihydroxy copolyether esters. Preferred compounds are diols with about 2 to 15 carbon atoms such as ethylene, propylene, isobutylene glycols, tetramethylene, 1,4-pentamethylene, 2,2-dimethyltrimethylene, hexamethylene and decamethylene, dihydroxycyclohexane, cyclohexane dimethanol, resorcinol, hydroquinone , 1,5-dihydroxynaphthalene, and the like. Especially preferred diols are aliphatic diols that contain 2 to 8 carbon atoms, and a more preferred diol is 1,4-butanediol.
    [0050] [050] The copolyesters that have been used advantageously for the manufacture of the suspension stop of the present invention are commercially available copolyester esters from E. I. du Pont de Nemours and Company, Wilmington, Delaware under the trademark Hytrel®.
    [0051] [051] According to a preferred embodiment, the suspension stops according to the present invention are made of thermoplastic copolyester elastomers (TPC) such as copolyetherester or copolyesterester, and mixtures thereof. Most preferably, a copolyester is used which is made from a terephthalic acid ester, for example, dimethyltereftalate, 1-4 butanediol and a poly (tetramethylene ether) glycol. The weight percentage of short-chain ester units is about 50 with the remainder being long-chain ester units. The copolyester ester elastomer has a high melt viscosity with a melt flow rate of about 4 g / 10m at 230 ° C under a load of 5 kg as measured according to ISO1133. Its hardness is about 47D Shore at 1 s as measured according to ISO868.
    [0052] [052] The material used to manufacture the suspension stops according to the present invention can comprise additives that include plasticizers; stabilizers; antioxidants; ultraviolet light absorbers; hydrolytic stabilizers; antistatic agents; dyes or pigments; filling agents, fire retardants; lubricants; reinforcing agents such as fibers, chips or particles of glass; minerals, ceramics, carbon, among others, including nanoscale particles; processing assistants, for example, release agents; and / or mixtures thereof. Suitable levels of these additives and methods of incorporating these additives into polymer compositions are known to those skilled in the art.
    [0053] [053] The suspension stop of the invention can be made of any molding operation or method suitable for molding a thermoplastic elastomer material. Examples of such molding operations and methods include operations that include: injection molding, extrusion (e.g., corrugated extrusion) and blow molding (including blow-extrusion molding and blow-injection molding). Blow molding is particularly preferred because it allows good control over the final geometry of the part and a good balance between the control of the final geometry and the cost of the process.
    [0054] [054] Some dimensions of two examples of suspension stops according to the invention are listed in Table 1 below. Table 1 concerns two suspension stops in which Tmax occurs substantially in the middle of the valley, and then Tmax is designated Tc: TABLE 1
    [0055] [055] Dimensions of two Examples of suspension stops according to the invention.
    [0056] [056] In use, the suspension stop is installed on a vehicle suspension rod between the vehicle chassis and a shock absorber. An example of an installation is shown schematically in Figure 4. In relation to Figure 4, the suspension stop (1) is installed on the shock absorber rod (2), so that a displacement of the shock absorber (3) in the upward direction it results in axial compression of the suspension stop between the shock absorber (3) and the chassis (4). If desired, the suspension stop (1) can be held in position by a suspension support (5). The numeral (6) identifies the terminal of the shock absorber connected to the wheel axle. EXAMPLES
    [0057] [057] The suspension stops according to the invention, E1 and E2, were prepared by blowing a copolyether ester elastomer made from a terephthalic acid ester, for example, dimethyltereftalate, 1-4 butanediol and a poly (ether of ether) tetramethylene) glycol. Both suspension stops E1 and E2 have Tmax substantially in the middle of the valleys, therefore, Tmax is designated Tc). The weight percentage of short chain ester units was about 50 and the rest of the ester units were long chain ester units. The copolyester ester elastomer had a melt flow rate of about 4 g / 10 minutes at 230 ° C under a load of 5 kg according to ISO1133. Its hardness was about 47D Shore at 1 s according to ISO868. A comparative suspension stop C1 was also prepared from this material.
    [0058] [058] The dimensions of the suspension stops are listed in Table 2. The suspension stops according to the invention, E1 and E2, had Tc / Tm> 1.2 (alternatively expressed as Tmax / Tm> 1.2 ), while the suspension stop of comparative example C1, had Tc / Tm = 1.15 (that is, less than 1.2).
    [0059] [059] In addition, the E1 and E2 suspension stops meet the requirements: Tc / Tm>1.2; and (Tc / Tm)> (Tc / Tm) 1 where (Tc / Tm) 1 = 3.43 - 0.05P - 0.222 SQRT (95 - 4.19P + 0.05P2 - 0.23Ri). On what: Tc is the maximum wall thickness in a valley (and is alternatively referred to as Tmax); Tm is the wall thickness at the point of tangency between a circle of radius rc and a circle of radius rs, or in cases where rs and rc are not tangent, Tm is the wall thickness at the midpoint of a line drawn tangent to the rs and rc circles; SQRT is square root; P is the distance; and Ri is the external radius in a valley. TABLE 2
    [0060] [060] Dimensions and compression behavior of suspension stops.
    [0061] [061] Calculation results [ie, calculated values of (Tc / Tm) 1 as compared to Tc / Tm] are shown in Table 3.
    [0062] [062] For suspension stops E1 and E2, Tc / Tm> (Tc / Tm) 1, while for the comparative suspension stop C1, Tc / Tm <(Tc / Tm) 1. TABLE 3 Tc / Tm of suspension stops.
    [0063] [063] A compression response was measured using two isolated bellows. The molded parts were cut in this way to avoid artifacts from the suspension stop terminals. The zero mm reference point was an external point located on the compression machine plate.
    [0064] [064] The molded parts were conditioned by applying 3 compression cycles from 0 to 10 kNa at 50mm / m at 23 ° C. The parts were then released and kept for an hour at a temperature of 23 ° C without stress. The molded parts were then exposed to a fourth compression cycle using the same conditions as the first three cycles. This last cycle defined the static compression curve of the suspension stops.
    [0065] [065] Table 2 lists the force required to provide 50% relative strain (F50), the force required to provide 60% relative strain (F60) and the relative strain when applying 10 kN of force (X10KN). It is evident that the force required to cause 50% relative deformation of the suspension stops according to the invention, that is, E1 and E2, which have Tc / Tm of 1.62 and 2.03, respectively, is substantially greater ( 603N and 775N, respectively) than the force required to cause 50% relative deformation in the comparative suspension stop C1, which has a Tc / Tm of 1.15 (529N). This is also true at 60% relative deformation. The suspension stops E1 and E2 require forces of 1117N and 1362N to cause 60% deformation, while the comparative suspension stop C1 requires only the force of 793N to cause equivalent deformation. The deflection relative to 10 kN, X10KN, is still very high, in fact, above 75%, and similar to that exhibited by the comparative suspension stop C1. This indicates that the suspension stops according to the invention, E1 and E2, are significantly more effective with respect to energy absorption than the comparative suspension stop C1.
    [0066] [066] The results for the comparative suspension stop C1 and inventive suspension stops E1 and E2 are shown graphically in Figure 3, in which a percentage of deflection (%) is plotted on the geometric axis X and an applied force (N) is plotted on the Y geometric axis. Percentage deformation is defined as the current deformation ratio in mm to the initial height in mm of the suspension stop before its first compression. The results for the E1 suspension stop are shown by the curve designated with triangles. The results for the E2 suspension stop are shown by the curve designated with circles. The results for the comparative suspension stop C1 are shown by the curve called diamonds.
    [0067] [067] The area under the curve (% of Force Deflection X) provides a measure of the total energy absorbed. The compression curve for the comparative suspension stop C1 (diamonds) is the smallest curve. The suspension stops according to the invention E1 (triangles) and E2 (circles) provide larger curves, with a larger area below the curve, which shows an increased energy absorption.
    [0068] [068] In addition, it can be seen from Figure 3 that the suspension stops according to the invention E1 and E2 do not significantly sacrifice a maximum displacement. X10KN for E1 and E2 is not significantly less than X10KN for C1.
    权利要求:
    Claims (14)
    [0001]
    SUSPENSION STOP made of copolyester, comprising: an elongated hollow tubular body that has a wall, the tubular body has at least two bellows, each bellows is defined by a peak and a valley, the peak has a sweetening radius of rs, the valley has a sweetening radius of rc and a maximum wall thickness in the Tmax valley; where rc is greater than rs, characterized by the ratio of Tmax, the maximum wall thickness in a valley to Tm, the wall thickness at an intermediate point between the peak and the valley is greater than or equal to 1.2, and where the valley is defined by an arched wall that has end points at intermediate points where the wall thickness is Tm.
    [0002]
    STOP according to claim 1, characterized in that (Tmax / Tm), the ratio of maximum wall thickness in the valley to the wall thickness at an intermediate point, is greater than (Tmax / Tm) 1, where (Tmax / Tm) 1 = 3.43 - 0.05 P - 0.222 SQRT (95 - 4.19 P + 0.05 P2 - 0.23 Ri), on what Tmax is the maximum wall thickness in a valley; Tm is the wall thickness at the midpoint where the midpoint is the point of tangency between a circle of radius rc and a circle of radius rs, or if rs and rc are not tangent, Tm is the wall thickness at the midpoint , where the intermediate point is the midpoint of a line drawn tangent to the circles rs and rc; SQRT is square root; P is the distance; and Ri is the external radius in a valley.
    [0003]
    STOP, according to claim 1, characterized in that the copolyetherester has a melt viscosity between 0.5 and 8 g / 10 minutes, at 230 ° C under a load of 5 kg measured according to ISO1133, and a hardness between or about 45 and 60D measured at 1 s according to ISO868.
    [0004]
    STOP according to claim 2, characterized in that the copolyetherester has a melt viscosity between 0.5 and 8 g / 10 minutes, at 230 ° C under a load of 5 kg measured according to ISO1133, and a hardness between or about 45 and 60D measured at 1 s according to ISO868.
    [0005]
    STOP according to claim 1, characterized in that the copolyetherester has a melt viscosity between 2 and 6 g / 10 minutes, at 230 ° C under a load of 5 kg measured according to ISO1133, and a hardness between or about 45 and 60D measured at 1 s according to ISO868.
    [0006]
    STOP, according to claim 2, characterized in that the copolyetherester has a melt viscosity between 2 and 6 g / 10 minutes, at 230 ° C under a load of 5 kg measured according to ISO1133, and a hardness between or about 45 and 60D measured at 1 s according to ISO868.
    [0007]
    STOP, according to claim 1, characterized in that the copolyetherester has a melt viscosity between 3 and 5 g / 10 minutes, at 230 ° C under a load of 5 kg measured according to ISO1133, and a hardness between or about 45 and 60D measured at 1 s according to ISO868.
    [0008]
    STOP according to claim 2, characterized in that the copolyetherester has a melt viscosity between 3 and 5 g / 10 minutes, at 230 ° C under a load of 5 kg measured according to ISO1133, and a hardness between or about 45 and 60D measured at 1 s according to ISO868.
    [0009]
    STOP, according to claim 1, characterized in that the copolyester esters are copolymers that have a multiplicity of long-chain ester units and recurring short-chain ester units joined head-to-tail by means of ester connections, said long-chain ester units are represented by the formula (A):
    [0010]
    METHOD FOR MANUFACTURING A SUSPENSION STOP, comprising the stage of: mold a copolyester material into an elongated hollow tubular body that has a wall, the tubular body has at least two bellows, each bellows is defined by a peak and a valley, the peak has a sweetening radius of rs, the valley has a sweetening radius of rc and a maximum wall thickness in the Tmax valley; where rc is greater than rs, characterized by the ratio of Tmax, the maximum wall thickness in a valley, for Tm, the wall thickness at an intermediate point between the peak and the valley, being greater than or equal to 1.2 , and where the valley is defined by the arched wall that has end points at the intermediate points where the wall thickness is Tm.
    [0011]
    METHOD, according to claim 10, characterized in that the molding method comprises a molding operation selected from the group consisting of injection molding, extrusion and blow molding.
    [0012]
    METHOD FOR ABSORBING SHOCKS IN A CAR SUSPENSION comprising using a suspension stop to absorb energy from a displacement of the suspension, in which the suspension stop is made of a copolyester material and comprises a hollow elongated tubular body that has a wall , the tubular body has at least two bellows, each bellows is defined by a peak and a valley, the peak has a sweetening radius of rs, the valley has a sweetening radius of rc and a maximum wall thickness in the valley of Tmax ; where rc is greater than rs, characterized by the ratio of Tmax, the thickness of the wall in a valley, for Tm, the thickness of the wall at an intermediate point between the peak and the valley, is greater than or equal to 1.2.
    [0013]
    STOP according to claim 1, characterized in that Tmax occurs substantially in the middle of the valley.
    [0014]
    METHOD, according to claim 10, characterized in that Tmax occurs substantially in the middle of the valley.
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    法律状态:
    2020-06-16| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2021-01-12| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-02-17| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 10/08/2011, OBSERVADAS AS CONDICOES LEGAIS. |
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    US61/372,985|2010-08-12|
    US201161479458P| true| 2011-04-27|2011-04-27|
    US61/479,458|2011-04-27|
    PCT/US2011/047242|WO2012021612A1|2010-08-12|2011-08-10|Thermoplastic jounce bumpers|
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