DE1644951A1 - Power transmission and / or damping fluid - Google Patents

Description

Power transmission and / or damping fluid The invention relates to a power transmission and / or '" Damping fluid, its viscosity under the action of shear forces on and after the cessation of the shear stress returns to its original value. In technology, liquid work media are often used as Constructive elements for the transmission and / or absorption of mechanical energy used. The use of liquids: for these purposes whose rheological properties are due to the Action of sound of mechanical energy on the liquid, 7.13. are not changed by shear stress, ie Newton's.cher fluids, can-due to the non-selective arid close; expensive power transfer; and / or energy absorption to undesired jerky loading of the power transmission Güngselemente or lead to insufficient braking or damping of a movement.

In the journal "Instrument Practice't, May 1967, pages 453-455 is the use of a liquid as a working medium in a damping system described, the viscosity of which moved in it with increasing speed Body increases, i.e. the use of a rheopexic fluid. By means of such a Liquid succeeds in transferring and / or absorbing mechanical energy "softly".

It was found to be liquid. Working media that have a polymer Compound with functional groups that contain hydrogen bonds can train, `are suitable for this.

The subject matter of the invention is thus a power transmission and / or damping fluid, the viscosity of which increases and decreases under the action of shear forces. after quitting the shear stress assumes its original value again, which is characterized in that it contains a polymeric compound or consists of a s = olchen compound that has functional groups that can form hydrogen bonds: According to GC "Pimentel and AZ McClellan in the book "The Hydrogen Bond1 ', page 5, hydrogen bonds come about through the interaction of two functional groups, which belong to the same or different molecules. the one of these groups must be called the Prdtondonator and the: other than Serve proton acceptor. Usually the. Proton of a Carboxyl, hydroxyl, amino or amide group released and from an oxygen atom, which is a carbonyl, ether or hydroxyl group, or before a nitrogen atom of an amino group or an N-heterocyclic compound. Also hydrogen bonded to sulfur or carbon atoms Atoms can participate in the formation of hydrogen bonds participate.-These bonds, however, are generally weaker. Polymeric compounds that have OH and / or NH groups are preferred,. because these groups have strong hydrogen bonds can train. Examples of OH and / or NH groups on Send compounds are carboxylic acids, alcohols, Pheno3, e, Oxme, Arides, amines and pyrroles. . With power transmission and / or damping according to the invention liquids is both the viscosity increase. lower shear = claim Pls also the decrease of the VJ_äkostät after- leave the shear stress time-dependent. The. characteristic of these liquids, under the influence of -shear stress - @: mg progressive. however, more or less quickly becomes more viscous makes it a satisfactory design element with which. mechanical energy can be transmitted rock-free, by a sudden load. Part of the energy from the -Liquid is .absorbed. After the sherds have subsided The viscosity of the liquid is reduced more under stress or. less quickly, so they are again taking for a function Shear stress is ready.

Should the power transmission and / or damping fluid according to the invention used in a power transmission device (e.g. a fluid coupling) it is to be chosen in such a way that it becomes viscous enough to be considered sufficient to act hard coupling element, via which a drive element is a driven one Can set construction element in motion. The progressive increase in toughness leads to a soft force absorption by the ä @ driven element of the power transmission device, even if it is designed so that it can operate at very low speeds of the drive element is set in motion. Such an identifier is in the case of fluid couplings unusual. -In its fully thickened form, the power transmission fluid can to an equivalent of a self-damping coupling member made of E1astomer material e.g. @ of a self-damping rubber coupling member, as the thickened Liquid has self-damping properties that are at least those of rubber are to be equated. By appropriate choice of the composition or the type of force transmission and / or damping fluids according to the invention, e.g. by a polymeric compound solution prepared in the following manner one can choose the working characteristics of: power transmission and / or damping systems change, e.g. the load capacity, speed of a coupling and its maximum load capacity as well as the speed with which it reacts to exposure to the load returns to a state in which they have a jerky load again soft. can accommodate.

Devices for the absorption of mechanical @ energy (e.g. vibration dampers), in which a power transmission and / or damping fluid according to the invention as Working medium can be used are designed so that through the inclusion 'of kinetic energy through the device. The working medium stressed on shear will. The damping effect of such a device, i.e. the amount of longitudinal a certain path of the working element of the device in the shear stressed Mechanical energy converted into heat increases with the increase the viscosity of the liquid. The absorbed by the device is reduced mechanical performance - or if it stops at all, viscosity also increases corresponding to the power transmission and / or damping fluid according to the invention and after the shear stress has ceased, it reaches the original one again Value. Accordingly, the amount <= that absorbed in the unit of time will also be mechanical energy smaller: sawn short, a damping fastener, the one according to the invention Contains power transmission and / or damping fluid as the working medium harder with increasing use and softer again with decreasing use.

A power transmission and / or damping fluid according to the invention thus offers the advantage that it simplifies the construction of power transmission or damping devices made possible by design elements that are used to change the Damping hardness or the coupling strength according to the respective requirements serve, can be simplified or omitted entirely.

The increase in viscosity according to the invention power transmission and / or Damping fluids in the case of shear stress is temperature-dependent - in such a way, that solidification occurs at higher temperatures. the liquid only at higher Shear stress sets in than at lower temperatures. Because of this behavior power transmission and / or damping fluids according to the invention becomes the risk a destruction of device parts as a result of eating see the above liquid working medium coupled moving device part reduced. If If one of these parts eats, this increases the temperature of the liquid working medium as a result of it. absorbed and Zn thermal energy converted mechanical energy. The viscosity then decreases due to this increase in temperature, see above. that the coupling strength between the device positions is reduced.

An inventive power transmission and / or Dämpfüngsflüssigkeit may, as already mentioned, composed of a polymeric compound or a solution to be such a polymeric compound in an appropriate carrier liquid rather, such a solution: an oil-soluble polymer in a 01, which is a mineral oil, a synthetic or a. vegetable oil can be. The specific effect of the polymer contained in the solution is presumably based on the fact that spherical polymer balls be stretched to ellipsoids by the .shear stress field. There- by increasing the number of intermolecular hydrogen. kenbindüngen at the expense of the intramolecular hydrogen bond bonds, whereby chain adhesions take place. The polymeric compounds of the power transmission according to the invention and / or damping fluids can be homopolymers, e.g. an homopolymer of 9-hydroxy-octadecyl methacrylate, ' however, copolymers are preferred, in particular a mixed polymer made from monomers with a polymerizable Ethylenic double bond is produced: Particularly preferred are copolymers of esters of unsaturated carboxylic acids, in particular of esters of unsaturated monocarboxylic acids, which if desired with conomers not falling under this group can be copolymerized. Examples of inventive power transmission and / or More suitable shock absorption fluids, mixed polymers are mixed Poly.iierisate of one or more methacrylic acid esters long- chain alcohols (e.g. lauryl methacrylate and / or ste: aryl - methacrylate) and 1-vinyl-2'-pyrrolidone. Mixing polymers containing free hydroxyl groups-. Examples of such polymeric compounds are polymers; the through copolymerization of alkyl esters of unsaturated acids with unsaturated acids, such as acrylic acid, methacrylic acid ,. Croton acid, maleic acid or fumaric acid. Particularly mixed polymers of alkyl esters of unsaturated honey are preferred carboxylic acids with unsaturated monocarboxylic acids. - Other suitable polymeric compounds are obtained, for example, by copolymerization of esters of unsaturated carbonic acids (preferably esters of unsaturated conocarboxylic acids), of which at least one contains one or more hydroxyl groups in the molecule, it being advantageous if one or more of the called hydroxyl groups sit in the part of the molecule that is derived from the alcohol. Examples of polymeric compounds for power transmission according to the invention. and / or damping fluids are particularly suitable, are the reaction products of ethylene oxide with copolymers of unsaturated monocarboxylic acids with alkyl esters of unsaturated monocarboxylic acids and in particular the reaction product of ethyl oxide with copolymers of methacrylic acid, zauryl methacrylate and stearyl methacrylate Whether or not these reaction products contain unreacted carboxyl groups, they can also contain any other known method, e.g. by direct mixed polymexization of alkyls of unsaturated acids with hydroxyl groups, the esters of unsaturated carboxylic acids and if desired, unsaturated carboxylic acids should be prepared.

As already mentioned, a force transmission and / or damping liquid according to the invention can be a solution of the polymeric compound. Particularly expediently, according to the invention, power transmission and / or damping fluids consist of a solution of the polymeric compound in a mineral lubricating oil: Any mineral lubricating oil can be used. Lubrication of metal surfaces suitable known hydrocarbon oil, zaH. a refined petroleum product. Hydrocarbon oils with a viscosity which lies in the range specified in the SAE "Crank Case Oil Classification" are preferred, i.e. oils which have a viscosity of 4 - 25 cSt at 100 ° C. If necessary, the lubricating oil can contain one or more known lubricating oil additives, for example: pour point depressants, oxidation inhibitors, metal deactivators, rust-preventing agents and anti-foaming agents. If desired, mixtures of mineral lubricating oils with synthetic or vegetable oils can also be used.

As already mentioned above: dP Bc-Ij # .. z + ungcharacteristics of power transmission and / or damping fluids according to the invention can be changed by changing the composition or the type of the fluid. This can be done using all or only some of the means available for this purpose, e.g. by changing the content of the polymeric compound dissolved in the carrier liquid, by using a different polymeric compound, by the molecular weight of the polymeric compound used or by the type the carrier liquid used as a solvent for the polymeric compound. The content of a polymeric compound dissolved in the carrier fluid in a power transmission and / or damping fluid according to the invention is to be adapted to the particular requirements given by a specific application. In general, 1 to 45% by weight, preferably 5 to 25% by weight, of the polymeric compound are dissolved in the carrier liquid. The power transmission and / or damping fluids according to the invention, which can be used in a very wide range of operating conditions, can be obtained by using as the polymeric compound a polymer of: three different methacrylic acid esters, in particular a copolymer of two different alkyl methacrylates and a hydroxyalkyl methacrylate, which contains the individual monomers in suitably chosen molar ratios - and by choosing a suitable concentration of the copolymer in a carrier liquid which contains a mineral lubricating oil. Examples of such copolymers dissolved in a mineral lubricating oil with a viscosity of at least 4 cSt. At 98.9 ° C, suitable power transmission and / or damping fluids according to the invention result in copolymers of lauryl methacrylate, stearyl methacrylate and hydroxyethyl methacrylate in molar ratios of 5: 5: 3 or 5. 5: 4 or 7: 3: 2.7. In general it can be said that the. The higher the concentration of the copolymer in the lubricating oil, the greater the increase in viscosity at a certain shear stress. For some areas of application it is advantageous to expand the adaptability of power transmission and / or damping devices which contain a power transmission and / or damping fluid according to the invention as a working medium by designing the mechanical part of the device in such a way that- the visual stress to which the work medium is exposed can be adjusted.

Examples of power transmission and / or damping devices in which power transmission and / or damping fluids according to the invention can be used as the working medium Fluid coupling system; - Shock absorber -; .- _ .Suspension systems; . Transmission:;- . ' @ Yibrationsdämpfungssyst-eme; - _-Speed controller #, Braking systems; Referring to the drawings, examples of Power transmission and / or damping devices in which power transmission and / or damping fluid according to the invention can be used as a working medium, three devices activities described: each one sitting on a shaft Have rotor, which is surrounded by the working medium - is. Fig. 1 is a section through a fluid coupling along a ner plane through the center line-of the shaft. FIG. 2 is a view of the coupling shown in FIG. 1 in FIG - 'Direction of the wave.' FIG. 3 shows a section in a manner analogous to that in FIG Fluid coupling of the type shown in Fig. 1, but which is so constructed. that the shear stress dea ", 4-rbeitgme-. diums can be regulated; Fig. 4 shows a shock absorber in section in. One through the. Middle of the wave going level: The fluid coupling according to FIGS. 1 and 2 consists of a housing 1, which forms the output part of the coupling, and a shaft 7, which belongs to the drive part of the coupling. The housing 1 consists of two parts which are held together by screws 2 which are provided with threads at both ends and on which nuts 3 sit. The housing 1 surrounds a working space 4, in which as. Working medium is a solution of a copolymer in a mineral oil.

The mineral solution used as the working medium contains sample prices 20 wt;% Eir @ cßi mixed polymer, däs Iiaurylmethacry-, lat-, Stearylmethacrylat- and Hydroxyäthylmethacrylateinhciten.-in a molar ratio of 5: 5 @@ 3 Contains. @ - The housing 1 has a closed with a screw plug 5. Drain opening on. In the working space 4 there is a cylindrical one fastened on the shaft 7 Rotor 6, which is surrounded by the working medium: The shaft 7 extends through the two end parts of the housing 1 designed as hubs 8, in which they can be rotated is stored. The play between the shaft 7 and the hubs 8 must be small enough., in order to; prevent loss of working medium. -The fluid coupling is working as follows: If the shaft 7 is set in rotation, it will of course open up her fixed rotor 6 with. The rotating rotor 6 shears the working medium, which becomes tougher as a result. The increase in the viscosity of the liquid working medium can become so strong that it becomes a driving link between the rotor 6 uX: d the housing 1 becomes. That way with the rotor 6 coupled Housing 1 is then set in rotation. If desired, of course, drive and output side of the device are swapped, i.e. that the drive on the housing 1 takes place, in which case the liquid working medium and via the on Her- attached rotor 6 shaft 7 connected to it in a non-positive manner is taken along.

The in fig. 3-illustrated coupling consists “also essentially” of a housing -1 as an output-side construction element and. a shaft 7 with a rotor 6 attached to it as a drive-side structural element. In contrast to the coupling shown in FIG. 1, one of the two inner end faces of the housing 1 is conical in the coupling shown in FIG. This conical inner surface 21 of the housing 1 lies. a correspondingly designed conical outer surface 22 of the rotor @ 6 opposite. The shaft 7 is provided with a setting device 29 by means of which: it can be displaced against the housing 1 along the shaft axis together with the rotor 6 fastened on it.

By moving the: rotor 6 against the housing 1, the Gap between the inner conical surface 21 des.Gehäuses 1 and the outer conical Area 22 of the rotor 6 is enlarged or increased according to the respective requirements can be reduced in size. This is for a certain speed difference between the housing 1 and the rotor 6 the shear stress of the working medium, which located in gap 4, so that the hardness of the coupling between the Housing 1 and the rotor 6 or the shaft 7 for a given speed difference between: these two parts of the device and given liquid Working medium (power transmission and / or damping fluid according to the invention) with a fluid coupling according to FIG. 3 can be adjusted.

As with the device according to FIG. also with the fluid coupling According to Fig. "3, the drive and output sides can be interchanged if desired.

The shock absorber shown in Fig. 4 of the drawing consists of a housing 30 surrounding a working space 40, one. Shaft 31, which is a rotor 32 carries, as well as a stator 33 as essential structural elements. the Shaft 31 extends through one side of the housing 1 into the working space 4: 0 and is mounted in the housing 1 by means of the roller bearings 39.

The rotor 32, which has a flat end face 34, sits on the end of the shaft 31 extending into the working space 40. The stator 33 has a flat end face 35 opposite the end face 34 of the rotor 32 and is arranged so that its central axis with the shaft 31 is aligned. It has an externally threaded guide and fastening bolt 36 , which is screwed into a rotatably arranged end cap 37 which is provided with an internally threaded end and is arranged on the end face of the housing 30 opposite the bearings 39. Between the end face 34 of the rotor 32 and the end face 35 of the stator 33 there is a working gap 38 which is filled by a liquid working medium, ie a power transmission and / or damping liquid according to the invention. By setting on the final cap. 37-- kjnn .the stator 35 on the. Rotor 32 to -or. from the ro- gate.-3.2 way. be-iregtg dhä the working gap 38 can be enlarged or reduces ornaments, whereby at a given speed difference between the rotor 32 and the stator 33 the shear stress Sprüchung des: '- Arbeztsmediuin (I force transfer according to the invention action; s --- and / or T damping liquid) larger or smaller will: _ _

Claims (4)

P a t e n t demands 1. Power transmission and / or damping fluid, their viscosity, kbsität under the action of shear forces and after cessation the excessive stress assumes its original value again, as marked by Evidence that it contains or consists of a polymeric compound consists, which has functional groups that form hydrogen bonds can. 2. power transmission and / or damping fluid according to claim 1, characterized characterized in that the polymeric compound has OH and / or NH groups. 3. Power transmission and / or damping fluid according to Claims 1 and 2, characterized characterized in that the polymeric compound consists of compounds with polymerizable Ä.thylendoppelüin boys is made. 4. power transmission and / or damping fluid according to claim 1 to 3, characterized in that it contains the polymeric compound dissolved in a carrier fluid. 5. Power transmission: - and / or damping fluid after Claim 1 to 4 characterized in that the. polymers Compound a copolymer of esters -unsaturated Monocarboxylic acids, where at least one ester is one or has several hydroxyl groups. Power transmission and / or damping fluid according to Claim 1 to 4-, characterized in that the polymer Compound a copolymer of unsaturated monocarbon. acids and alkyl esters of unsaturated monocarboxylic acids. 7. Power transmission and / or damping fluid according to Claim l to 4, characterized in that the polymers. Compound a reaction product of ethylene oxide with one. Copolymer of unsaturated conocarboxylic acids and alkyl is entern unsaturated monocarboxylic acids. B. power transmission and / or damping fluid Claim 7, characterized in that: that the polymeric bond a reaction product of Äthylenoxycmit a Mschpolyrierisat of lauryl methacrylate, stearyl methacrylate and is methacrylic acid. fl power transmission and / or damping fluid Claim 1 to 5, characterized in that the polygere Compound an optionally reacted with ethylene oxide Copolymer of lauryl methacrylate, stearyl methacrylate and is hydroxyethyl methacrylate. 10. Power transmission and / or damping fluid according to. Claim 9, characterized in that the molar ratio from lauryl to stearyl to hydroethyl methacrylate in the Copolymer is 5: 5: 3. 11. Power transmission and / or dampening fluid Claim 9, characterized in that the molar ratio of Zauryl to stearyl to hydroxyethyl methacrylate in mixed poly merisat 5 is 5: 4, 12. Power transmission and / or damping fluid according to Claim 9, characterized in that "the molar ratio of Zauryl to steryl to hydroxyethyl methacrylate in the M - '. Sc, hpoly- merisat 7 ': 3: 2.7 is. . 1_3. Force transmission and / or damping capacity according to any one of claims 1 to 12, characterized in that it Contains 1 to 45 percent by weight of the polymeric compound.