FR2480374A1 - FIXING MEANS SUPPORTING A LOAD AND ABSORBING SHOCKS AND VIBRATIONS - Google Patents

Abstract

THE INVENTION CONCERNS A LOAD-SUPPORTING FIXING MEANS AND ABSORBING SHOCKS AND VIBRATIONS. ACCORDING TO THE INVENTION, IT INCLUDES AN EYE BOLT 20 HAVING AN EYE PORTION, AND A BOLT 26 FIXED TO THE ROD AT ITS END DISTAL TO THE EYE, TO ALLOW THE ATTACHMENT OF THE EYE BOLT TO A SUPPORT STRUCTURE ; AN ANNULAR SHOCK AND VIBRATION ABSORBING BODY 30 MOUNTS INTO THE BORE; AND A MEANS FOR SECURING THE BODY IN THE BORE. THE INVENTION APPLIES IN PARTICULAR TO AIRCRAFT STRUCTURES.

Description

The present invention relates to shocks insulators and

  vibrations, used to connect

  components together, and it relates more particularly

  to such devices which provide a restraint, with isolation, between the components connected together relative to a relative movement in a selected plane while allowing a relative movement perpendicularly

at this level.

  Shock and vibration isolators are well known and widely used. In particular, such insulators elastically connect two components together, forming in fact a mechanical oscillator tuned to oscillate at a frequency lower than that of the vibrations to be attenuated by an amount depending on the desired attenuation. The tuning of the mechanical oscillator is accomplished by varying the strength of the insulator; the stiffer the insulator, the higher the tuned frequency. The stiffness of an insulator depends, in turn, not only on the elasticity of the building material of this insulator, but also on the dimensions (and, in the case of a solenoid with damping, the

  amount of deflection or deformation) of the insulator.

  The dimensions and the arrangement of the elastic material can be modified, so as to modify the

  amount of stiffness and therefore the degree of attenuation

  in each direction and isolators o are

  incorporated these features are well known.

  A particular problem arises when an insulator must provide restraint in all directions except a selected direction, while allowing free relative movement of the coupled components in this preferred direction. Such an insulator is required, for example, when a component that is subjected to thermal expansion must be mounted and fully retained by more than one insulator. While one or more of the insulators

  used in such an application may be

  such an attempt results in insulators that may not provide adequate restraint in other directions, with moreover less than optimal damping, particularly in terms of thermal expansion. concerning vibration excursions, parallel-

  line or lines joining the insulators.

  Such insulators generally also have

  asymmetric attenuation properties not desired.

  In another attempt, which found wide application in mounting aircraft turbines, the components were secured together by two insulators, one providing restraint in all directions and the other providing restraint in all directions to

  except for a direction parallel to the first.

  To achieve this, the second insulator is manufactured in the form of two concentric cylinders free to rotate relative to each other, and yet retained both axially and radially by elastic buffers. This insulator is fixed firmly by one of the two cylinders to one of the two components to be connected so that the axes of the concentric cylinders are in a plane which is substantially perpendicular to the direction of anticipated thermal growth (this is that is, in a plane perpendicular to the direction of the first isolator). The free cylinder of the insulator is attached eccentrically by a suitable universal coupling to the remaining component. A difference in expansion between the components is imparted to the insulator in the form of a rotation difference of one

cylinder relative to each other.

  Although this type of insulator is widely used, however, it has drawbacks. Clearly, the relative amount of linear motion liberated is limited, particularly if precise angular alignment of the components is to be maintained. By the way, the required eccentric fitting of a component, in order to get the torque to convert linear motion into motion

  of rotation, produces an arm of leverage by which

  Loads seen by the insulator are magnified. So again, in applications requiring the isolator

  mounted so that the axes of the cylinders

  vertical, this eccentric arrangement ensures an unequal load of the elastic components of the insulator by acting cantilever. This asymmetrical load of the insulator must be compensated by an asymmetrical stiffening of the elastic elements, with; as a result, an asymmetrical change in attenuation and damping properties. Finally, it should be noted that such insulators are relatively complex, requiring the

  manufacture and assembly of a number of parts.

  Accordingly, an object of the present invention is an insulator which provides an isolating restraint between two components connected together by means of this insulator with respect to a relative movement in a selected plane, while allowing free relative movement perpendicular to this plan. Moreover, the present invention relates to such insulators where the possibility of free relative movement in a preferred direction is not accompanied by adverse effects of the performance of the insulator. More particularly, the present invention relates to such an insulator where the possibility of free relative movement in a preferred direction is achieved without adjustment of the stiffness, and hence the attenuation properties, of the insulator in any other direction. On the other hand, the subject of the present invention is an insulator where the free relative movement in a preferred direction can be relatively unlimited over its extent, and can be accomplished

  without changing the orientation of the two components.

  The present invention furthermore for another object such an insulator which is less complex, has little

  parts, and is easy to manufacture and assemble.

  These and other objects are achieved according to the present invention by a shock-absorbing fastening means which is preferably in the form of a threaded-ring ring, the ring portion of the fastening means being provided with a fastener part. resilient, shock and vibration absorbing annular insert having a tubular core with a cylindrical and smooth inner surface. This securing means may be rigidly attached to one of the two components to be joined to each other by the bolt portion, the ring portion being disposed so that the tubular core is aligned parallel to the desired direction of relative movement. free. The fastening means is joined to the other of the two components by a cylindrical rod, dimensioned to regularly and slidably fit into the tubular core, being rigidly attached to the other component in this arrangement to be coaxial

with the soul.

  Note that the freedom of the cylindrical rod and the soul to move relative to each other in the axial direction allows free relative movement between the two components thus connected to each other. At the same time, a relative movement between the two components in any other direction will radially compress the annular shock absorbing insert separating

  the core of the annular portion of the plug ring.

  As a result, the securing means provides restraint relative to a relative movement, together with shock and vibration isolation, in the plane of the annular insert, while permitting

  relative free movement perpendicular to this plane.

  Moreover, since the free relative movement is axial while the retaining forces of the annular insertion piece are radial, there is no torque between the free movement and the attenuated movement, and consequently the possibility of movement free does not place any restraint on the attenuation properties of the isolator. It will also be noted that the insulator according to the invention undergoes linear motion centrally and 5.

  not eccentrically, and therefore the relationship-

  angle between the components can be maintained despite

  the excursion in the non-restrained direction. This configuration

  It also ensures that the amplified and cantilevered loads will not be intrinsically applied to the elastic member. Moreover, it will be understood that the extent of free relative motion is limited only by the extent

  of the cylindrical rod passing through the insulator.

  The invention will be better understood, and other purposes, features, details and advantages thereof

  will appear more clearly during the description

  explanatory text which will follow with reference to the accompanying schematic drawings given solely by way of example illustrating an embodiment of the invention and in which: - Figure 1 is a view of a preferred form of an insulator made according to the principles of the present invention; FIG. 2 is a cross-sectional view of the insulator of FIG. 1 taken along line 2-2; and FIG. 3 is a view, partially in section, in the same direction as FIG. 2, showing the isolator

joining two components.

  In all the figures, identical markers

  designate identical components.

  Referring to FIGS. 1 and 2, there can be seen a vibration isolator, made in accordance with the principles of the present invention, which, in a preferred embodiment, comprises a cone shaped eye ring or bolt. 20, an elastic and annular member 30, and a tubular Ms. 32. In a preferred embodiment for a connection between a pylohe structure of a jet aircraft and a motor assembly T5, all the components are made of metal, as steel, the bolt 20 and the core 32 being made of hardened steel and the elastic element 30 being made of a compressed steel mesh. It will be understood, however, that the present invention has other applications and therefore other materials may be employed in vibration isolators made according to the principles of the invention, provided that the materials possess the requisite mechanical properties. that is, strength and rigidity in the case of bolt 20 and core 32 and elasticity in the case of elastic member 30) for the intended application. Thus, for example, the bolt 20 and the core 32 could be aluminum, bronze or even

  polymers such as polycarbonate, polyisulfide

  phenylene and the like, while the elastic member 30 could be a natural or synthetic elastomer or

felt or cork.

  The bolt 20 consists of the eye portion or ring 22, a stem portion 24, and a bolt portion 26. In a preferred embodiment, the portion 22 has the general shape of a a straight and hollow circular cylinder having an axial extent somewhat smaller or equal to its outer diameter, although it can be understood that other dimensional ratios are possible. The stem portion 24 extends radially from a midpoint on the outer surface of the

  eye portion 22, over a selected main distance-

  based on the desired separation between the components to be joined to each other by the insulator. In a preferred embodiment, the portion 24 is substantially in the shape of a right circular cone frustum, whose wider base has a diameter of the order of the axial extent of the ring portion 22. Coaxial to the the stem portion 24 and extending from its distal end relative to the ring portion 22, is the bolt portion 26. In a preferred embodiment, the bolt portion 26 is threaded and its diameter is substantially identical to that of the base of smaller diameter of the conical rod 24. Preferably, the eye or ring, rod and bolt 22, 24 and 26 are made in one piece, although it is understood that they could be made separately and then assembled. The dimensions of these various parts of the eye bolt 20 are established by means well known in mechanical techniques, considering inter alia, the size of the load to be supported and the

  resistance of the building material.

  The recess in the portion 22 is in the form of a substantially concentric cylindrical bore therethrough, the major portion of which is delimited by the cylindrical surface 27, as can be seen by referring to FIG. 2. Over a short axial distance at each end of the bore, the diameter of the inner surface of the portion 22 is somewhat smaller than that of the outer surface 27, thereby forming flanges

  internal radials 28. The dimensions of the cylindrical surface

  27 and 28 flanges are established mainly considering the use of the insulator, as it is

will describe below.

  In the bore of the portion 22 defined by the cylindrical surface 27 fits tightly an annular elastic member 30, which is held captive against movement parallel to the axis of the cylindrical surface by the inner radial flanges 28. A To this end, the annular elastic element 30 is sized to have the same axial extent as the separation between the internal radial flanges 28 of the part 22, and the same

  external diameter than that of the cylindrical surface 27.

  The radial thickness of the annular elastic member 30 is established, inter alia, by the desired attenuation properties of the insulator, as those skilled in the art will be able to understand. In designing the insulator, it should be noted that the maximum radial deformation or deformation of a segment of the elastic element 30 is smaller than the radial thickness of the elastic element of at least the sum of the radial dimensions of the elastic element. flange 28 (on the part 22) and the flange 34 (on the core 32 which will be described below). As previously mentioned, the annular elastic member 30 preferably consists of a compressed metal mesh (such members are known in the art of shock and vibration insulators and are described, for example, in U.S. Patent No. 3,073,557), although other

  materials may be useful in some applications.

  The elastic and annular element 30 can be manufactured either in one piece or, as illustrated in FIG. 1, in the form of an assembly of a number

  of individual annular and elastic sectors 31.

  While the illustrated multi-sector annular elastic member is formed of six elastic annular sectors of equal size 31, the number of individual sectors used to form the complete ring, and the annular extent of each sector, can obviously be modified if desired. Furthermore, it will be understood that the annular and resilient sectors should not be angularly dimensioned to fit into a complete ring, but they can be designed to leave circumferential gaps if desired. Such modifications make it possible to design insulators that can have properties

  isolation variables in different radial directions

  rents, or capable of supporting a large load in a preferred radial direction while having substantially uniform insulation properties in all

the radial directions.

  In the elastic and annular member 30 is concentrically placed the core 32. The core 32 has substantially the shape of a circular and straight cylindrical tube sized to fit very tightly in the annular resilient member 30 and pass through. The axially extending core 32 corresponds to the portion 22. Each end of the core 32 is provided with an outer radial flange 34 arranged to substantially face the corresponding inner radial flanges 28 in a fully assembled bolt 20. In a preferred embodiment, the core 32 is provided with a sleeve 36, in the form of a circular and straight cylindrical tube whose diameter corresponds to the internal diameter of the core 32 and whose axial length corresponds to that of blade. The sleeve 36 is concentrically disposed in the core 32. The sleeve 36, which is optional, forms a bearing surface. Therefore, if it is used, the sleeve 36 is manufactured in

  a suitable material with a low coefficient of friction.

  With regard to the assembly of the insulator, it will be noted that the method of assembling the annular elastic element 30 and the core 32 in the part 22 depends on the nature of the elastic element 30. Thus, if the annular elastic member 30 is a unitary body, it may be preassembled to the core 32 by stretching or forming it around the core, and then this subassembly may be forced, by compression of the elastic element, inside

  boring of Part 22. Moreover, and in particular

  in the case where the annular elastic element 30 is composed of a number of elastic sectors 31, the assembly can be very easily accomplished by first assembling the annular elastic element in

  the bore of the part 22 and then fixing thereafter the core 32.

  It will also be noted that an annular elastic element

  lastomer can be molded on site.

  While the flanges 28 and 34 serve to secure the annular elastic member 30 in the portion 22, and the core 32 in the annular elastic member, the flanges may also serve to maintain the annular elastic member 30 in axial compression. This may be desirable in some types of insulators and for some manufacturing processes. For example, the elastic member 30 may be formed by the axial compression of a metal mesh tubular sole having an initial axial extent greater than that of the portion 22 and subsequently further compressed and maintained under compression by one or the other. other (or both) groups of flanges. Referring now to Figure 3, there can be seen solenoid made according to the invention, joining two components 38 and 40. For example, the component 38 may be a jet engine mounting ring and the component 40 can be the pylon structure of a jet plane. Component 38 has amounts 42 that

  have aligned holes for receiving a threaded bolt 44.

  The posts 42 support the bolt 44 parallel to the desired direction of free relative movement between the components. The bolt 44 is sized to fit slidably through the sleeve 36, and is secured by a nut 46. It will be appreciated that a given insulator may be adapted to match bolts 44 of different diameters by appropriately changing The uprights 42 are sized to support the bolt 44 to form a clearance between the ring portion 22 and the component 38 when the bolt 20 is attached to the component by the uprights 42 and the bolt 44. The studs are spaced apart. a greater distance than the desired relative amount of movement between the components 38 and 40, in addition to the axial extent of the portion 22. Faced with the location of the bolt 44, the component 40 is provided with an opening 47 configured to conform to the stem portion 24 and the bolt portion 26 of the ring bolt. The aperture 47 has an axis that is substantially perpendicular to the desired direction of free relative motion and is dimensioned such that when the bolt 20 rests securely in the aperture, a clearance is maintained between the components 38 and 40 over any the relative displacement movement between the components If the relative free movement possible between the components 38 and 40 is a preferential movement from an initial relationship between the components, the arrangement of the uprights 42 and the opening 47 will be such that at the initial condition, the portion 22 of the bolt 20 will be moved along the bolt 44 to the amount 42 opposite the preferential movement by an appropriate amount. Otherwise, the arrangement of the posts and the opening will normally be such that the ring portion is centered. The bolt is attached to the component 40 by the nut 48 on the part

forming bolt 26.

  In use, the sliding fit between the sleeve 36 and the bolt 44 allows free relative movement between the components 38 and 40 axially along the bolt 44 between the contact points of the ring portion 22 and the posts 42. Relative linear lines between the components perpendicular to the possible movement are seen as displacement -radial compression by the annular elastic member 30. Among the degrees of freedom of rotation between the components, only those around axes orthogonal to the axis of the bolt 44 will impose loads on the insulator, as long as the bolt 44 and the bolt 20 are free to rotate relative to each other about this last axis. In normal installations, an additional insulator, remote from the bolt 20, will restrict the relative rotational movement of the components 38 and 40 about normal axes to the axis of the bolt 44. Thus, it can be seen that in normal installations the isolator does not see moments that may tend to either amplify the load on the insulator or cause an irregular load - Note that various modifications may be

  without departing significantly from the scope of the invention.

  tion. Thus, for example, while the conical shape of the stem portion 24 facilitates the precise and stable placement of the insulator with respect to the component 40, this rod can be manufactured in a cylinder or other suitable form, for example, of - whether its cross section is square, rectangular, or triangular; furthermore, it may also be wedged to facilitate the orientation of the resilient annular member 30. It may also be noted that in some cases the axes of the stem portion 24 and the bolt portion 26 may be more advantageously established at an angle other than being substantially

  perpendicular to the axis of the elastic annular element 3A.

  On the other hand, it is envisaged that the bolt portion 26 and the shank portion 24 may have the same shape in cross-section and / or the same maximum dimension. In another possible modification, the non-threaded bolt portion 26 but connected to the component 40 is used in another way, for example by welding or by an adhesive or by C-shaped locking rings. The invention is in no way limited to the embodiment described and shown which has been given by way of example only. In particular, it includes all means constituting technical equivalents

  described means as well as their combinations if these

  These are executed according to his spirit and implemented

  as part of the protection as claimed.

Claims (10)

R E V E N D I C A T I 0 N S   1. A load-bearing and shock and vibration-absorbing fastening means, characterized in that it comprises: an eye bolt (20) comprising an eye portion (22) through which a bore passes, a portion forming an elongate shaft (24) extending from said eye portion and a bolt portion (26) attached to said shaft portion at the distal end relative to said eye portion to permit attachment of said eye bolt to a support structure; an annular shock and vibration absorbing body (30) mounted in said bore; and   means for securing said body in said bore.   2. - Fastening means according to claim 1, characterized in that the aforementioned rod portion (24) has substantially the shape of a right circular cone truncated having a maximum diameter substantially equal to the maximum dimension of the eye portion aforementioned, and a minimum diameter substantially equal to that of the bolt part mentioned above.   3. A fixing means according to claim 2, characterized in that said eye portion (22) has an axial extent and an outer diameter which are   substantially equal to each other.   4. Fastening means according to claim 1, characterized in that it further comprises a concentric tubular core (32) and inside the aforementioned body   absorbing shocks and vibrations.   5. Fastening means according to claim 4, characterized in that the core (32) above is fixed in the aforementioned body by two radial outer flanges (34).   attached to said Soul and located at opposite ends thereof.   6. Fastening means according to claim 1, characterized in that the aforementioned means for fixing the aforementioned body in the aforesaid bore comprises two internal radial flanges (28) attached to the eye portion   above and located at opposite ends of said bore.   7. Fastening means according to claim 1, characterized in that the aforementioned annular body absorbing shocks and vibrations consists of a mesh in compressed metal.   8. Fastening means according to claim 1, characterized in that the aforementioned annular body is composed of   of a number of elastic annular sectors.   9.- shock and vibration absorbing means for interconnecting a mounting ring on an aircraft turbine with a motor pylon structure of said aircraft, characterized in that it comprises: an eye bolt (20) having a an eye portion (22) having a bore therethrough, an elongate shaft portion (24) extending radially from said eye portion and a threaded bolt portion (26), said shaft being substantially in the form of a a straight and truncated circular needle tapering from said eye to said threaded bolt portion, said threaded bolt portion being axially attached to said shank, at the distal end relative to said eye, to allow attachment of said bolt to eye to said structure; an annular shock and vibration absorbing body (30) composed of a compressed metal mesh inserted into said bore; and a tubular core (32) concentric with, and within, the shock and vibration absorbing body, said core being further provided with an inner surface of a substantially smooth finish; said core being adapted to receive a mounting bolt (44) for slidingly attaching said securing means to said mounting ring to allow free relative movement between said mounting ring and said pylon structure in a direction parallel to the axis said mounting bolt while providing a resilient btenoe to relative movements between said mounting ring   and said structure in all other directions.   10. Fastening means according to claim 7, characterized in that the aforementioned compressed metal mesh is formed under axial compression of a tubular metal mesh member and is retained by two flanges.   carried by the aforementioned eye bolt.