FR2642808A1 - WATERTIGHT RING - Google Patents

Abstract

This ring is of the type comprising an annular sealing body 5. The sealing body 5 is connected on at least one axial side 3, 4 of the sealing ring. This ring is more particularly intended for sealing screwed assemblies or screw closures.

Description

The present invention relates to a ring

  sealing, in particular for screwed joints or screw closures or the like, having an annular sealing body. Sealing rings of this type are used for sealing the fluids in the assembly area of

  least two components, in particular to seal

  screwed joints such as screwed tube connectors, screw closures or plugs or the like. In the position of use, taken in these cases, a sealing ring is placed, axially, between the sealing faces of the components to be sealed with respect to each other and, to obtain a good contact d sealing, the components are tightened against each other, so that their sealing faces come against the sealing ring, from both axial sides, and

  compress or crush it to some extent.

  Known sealing rings, such as those described in DIN 7603, consist exclusively of an annular sealing body whose particular shape and material depend on the specific conditions. But it is always this disadvantage that the sealing rings, when they are too strongly compressed by the sealing faces which are applied against them, can be damaged, so that it results in sealing defects. In addition, in the case where

  two elements screwed together, the sealing ring

  inserted bite may be twisted during screwing, so that it no longer takes the position of use, necessary for an optimal sealing effect, and that it

  can even break in some cases.

  The invention therefore aims to provide a sealing ring, which can be stressed, in particular axially, by the sealing faces of the components to be sealed, which can not be damaged or destroyed during assembly, which allows positioning correct

  in the intended position of use, in all

  constants, and which always ensures a reliable seal.

  This object is achieved by the fact that the sealing body is connected to at least one bearing element which forms a stop, intended to limit the axial crushing of the sealing body. In addition to the sealing body, the sealing ring therefore comprises. in addition, at least one support member which imparts stability and hold to the sealing ring during assembly and which prevents the sealing body from being excessively crushed or compressed,

during assembly.

  The support element, at least one, nevertheless allows a crushing of the sealing body, in the

  necessary measure to ensure a reliable seal.

  The sealing body advantageously projects the existing bearing elements, at least on one axial side of the sealing ring. If the sealing faces of the elements to be sealed relative to each other, then are axially pressed against the sealing ring, from both sides, the sealing body can be squashed or compressed axially, until the sealing faces are applied against the support elements, serving as a stop. The support members then prevent the seal body from being further crushed, and their opposing strength nevertheless ensures a tight fit

  reliable components, one against the other.

  The sealing body may be made of a material different from that of the support element, the latter being conveniently made of a material harder than the sealing body. The abutment effect of the support element is produced, for the most part, in this

case, by the hardness of the material.

  It is also possible, in particular by suitably choosing the form of construction of the support element, to obtain that the sealing ring has, axially, a greater resistance or stability than the

sealing body.

  The support element is suitably made of metal or has at least metal component parts, which guarantees a high resistance. But the support element perhaps, also made of a material-based material

  plastic, or plastic such as a polymer.

  At least one support element is preferably placed in the region of the inner periphery and / or in the region of the outer periphery of the sealing body, the respective support element being able to bear against the inner face or associated outer annular sealing body, or be inserted, for example, into the sealing body, for example in a recess thereof. In the latter case, it may be advantageous, especially when the support element must contribute to fixing the sealing ring, protrudes relative to the sealing body, or comes out of

  this one, for a certain distance, radially.

  Even protection against excessive crushing of the sealing body is obtained when

  the support element is a support ring, placed 'coaxial-

  the sealing body, which may be in the form of a socket, especially when the sealing body has a large width. The support ring configuration

  further guarantees, in particular, that the body of

  it can not deviate radially in the case of axial crushing, but is supported radially. Depending on the application and the desired support effect, a support ring may be provided in the region of the inner periphery and / or in the

  outer circumference of the sealing body.

  It is interesting that the width of the bearing ring, measured in the axial direction of the sealing ring, is slightly less than that of the sealing body; in this case, it is advantageous that the sealing body protrudes axially on both sides of the ring

  of support, and that the longitudinal median planes,

  in the axial direction, the sealing body and

of the support body, coincide.

  The support element is preferably integral with the sealing body, the support element being attachable

  and anchored, by form concordance. on the body of

  and in the case of a support ring configuration,

  can be inserted preferably into a peripheral groove

  planned, coaxially, at a corresponding point in the

sealing body.

  It may be, in this case, a fixed assembly, removable, which can also be irremovable. In particular cases where the support element is placed only against the outer face of the sealing body, it is advantageous that the support element is connected to the sealing body, by an assembly or by a coating. This can be achieved, for example, by means of a bonded assembly or by projection of the sealing body on the support element, or vice versa. It is obvious that one can have at the same time, an assembly by concordance of form and a

  adhesion joining of materials.

  The invention guarantees the deformability of the sealing body, which makes it possible to obtain an optimal sealing effect; it offers, at the same time, very

effective against destruction.

  Various embodiments of the invention are described below in more detail with reference to the accompanying drawings, in which: FIG. 1 is a sectional view of a first embodiment of the sealing ring according to FIG. invention, with a cutting plane extending radially and axially, along the line II of Figure 2; Figure 2 is a top view of the sealing ring of Figure 1, in the axial direction, according to the arrow II of Figure 1;

26428O8

  Figure 3 is a sectional view, similar to that of Figure 1, of a detail of another embodiment of a sealing ring; Figure 4 is a view, similar to that of Figure 1, of another embodiment of a sealing ring;

  FIG. 5 is a sectional view through

  longitudinal axis, of another embodiment of the sealing ring according to the invention, along the line V-V of Figure 3; FIG. 6 is a view from above, similar to that of FIG. 2, of another embodiment of the

  sealing ring according to the invention.

  The sealing rings shown in the figures are provided, in particular, for screwed connections or screw closures, but their applications are not limited to these cases. These are sealing rings

  which, in operation, ensure watertightness, essential-

  by their two surface regions, placed on opposite axial sides to each other - hereinafter referred to as sealing faces 3, 4 on the sealing ring side - which are annular in shape. These sealing faces 3, 4 are on an annular sealing body 5 whose periphery is conveniently circular cylindrical contour, both inside and outside. The sealing body is made of a material having sealing properties, which can be deformed by compression; in the exemplary embodiments shown, it is a plastic material and in particular rubber. But it is understood that one can also choose other sealing materials for the sealing body, for example materials based on steel, aluminum or copper. The sealing body can also be a composite body, unlike the examples of

production.

  Figure 1 shows that the sealing ring according to the invention can be placed in its position of use, between components 6, 7 to seal, these components being shown in dotted lines, only schematically. Moreover, all the figures represent the sealing ring in its position

  initial, that is to say not deformed.

  The component 7, shown in Figure 1, is, for example, a wall in which is formed an opening 8 which must be sealed. The closure is effected by means of the other component 6 which is here a screw closure which has a tool-engaging portion 9, a threaded rod 10 and an annular flange 14, inserted axially between these, projecting radially, all around. The threaded rod 10 is screwed into a tapping of the opening 8. On the sides, facing each other in the axial direction 2, of the annular paste 14 and the wall 7, there are faces of sealing on the component side, between which is placed the sealing ring, in its position of use, in which it is oriented coaxially towards the opening 8 and one of its sealing faces 3, 4 is turned towards one of the two sealing faces 15 on the component side. In order to obtain the sealing effect between the two components 6, 7, the two sealing faces 15 on the component side are approaching each other in the axial direction 2, which, in the example of FIG. realization, is done by screwing the screw lock 6 into the

  8. The sealing body 5 of the sealing ring

  The density is crushed or compressed axially. Due to the external resistance of the sealing body 5, there is a sealing engagement of the sealing faces 3, 15 or 4,

turned towards each other.

  In the position of use, the threaded rod 10 passes through, in this embodiment, the opening

annular 18.

  According to the invention, it is now provided that the sealing body 5 is connected to at least one bearing element 16, 16 'which forms a stop, intended to limit the axial crushing of the sealing body 5. support element ensures that the sealing body 5 can be crushed only over a certain axial distance, by the components 6, 7 to be assembled together, and to prevent a greater axial approximation of the sealing faces side components, of the two components 6, 7. This prevents the sealing body 5 from being damaged or destroyed by too much unintentional crushing. At the same time, however, it is ensured that crushing or compression of the sealing body 5 is possible within certain limits so that the paired sealing faces facing each other can come into close contact with each other. under

the effect of pressure.

  In the exemplary embodiments shown in FIGS. 1 to 4, the sealing ring has a bearing element 16 which has the shape of a bearing ring and which is placed coaxially with the sealing body 5. Its width, measured in the axial direction 2, is smaller than that of the sealing body 5, at its widest point, so that the sealing body 5 protrudes over at least one axial side of the sealing ring. sealing - on

  two axial sides, in the exemplary embodiments.

  The annular support element 16 is placed in the region of the outer periphery 17, in the examples of FIGS. 1 and 3, and in the region of the inner periphery 18 of the sealing body 5, in the embodiment of the invention. FIG. 4. In FIG. 4, it is indicated in dashed lines at 19 that it is also possible to place at the same time a support element 16 on the inner periphery 18 as on

  the outer periphery 17 of the sealing body 5.

  The abutment function of the support elements is based on the fact that they have a greater resistance and in particular a greater compressive strength, in the axial direction 2, than the sealing body 5 to which they are connected. This property can be obtained, for example, by the design mode of the respective support element; but the possibility chosen in the exemplary embodiments, according to which the material of the support element is different from that of the sealing body, is particularly advantageous. By properly selecting the material, the desired behavior can be achieved in abutment, the support element 16, 16 'to be suitably made of a material harder than the sealing body. In this case, therefore, there is practically a two-material sealing ring whose bearing element is in a hard material and the sealing body in a

  softer material, for example in a semi-

rigid.

  The support element 16, 16 'is preferably formed

  made of metal, for example steel, or

  less a material which has metallic constituents

  c. However, it is also possible to make the support element made of plastic or a plastic-based material which has the characteristics of

  necessary hardness, polymers that are suitable for

  larly. In the exemplary embodiment according to FIGS. 1 and 2, the bearing element is applied against the outer periphery 17, turned radially outwards, of the sealing body 5. It therefore coaxially surrounds the sealing body 5. It is advantageous that the longitudinal median planes of the two components, perpendicular to the

  axial direction, coincide, as shown in Figure 1.

  The attachment of the support member 16, with respect to the sealing body 5, can be guaranteed simply because of the radial elasticity of the sealing body 5, but it is appropriate to provide an additional fixed connection. This may include, in this case, an assembly, for example a bonded assembly or an assembly by adhesion. But one can also imagine to apply the support element 16, on the sealing body 5, with a coating layer and, in particular to apply it by projection on it or against it. In all these cases, we have an irremovable fixed link between the element

  support and the sealing body.

  The comments above also apply to the embodiment of FIG. 4, with the difference that the support element 16 is provided on the peripheral face 18, directed radially inwards, of the

sealing body 5.

  While in the examples of

  1, 2 and 4, the support element 16 is placed on the outer periphery or the inner periphery of the sealing body 5, in the embodiment according to FIG. The sealing body 5 is inserted in the sealing body 5. For this purpose, the sealing body 5 has, in the region of the corresponding periphery - here, the outer periphery 17 - a recess 20, in the manner an annular groove, whose longitudinal axis coincides with the longitudinal direction 2 of the sealing body 5, and in which is inserted the support element 16. As a result, the support element 16 is flanked , on its two axial sides, a continuous annular projection 21 of the sealing body 5, which prevents direct contact between the sealing faces 15 of the components to be sealed and the bearing element 16. The faces sealing 15 are thus protected. Furthermore, in one embodiment of this type, it is possible to maintain the support element 16, only in the context of an assembly of conformal shape, against the sealing body 5, in the inserting, for example so

removable, in the recess 20.

  In the embodiment of Figure 3, the outer periphery 22 of the support element 16 is in the same plane as that of the sealing body 5; but it is also quite possible to make sure that the bearing element protrudes beyond the sealing body 5, over a certain distance radially, as indicated in FIG.

dotted in Figure 3.

  It is obvious that it is also possible to provide a combination of form-fitting and material adherence between the sealing body 5 and

the respective support element 16.

  The exemplary embodiment according to FIG. 5 shows that instead of a single continuous support element 16, one

  can also place several support elements 16 'discon-

  tinus and separated, on the associated sealing body 5. In this exemplary embodiment, a plurality of support elements 16 'are distributed, spaced from each other, in the circumferential direction, along the outer periphery 17 of the sealing body 5. For a better fixing, they are housed in recesses 23, pocket-shaped, body

sealing 5.

  When the support element 16 has the shape of a support ring, there is the other advantage of a support of the sealing body 5 in the radial direction, since it is prevented from radially deviating, in case axial bias, and it emerges, by crushing, the annular sealing slot, formed between the two sealing faces 15 components. On the peripheral side 17 or 18 on which is a support ring, the radial displacement

  sealant material is prevented.

  It is obvious that the cross-section of the bearing elements 16, 16 ', as well as that of the sealing body 5, can be chosen as required. It will also adapt the thickness of the bearing elements 16, 16 ', measured in the radial direction, the probable axial forces and will be chosen larger in the case of a higher force. It is obvious, moreover, that the length of the bearing elements 16, 16 ', measured in the axial direction 2, is adapted to the length of the body.

  5 respective sealing, so as to guarantee the crush-

  minimum, necessary for a good seal, before the sealing faces; 15 component side, fail

on the support element 16, 16 '.

  It will be mentioned further that the arrangement of the bearing elements in the region of the outer periphery 17 of the sealing body 5 is generally only advantageous if the sealing faces 15 on the component side, or their radial extensions, extend. on the corresponding support element and flank it axially. In this case only, it is ensured that the sealing faces 15 can reach the support element, to limit the displacement. If a provision of this type is not guaranteed, preference will be given to a provision of the supporting elements

  in the interior periphery 18.

  With regard to its construction, the embodiment of Figure 6 essentially corresponds to

  that of Figure 2, that is why the elements cor-

  respondents have identical references. However, there is a difference in essential construction of the support element 16, which, of course, also forms a support ring, but which, unlike the embodiment of Figure 2, is not closed, but interrupted at a point 25 of its periphery. It can therefore be imagined that the support ring according to FIG. 6, comes from a band-shaped body, bent into a ring, the cut-off point 25 being located between the two free ends 26, 26 'of the ring, turned towards each other in a curved state. This cutoff point is suitably configured as an intermediate space or slot whose width can be chosen in

according to the requirements.

  This embodiment has the advantage that the support ring, open at one point, can be formed by a spring ring which is threaded on the outer periphery 17 of the sealing body 5, or placed in the region of the outer periphery. the sealing body 5, by widening, against the elastic force of a spring. In the mounted state of the support ring 16, it surrounds the sealing body 5 by tightening it, since it tends to shrink the cross section that surrounds, so that the assembly is facilitated and that a better hold on the sealing body 5 is obtained. The support element 16, configured as a ring, is provided with a flange. *% I _ _e__ of ^ s ^ RTEZ as tfrevlSésnt 0 of the Er> 1- ^ r ^ sto ol ESAC 2 nsuléo mornt ot1 enaarao rn mn U lo - 2nt- rt ^ S'Fw12 SSE1 r4 - StE 2-AQ 2 5 5 5 5 5 5 le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le le>

--- ----------

  CnorA ca ln- 'ci .-- 1-e = "1 af wrt slsrte 1> F>" J: rar' = n rr 4s _e ^ _i E1 IU rt5 é _ _E i L1 eewv _t_ h Ail Mount & 4 TanfnC Tinci AA 1 AmrQcVi 4 cn O r2bFoe By rediLl-i4 - Ti i = c + lr EEII + RVI email or 'r' olii4 'ty vc7 n T tiici At; S: lè-4 r | i 5 C! ae + n ii,; i ri es sWiyi ________ ______ _ t-_u _l_______e - -_ t riv4riw A + ^ i ow "4lt OLAs nr't I * g + '- ^^ Z ^ * _ ^ 4 i% iw ic' v; 4 monh'I '! rc AVT ao4n AA 4> ,, i, .. 4 Q 1ioAmeI AIzanwm Atoc _ _ tr * t _OP' TCH4 * _ _ _ _ _44 a ^ CA4; - _1cbfa; 4 __ __ A A A 4 4 4 4 4 4 à à à 4 4 4 4 4 4 4 4

Claims (7)

  Sealing ring, in particular for screwed joints or screw closures or the like, having an annular sealing body, characterized in that the sealing body (5) is connected to at least one support element ( 16, 16 ') which forms a stop, intended for   limit the axial crushing of the sealing body (5).   2. Sealed the claim l, characterized in that eléle t the sealing body (5 on at least u tlt axial (3, i) of the sealing ring.   3. Seal ring according to claim 2, characterized in that the sealing body (5 ') is made from another material (16, 4-). any one   Claims 1 to 3, characterized in that the element   of support (16, 16 ') is made of a material harder than the sealing body (5).   - 5. Seal ring according to any one of   Claims 1 to 4, characterized in that the element   (16, 16 ') has greater strength or stability than the sealing body (5), in the direction   axial (2) of the sealing ring.   6. Seal ring according to any one of   Claims 1 to 5, characterized in that the element   support member (16, 16 ') is made of metal or has at least constituent parts made of metal or of material based on plastics material and in particular plastic material, for example polymer.   7. Sealing ring according to any one   Claims 1 to 6, characterized in that an element   at least one bearing surface (16, 16 ') is placed in the region of the inner periphery (18) and / or in the region of the outer periphery (17) of the sealing body (5), which applies suitably. against the associated inner or outer face of the annular sealing body (5), or is embedded in the sealing body (5), this bearing element being accommodated, in particular, in a recess (20, 23) of the sealing body (5) and / or protruding, with respect to the sealing body (5), on a certain   distance, in the radial direction.   8. Sealing ring according to any one   Claims 1 to 7, characterized in that the element   support (16) is a support ring, suitably in f.u.   socket, p-acea coaxially with the body 5).   Sealing ring according to claim 8, characterized in that the bearing ring is open or spaced, at a point (25) from its periphery, the straight ends (26, 26 ') of the sealing ring. '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' '' ''. iL-. spring, which surrounds 'J. * L .. TO   Body of éscsc; é ^ $ ;; in the s-errant1 opportun1unc-4erit dae VO ring tnçiés the reentrèd.d- 4r v cu r, arésée in that the width ,,, esur é = in the -direction axial (2) , of the support element 16) in. Bearing shape, is lower than that of the sealing body due. -7 th ef-tan body, which is axially extended at 3 to the support ring, on both sides, and the longitudinal median planes, perpendicular to the axial direction of the sealing body (,) and the support ring ('L), o%, cd, opportunely.   11. Sealing ring according to any one of   claims, cracter-e in that the element   support 1'6, 16 ') is attached to the seal body = 5),   form and in the case of a config-ura-   In the aperture ring, it is preferably inserted into a perimeter frame Z 1 provided in a manner corresponding to the sealing body. 12. Seal ring according to any one of   Claims 1 to 11, characterized in that the element   bearing (16, 16 ') is connected to the sealing body (5), by an assembly or by a coating or the like, for example by means of an adhesive or crimp connection, or   by Ar - f1 of a Porini x x - t4 -