Title of Invention	"SPACER WASHER"
Abstract	The pipe spacer washer (1) according to the invention includes a radially split annular element (la) defined by three mutually hinged semiannular elements (4, 5 / 6); and a snap-on fastening device defined by a tooth (32) and a seat (40) for insertion of the tooth, located at opposite substantially facing circumferential ends (2, 3) of the annular element (la), and for integrally connecting the circumferential ends (2, 3) to define an inner ring (55) housing the pipe and connected in one piece to an outer supporting ring (56) by a number of radial ribs (13, 14, 20, 21, 27, 28, 31). The washer (1) is made entirely of a single material of a Shore A hardness of over 80, in particular xantoprene®; the retaining tooth (32) is in the form of an asymmetrical arrow, and has an inner axially through cavity (39) elongated circumferentially; and the seat (40) for receiving the retaining tooth is closed partially on both sides by two lateral braces (50, 53) offset circumferentially.

Title of Invention

"SPACER WASHER"

Abstract

The pipe spacer washer (1) according to the invention includes a radially split annular element (la) defined by three mutually hinged semiannular elements (4, 5 / 6); and a snap-on fastening device defined by a tooth (32) and a seat (40) for insertion of the tooth, located at opposite substantially facing circumferential ends (2, 3) of the annular element (la), and for integrally connecting the circumferential ends (2, 3) to define an inner ring (55) housing the pipe and connected in one piece to an outer supporting ring (56) by a number of radial ribs (13, 14, 20, 21, 27, 28, 31). The washer (1) is made entirely of a single material of a Shore A hardness of over 80, in particular xantoprene®; the retaining tooth (32) is in the form of an asymmetrical arrow, and has an inner axially through cavity (39) elongated circumferentially; and the seat (40) for receiving the retaining tooth is closed partially on both sides by two lateral braces (50, 53) offset circumferentially.

Full Text	The present invention relates to a spacer washer for a pipe, in particular a vehicle brake hose. As is known, spacer washers are used extensively in the car industry, e.g. for routing small-diameter hoses -typically fuel or brake hoses - underneath vehicle frames. Conventional washers are substantially cylindrical and normally comprise an inner seat housing the pipe and connected by radial supporting portions to an outer annular supporting element. Of this basic design, numerous geometric variations are known. To permit insertion of the pipe inside the seat, the washer normally comprises a radially-open annular element with a snap-on fastening device. Some known washers, for example, comprise two hinged semiannular portions which snap on to each other, or a number of hinged elements - typically three - the two end ones of which comprise the snap-on fastening device. The fastening device normally comprises a tooth (a saw-shaped or symmetrical arrow-shaped tooth) which fits inside a seat. During insertion, the seat is deformed elastically to let the tooth through, and then snaps back into the undeformed position to lock the tooth inside. For which purpose, the seat must obviously either be made of flexible material, or be so shaped as to flex easily. On the other hand, the washer must have a certain degree of rigidity to prevent the pipe from being crushed. Some known washers are made entirely of fairly rigid polymeric material with a laterally open retaining tooth seat which parts compass-fashion to permit insertion of the tooth. Though cheap and easy to produce, by enabling the washer to be manufactured in one straightforward stamping operation, the laterally open seat design is easily released accidentally when subjected to torsion. Washers of this type, which indeed provide for effectively protecting the pipe, are also difficult to assemble, especially on automated assembly lines, precisely on account of their rigidity, which also accounts for the failure of this type of washer to damp in-service vibration of the vehicle. To simplify assembly and, above all, damp vibration, other known washers are made of two different coprocessed materials of different rigidity : a more rigid material for a central supporting layer; and an elastomeric vibration-damping material for the outermost layer and the one directly contacting the pipe. Washers of this type, however, are expensive to produce, involve a complex manufacturing process for coprocessing different materials, and yet still fail to solve the problem of possible lateral release of the fastening device, which is substantially of the same design as that of washers made entirely of rigid material. It is an object of the present invention to provide a spacer washer for pipes, designed to overcome the aforementioned drawbacks typically associated with known types, and which in particular is cheap to produce, easy to assemble, and capable of damping vibration. It is a further object of the present invention to provide a spacer washer designed to prevent accidental release when subjected to torsion. According to the present invention, there is provided a spacer washer for a pipe, in particular a vehicle brake hose, comprising a flexible radially-split annular element; and mutually cooperating snap-on fastening means located at opposite substantially facing circumferential ends of said annular element, and for integrally connecting said ends to define an inner ring housing said pipe and connected in one piece to an outer supporting ring by a number of radial ribs; characterized by being made of a single material of a Shore A hardness of over 80. More specifically, the material used is xantoprene®. Thorough testing by the Applicant's researchers, in fact, shows pipe spacer washers of good functional characteristics to be producible from a single elastomeric material, providing it has a Shore A hardness of over a given minimum value. Research has shown the minimum Shore A hardness value to be approximately 80. Washers produced from material of a hardness below this value failed to provide for adequately supporting and protecting the pipe, whereas those of the same design but produced from material of a hardness of over 80 proved sufficiently rigid to prevent crushing of the pipe, while at the same time effectively damping vibration. Besides being made from the single material indicated above, the washer according to the invention also comprises several novel design characteristics enabling the use of materials of a Shore A hardness close to the above minimum value, to ensure both protection of the pipe and effective vibration damping performance. In particular, the snap-on fastening means comprise a retaining tooth defined axially by a pair of opposite flat faces, and a seat for snap-in insertion of the tooth; and the tooth comprises at least one inner axially through cavity substantially elongated circumferentially. Said tooth is also in the form of an asymmetrical arrow, and comprises a connecting portion projecting from a first of said opposite circumferential ends of said annular element; and a pointed portion defined, between said opposite faces, by two converging convex surfaces; the radial extension of said pointed portion, at a boundary section with said connecting portion, being greater than that of said connecting portion, so as to define, at said boundary section, a first pair of shoulders. Said seat comprises, internally, a second pair of shoulders for engaging said first pair of shoulders; said seat being defined outwards and radially by two circumferential walls, and being laterally open on the sides facing said faces of the tooth; and said two circumferential walls being connected integrally, on the side facing a first of said faces, by at least a first lateral brace, and, on the side facing a. second of said faces, by at least a second lateral brace. Said braces are also offset circumferentially on opposite sides of said seat. The shape of the retaining tooth provides for smoother insertion of the tooth inside the seat; and the cavity formed in the tooth provides for easily deforming the tooth when fastening the washer, so that, as opposed to depending entirely on the seat, as with known washers, the deformation required to insert the tooth inside the seat is partly absorbed by the tooth itself, thus further simplifying closure of the washer. Finally, the fact that the seat is closed laterally on both sides - not an obvious solution from the manufacturing technology standpoint - prevents accidental release of the washer caused by torsional stress as the vehicle is moving. However, to enable the washer to be produced in a single stamping operation with no increase in production cost/ the elements laterally closing the seat are formed on the two sides of the washer and offset circumferentially. A non-limiting embodiment of the present invention will be described by way of example with reference to the accompanying drawings, in which: Figure 1 shows a plan view of a spacer washer in accordance with the present invention; Figure 2 shows a section along line II-II of the Figure 1 washer. With reference to Figures 1 and 2, number 1 indicates a spacer washer for a pipe (not shown). Washer 1 comprises an annular element la split radially so that the two opposite ends 2 and 3 are substantially facing each other, and which in turn comprises three elements 4, 5, 6 defining respective annular portions and connected integrally by portions 7 and 8 (between elements 4 and 5 and elements 5 and 6 respectively) which, being elastically deformable, define respective hinges by which to open and close washer 1 to insert the pipe. The geometry of elements 4, 5, 6 is substantially known. More specifically, element 4 is in the form of a sector of predetermined size, and comprises an inner axially through cavity 10 defined by two curved walls 11 and 12, wall 12 being radially outwards with respect to wall 11, and by two radial ribs 13 and 14 integrally connecting curved walls 11 and 12. Whereas curved walls 11r 12 are of full thickness, that is, of the same axial size as washer 1, radial ribs 13, 14 are thinner; and, to increase the structural rigidity of washer 1, the respective surfaces of curved walls 11, 12 facing cavity 10 are provided along their full length with circumferential ribs 15, 16 connecting and of the same thickness as radial ribs 13, 14. Elements 5 and 6 are also in the form of sectors of predetermined size, and comprise respective inner axially through cavities 17 and 24. Cavity 17 is defined by curved walls 18, 19, wall 19 being radially outwards with respect to wall 18; the respective surfaces of walls 18, 19 facing cavity 17 are provided along their full length with circumferential ribs 22, 23; and walls 18, 19 are connected integrally by radial ribs 20, 21. Similarly, cavity 24 is defined by curved walls 25, 26, wall 26 being radially outwards with respect to wall 25; the respective surfaces of walls 25, 26 facing cavity 24 are provided along their full length with circumferential ribs 29, 30; and walls 25, 26 are connected integrally by radial ribs 27, 28. Like walls 11 and 12, curved walls 18, 19, 25, 26 are of full thickness, whereas radial ribs 20, 21, 27, 28 and circumferential ribs 22, 23, 29, 30 are thinner and of the same thickness as ribs 13, 14, 15, 16. In addition to portion 7, elements 4 and 5 are also connected by a further V-shaped circumferential connection 70 integrally connecting radial ribs 14 and 20; and similarly, elements 5 and 6 are connected by a V-shaped circumferential connection 80 integrally connecting radial ribs 21 and 27. Element 4 comprises a further radial rib 31, of full thickness, connecting curved walls 11 and 12, adjoining rib 13, i.e. on the opposite side to rib 14, and which substantially defines end 2 of annular element la. At end 2, annular element la also comprises a retaining tooth 32 defined axially by a pair of flat opposite faces (only one of which, indicated 60, is shown in Figure 1), and in turn comprising a connecting portion 33 projecting from end 2 of element la, and a pointed portion 34 defined, between said flat faces, by two converging convex surfaces 35 and 36. Portions 33 and 34 of tooth 32 are of the same thickness but thinner than washer 1, and have different radial extensions at the boundary section, so as to define a pair of shoulders 37, 38 engageable inside an appropriate seat. Tooth 32 comprises an inner axially through cavity 39, e.g. oval in shape or substantially in the form of an elongated loop. At end 3 facing end 2, annular element la comprises a seat 40 for snap-in insertion of retaining tooth 32. Seat 40 is substantially the same shape as pointed portion 34 of tooth 32, which it is designed to receive; and, at the inlet 41 of seat 40, curved walls 25, 26 comprise respective projections 45, 46 defining respective shoulders 47, 48 for engaging shoulders 37, 38 of tooth 32 when this is inserted inside seat 40. On the side facing a first face 51 of washer 1 (the same side as face 60 of tooth 32), seat 40 is closed laterally by a flat wall 50, which in effect integrally connects curved walls 25, 26 of element 6; on the opposite face 52 of washer 1, seat 40 is partially closed by a brace 53, which in effect connects the ends of projections 45, 46; and wall 50 and brace 53 are offset circumferentially, that is, are not superposed when projected in a plane perpendicular to the axis of washer 1. As already stated and explained in more detail later on, seat 40 is closed laterally to prevent accidental release of washer 1 caused by torsional stress; while the particular design of the lateral closing elements, that is, wall 50 and brace 53, is dictated by production requirements, i.e. the necessity of producing washer 1 as quickly and cheaply as possible in a single stamping operation : to permit the insertion of opposite tool carriages, brace 53 is therefore offset circumferentially with respect to wall 50. In actual use, washer 1 is closed in known manner about the pipe (not shown) by forcing retaining tooth 32 inside seat 40, so that curved walls 11, 18, 25 define a seat 55 housing the pipe, and the radially outermost curved walls 12, 19, 26 define an outer supporting ring 56. Unlike known washers, when tooth 32 is forced inside seat 40, deformation is not limited solely to seat 40, but is partly absorbed by tooth 32 itself by virtue of cavity 39, which, during insertion, substantially assumes the shape of a figure eight. This, plus the fairly flexible nature of the material from which washer 1 as a whole is made, makes washer 1 much easier to close as compared with known types. Once inserted, tooth 32 is prevented from working laterally out of seat 40 by being retained by wall 50 on one side and brace 53 on the other, thus safeguarding against accidental release of the washer caused by torsional stress. Clearly, changes may be made to the washer as described and illustrated herein without, however, departing from the scope of the accompanying Claims. 1) A spacer washer (1) for a pipe, in particular a vehicle brake hose, comprising a flexible radially-split annular element (la); and mutually cooperating snap-on fastening means (32, 40) located at opposite substantially facing circumferential ends (2, 3) of said annular element (la), and for integrally connecting said ends (2, 3) to define an inner ring (55) housing said pipe and connected in one piece to an outer supporting ring (56) by a number of radial ribs (13, 14, 20, 21, 27, 28, 31); characterized by being made of a single material of a Shore A hardness of over 80. 2) A washer as claimed in Claim 1, characterized in that said single material is xantoprene®. 3) A washer as claimed in Claim 1 or 2, characterized in that said snap-on fastening means comprise a retaining tooth (32) defined axially by a pair of flat opposite faces; and a seat (40) for snap-in insertion of said tooth (32). 4) A washer as claimed in Claim 3, characterized in that said retaining tooth (32) comprises at least one inner axially through cavity (39). 5) A washer as claimed in Claim 4, characterized in that said cavity (39) is substantially elongated circumferentially. 6) A washer as claimed in one of the foregoing Claims from 3 to 5, characterized in that said tooth (32) is in the form of an asymmetrical arrow, and comprises a connecting portion (33) projecting from a first (2) of said opposite circumferential ends (2, 3) of said annular element (la), and a pointed portion (34) defined, between said opposite faces, by two converging convex surfaces (35, 36); the radial extension of said pointed portion (34), at the boundary section with said connecting portion (33), being greater than that of the connecting portion, so as to define, at said boundary section, a first pair of shoulders (37, 38). 7) A washer as claimed in Claim 6, characterized in that said seat (40) comprises, internally, a second pair of shoulders (47, 48) for engaging said first pair of shoulders (37, 38); said seat (40) being defined outwards and radially by two circumferential walls (25, 26), and being open laterally on the sides facing said faces of the tooth; said two circumferential walls (25, 26) being connected integrally, on the side facing a first of said faces, by at least a first lateral brace (50), and, on the side facing a second of said faces, by at least a second lateral brace (53). 8) A washer as claimed in Claim 7, characterized in that said braces (50, 53) are offset circumferentially on opposite sides of said seat (40). 9) A washer as claimed in Claim 8, characterized in that said first lateral brace (50) extends from a bottom end of said seat to said second lateral brace (53). 10) A washer as claimed in one of the foregoing Claims, characterized in that said annular element (la) comprises a number of semiannular elements (4, 5, 6) hinged to one another. 11) A spacer washer for a pipe, in particular a vehicle brake hose, substantially as described and illustrated herein with reference to the accompanying drawings.

Full Text

The present invention relates to a spacer washer for a pipe, in particular a vehicle brake hose.
As is known, spacer washers are used extensively in the car industry, e.g. for routing small-diameter hoses -typically fuel or brake hoses - underneath vehicle frames.
Conventional washers are substantially cylindrical and normally comprise an inner seat housing the pipe and connected by radial supporting portions to an outer annular supporting element. Of this basic design, numerous geometric variations are known.
To permit insertion of the pipe inside the seat, the washer normally comprises a radially-open annular element with a snap-on fastening device. Some known washers, for example, comprise two hinged semiannular portions which snap on to each other, or a number of hinged elements - typically three - the two end ones of which comprise the snap-on fastening device.
The fastening device normally comprises a tooth (a saw-shaped or symmetrical arrow-shaped tooth) which fits inside a seat. During insertion, the seat is deformed
elastically to let the tooth through, and then snaps back into the undeformed position to lock the tooth inside. For which purpose, the seat must obviously either be made of flexible material, or be so shaped as to flex easily.
On the other hand, the washer must have a certain degree of rigidity to prevent the pipe from being crushed.
Some known washers are made entirely of fairly rigid polymeric material with a laterally open retaining tooth seat which parts compass-fashion to permit insertion of the tooth.
Though cheap and easy to produce, by enabling the washer to be manufactured in one straightforward stamping operation, the laterally open seat design is easily released accidentally when subjected to torsion.
Washers of this type, which indeed provide for effectively protecting the pipe, are also difficult to assemble, especially on automated assembly lines, precisely on account of their rigidity, which also accounts for the failure of this type of washer to damp in-service vibration of the vehicle.
To simplify assembly and, above all, damp vibration, other known washers are made of two different coprocessed materials of different rigidity : a more rigid material for a central supporting layer; and an elastomeric vibration-damping material for the outermost layer and the one directly contacting the pipe. Washers of this type, however, are expensive to produce, involve
a complex manufacturing process for coprocessing different materials, and yet still fail to solve the problem of possible lateral release of the fastening device, which is substantially of the same design as that of washers made entirely of rigid material.
It is an object of the present invention to provide a spacer washer for pipes, designed to overcome the aforementioned drawbacks typically associated with known types, and which in particular is cheap to produce, easy to assemble, and capable of damping vibration.
It is a further object of the present invention to provide a spacer washer designed to prevent accidental release when subjected to torsion.
According to the present invention, there is provided a spacer washer for a pipe, in particular a vehicle brake hose, comprising a flexible radially-split annular element; and mutually cooperating snap-on fastening means located at opposite substantially facing circumferential ends of said annular element, and for integrally connecting said ends to define an inner ring housing said pipe and connected in one piece to an outer supporting ring by a number of radial ribs; characterized by being made of a single material of a Shore A hardness of over 80.
More specifically, the material used is xantoprene®.
Thorough testing by the Applicant's researchers, in fact, shows pipe spacer washers of good functional
characteristics to be producible from a single elastomeric material, providing it has a Shore A hardness of over a given minimum value.
Research has shown the minimum Shore A hardness value to be approximately 80. Washers produced from material of a hardness below this value failed to provide for adequately supporting and protecting the pipe, whereas those of the same design but produced from material of a hardness of over 80 proved sufficiently rigid to prevent crushing of the pipe, while at the same time effectively damping vibration.
Besides being made from the single material indicated above, the washer according to the invention also comprises several novel design characteristics enabling the use of materials of a Shore A hardness close to the above minimum value, to ensure both protection of the pipe and effective vibration damping performance. In particular, the snap-on fastening means comprise a retaining tooth defined axially by a pair of opposite flat faces, and a seat for snap-in insertion of the tooth; and the tooth comprises at least one inner axially through cavity substantially elongated circumferentially.
Said tooth is also in the form of an asymmetrical arrow, and comprises a connecting portion projecting from a first of said opposite circumferential ends of said annular element; and a pointed portion defined, between said opposite faces, by two converging convex surfaces; the radial extension of said pointed portion, at a
boundary section with said connecting portion, being greater than that of said connecting portion, so as to define, at said boundary section, a first pair of shoulders.
Said seat comprises, internally, a second pair of shoulders for engaging said first pair of shoulders; said seat being defined outwards and radially by two circumferential walls, and being laterally open on the sides facing said faces of the tooth; and said two circumferential walls being connected integrally, on the side facing a first of said faces, by at least a first lateral brace, and, on the side facing a. second of said faces, by at least a second lateral brace.
Said braces are also offset circumferentially on opposite sides of said seat.
The shape of the retaining tooth provides for smoother insertion of the tooth inside the seat; and the cavity formed in the tooth provides for easily deforming the tooth when fastening the washer, so that, as opposed to depending entirely on the seat, as with known washers, the deformation required to insert the tooth inside the seat is partly absorbed by the tooth itself, thus further simplifying closure of the washer.
Finally, the fact that the seat is closed laterally on both sides - not an obvious solution from the manufacturing technology standpoint - prevents accidental release of the washer caused by torsional stress as the vehicle is moving. However, to enable the washer to be
produced in a single stamping operation with no increase in production cost/ the elements laterally closing the seat are formed on the two sides of the washer and offset circumferentially.
A non-limiting embodiment of the present invention will be described by way of example with reference to the accompanying drawings, in which:
Figure 1 shows a plan view of a spacer washer in accordance with the present invention;
Figure 2 shows a section along line II-II of the Figure 1 washer.
With reference to Figures 1 and 2, number 1 indicates a spacer washer for a pipe (not shown).
Washer 1 comprises an annular element la split radially so that the two opposite ends 2 and 3 are substantially facing each other, and which in turn comprises three elements 4, 5, 6 defining respective annular portions and connected integrally by portions 7 and 8 (between elements 4 and 5 and elements 5 and 6 respectively) which, being elastically deformable, define respective hinges by which to open and close washer 1 to insert the pipe.
The geometry of elements 4, 5, 6 is substantially known. More specifically, element 4 is in the form of a sector of predetermined size, and comprises an inner axially through cavity 10 defined by two curved walls 11 and 12, wall 12 being radially outwards with respect to wall 11, and by two radial ribs 13 and 14 integrally
connecting curved walls 11 and 12. Whereas curved walls 11r 12 are of full thickness, that is, of the same axial size as washer 1, radial ribs 13, 14 are thinner; and, to increase the structural rigidity of washer 1, the respective surfaces of curved walls 11, 12 facing cavity 10 are provided along their full length with circumferential ribs 15, 16 connecting and of the same thickness as radial ribs 13, 14.
Elements 5 and 6 are also in the form of sectors of predetermined size, and comprise respective inner axially through cavities 17 and 24. Cavity 17 is defined by curved walls 18, 19, wall 19 being radially outwards with respect to wall 18; the respective surfaces of walls 18, 19 facing cavity 17 are provided along their full length with circumferential ribs 22, 23; and walls 18, 19 are connected integrally by radial ribs 20, 21.
Similarly, cavity 24 is defined by curved walls 25, 26, wall 26 being radially outwards with respect to wall 25; the respective surfaces of walls 25, 26 facing cavity 24 are provided along their full length with circumferential ribs 29, 30; and walls 25, 26 are connected integrally by radial ribs 27, 28.
Like walls 11 and 12, curved walls 18, 19, 25, 26 are of full thickness, whereas radial ribs 20, 21, 27, 28 and circumferential ribs 22, 23, 29, 30 are thinner and of the same thickness as ribs 13, 14, 15, 16.
In addition to portion 7, elements 4 and 5 are also connected by a further V-shaped circumferential
connection 70 integrally connecting radial ribs 14 and 20; and similarly, elements 5 and 6 are connected by a V-shaped circumferential connection 80 integrally connecting radial ribs 21 and 27.
Element 4 comprises a further radial rib 31, of full thickness, connecting curved walls 11 and 12, adjoining rib 13, i.e. on the opposite side to rib 14, and which substantially defines end 2 of annular element la.
At end 2, annular element la also comprises a retaining tooth 32 defined axially by a pair of flat opposite faces (only one of which, indicated 60, is shown in Figure 1), and in turn comprising a connecting portion 33 projecting from end 2 of element la, and a pointed portion 34 defined, between said flat faces, by two converging convex surfaces 35 and 36. Portions 33 and 34 of tooth 32 are of the same thickness but thinner than washer 1, and have different radial extensions at the boundary section, so as to define a pair of shoulders 37, 38 engageable inside an appropriate seat.
Tooth 32 comprises an inner axially through cavity 39, e.g. oval in shape or substantially in the form of an elongated loop.
At end 3 facing end 2, annular element la comprises a seat 40 for snap-in insertion of retaining tooth 32.
Seat 40 is substantially the same shape as pointed portion 34 of tooth 32, which it is designed to receive; and, at the inlet 41 of seat 40, curved walls 25, 26
comprise respective projections 45, 46 defining respective shoulders 47, 48 for engaging shoulders 37, 38 of tooth 32 when this is inserted inside seat 40.
On the side facing a first face 51 of washer 1 (the same side as face 60 of tooth 32), seat 40 is closed laterally by a flat wall 50, which in effect integrally connects curved walls 25, 26 of element 6; on the opposite face 52 of washer 1, seat 40 is partially closed by a brace 53, which in effect connects the ends of projections 45, 46; and wall 50 and brace 53 are offset circumferentially, that is, are not superposed when projected in a plane perpendicular to the axis of washer 1.
As already stated and explained in more detail later on, seat 40 is closed laterally to prevent accidental release of washer 1 caused by torsional stress; while the particular design of the lateral closing elements, that is, wall 50 and brace 53, is dictated by production requirements, i.e. the necessity of producing washer 1 as quickly and cheaply as possible in a single stamping operation : to permit the insertion of opposite tool carriages, brace 53 is therefore offset circumferentially with respect to wall 50.
In actual use, washer 1 is closed in known manner about the pipe (not shown) by forcing retaining tooth 32 inside seat 40, so that curved walls 11, 18, 25 define a seat 55 housing the pipe, and the radially outermost
curved walls 12, 19, 26 define an outer supporting ring 56.
Unlike known washers, when tooth 32 is forced inside seat 40, deformation is not limited solely to seat 40, but is partly absorbed by tooth 32 itself by virtue of cavity 39, which, during insertion, substantially assumes the shape of a figure eight. This, plus the fairly flexible nature of the material from which washer 1 as a whole is made, makes washer 1 much easier to close as compared with known types.
Once inserted, tooth 32 is prevented from working laterally out of seat 40 by being retained by wall 50 on one side and brace 53 on the other, thus safeguarding against accidental release of the washer caused by torsional stress.
Clearly, changes may be made to the washer as described and illustrated herein without, however, departing from the scope of the accompanying Claims.

1) A spacer washer (1) for a pipe, in particular a
vehicle brake hose, comprising a flexible radially-split
annular element (la); and mutually cooperating snap-on
fastening means (32, 40) located at opposite
substantially facing circumferential ends (2, 3) of said
annular element (la), and for integrally connecting said
ends (2, 3) to define an inner ring (55) housing said
pipe and connected in one piece to an outer supporting
ring (56) by a number of radial ribs (13, 14, 20, 21, 27,
28, 31); characterized by being made of a single material
of a Shore A hardness of over 80.
2) A washer as claimed in Claim 1, characterized in
that said single material is xantoprene®.
3) A washer as claimed in Claim 1 or 2,
characterized in that said snap-on fastening means
comprise a retaining tooth (32) defined axially by a pair
of flat opposite faces; and a seat (40) for snap-in
insertion of said tooth (32).
4) A washer as claimed in Claim 3, characterized in
that said retaining tooth (32) comprises at least one
inner axially through cavity (39).
5) A washer as claimed in Claim 4, characterized in
that said cavity (39) is substantially elongated
circumferentially.
6) A washer as claimed in one of the foregoing
Claims from 3 to 5, characterized in that said tooth (32)

is in the form of an asymmetrical arrow, and comprises a connecting portion (33) projecting from a first (2) of said opposite circumferential ends (2, 3) of said annular element (la), and a pointed portion (34) defined, between said opposite faces, by two converging convex surfaces (35, 36); the radial extension of said pointed portion (34), at the boundary section with said connecting portion (33), being greater than that of the connecting portion, so as to define, at said boundary section, a first pair of shoulders (37, 38).
7) A washer as claimed in Claim 6, characterized in
that said seat (40) comprises, internally, a second pair
of shoulders (47, 48) for engaging said first pair of
shoulders (37, 38); said seat (40) being defined outwards
and radially by two circumferential walls (25, 26), and
being open laterally on the sides facing said faces of
the tooth; said two circumferential walls (25, 26) being
connected integrally, on the side facing a first of said
faces, by at least a first lateral brace (50), and, on
the side facing a second of said faces, by at least a
second lateral brace (53).
8) A washer as claimed in Claim 7, characterized in
that said braces (50, 53) are offset circumferentially on
opposite sides of said seat (40).
9) A washer as claimed in Claim 8, characterized in
that said first lateral brace (50) extends from a bottom
end of said seat to said second lateral brace (53).

10) A washer as claimed in one of the foregoing
Claims, characterized in that said annular element (la)
comprises a number of semiannular elements (4, 5, 6)
hinged to one another.
11) A spacer washer for a pipe, in particular a
vehicle brake hose, substantially as described and
illustrated herein with reference to the accompanying
drawings.

Documents:

2798-del-1997-abstract.pdf

2798-del-1997-assignment.pdf

2798-del-1997-claims.pdf

2798-del-1997-correspondence-others.pdf

2798-del-1997-correspondence-po.pdf

2798-del-1997-description (complete).pdf

2798-del-1997-drawings.pdf

2798-del-1997-form-1.pdf

2798-del-1997-form-13.pdf

2798-del-1997-form-19.pdf

2798-del-1997-form-2.pdf

2798-del-1997-form-3.pdf

2798-del-1997-form-4.pdf

2798-del-1997-form-6.pdf

2798-del-1997-gpa.pdf

2798-del-1997-petition-137.pdf

2798-del-1997-petition-138.pdf

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Patent Number

199852

Indian Patent Application Number

2798/DEL/1997

PG Journal Number

45/2007

Publication Date

09-Nov-2007

Grant Date

26-Oct-2007

Date of Filing

30-Sep-1997

Name of Patentee

I.T.W. AUTOMOTIVE ITALIA S.R.L.

Applicant Address

STRADA SETTIMO 352/4, 10156, TORINO, ITALY.

Inventors:

#	Inventor's Name	Inventor's Address
1	ROCCO CALABRESE	CORSO GIULIO CESARE, 116, 10100, TORINO, ITALY.

PCT International Classification Number

F16L 9/18

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	TO96A 000811	1996-10-04	Italy