CH684391A5 - Method and apparatus for implementing an O-ring in a groove. - Google Patents

Description

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CH 684 391 A5

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Description

The subject of the present invention is a method and a device for placing an O-ring in the groove of a part or part of a part of revolution.

So far, the O-ring seals, commonly called O-rings or O-ring seals, have been placed in their grooves manually or mechanically using a tool. In all cases it is necessary to enlarge the diameter of the O-ring to bring it to the outside diameter of the groove. In the case of a very small O-ring, there is a great risk of injuring this O-ring with the tool used to enlarge it and push it into its groove.

The present invention aims to set up an O-ring in a groove, in particular a very small O-ring in the groove of a piston, without using any tool or other solid member to enlarge and push the seal. toric.

The method according to the invention is characterized in that the O-ring is threaded on an auxiliary cylindrical rod of diameter substantially equal to that of the O-ring, that the end of the part of revolution is applied coaxially against the end of said rod and that the O-ring of the rod is passed over the part of revolution by means of compressed air.

The device according to the invention is characterized in that it comprises a source of compressed air, a cylinder connected to this source of compressed air and containing a piston secured to a rod with a diameter at least approximately equal to the internal diameter of the O-ring and projecting from the cylinder body and a spring working in compression between the bottom of the cylinder and the piston, the piston and its rod having grooves, and the end of the cylinder body surrounding the piston rod having a recess cylindrical coaxial with the rod and of a diameter such that it allows the compressed O-ring to pass between the part of revolution and the wall of the recess, the stroke of the piston being such that when the spring is completely compressed, the end of the piston rod is located in the recess and exceeds the bottom of this recess by a length equal to the diameter of the section of the O-ring.

In the fully retracted position of the piston, the compressed air sent into the grooves of the latter has the effect of pushing the O-ring seal first radially, which forces it to extend, then then axially up to 'that it relaxes in the throat of the piece of revolution. The means for extending the O-ring and pushing it into its groove is therefore only constituted by compressed air. The latter does not risk damaging the O-ring.

The method according to the invention can be used both for large O-rings and for very small O-rings.

The appended drawing represents, by way of example, an embodiment, as well as two variants,

a device for implementing the method according to the invention.

Fig. 1 is a schematic view of a device for the installation of an O-ring on a piston, FIG. 1a being a front view of the cylinder 1.

Figs. 2 to 5 are sectional views of the essential part of the device of FIG. 1 in successive operating positions.

Fig. 6 is a partial view, in section, of a first alternative embodiment of the device according to FIGS. 1 to 5 for the installation of an O-ring in a groove located at a certain distance from the end of an axis.

Fig. 7 is a partial view, in section, of a second alternative embodiment of the device for the installation of an O-ring on a piston situated at a certain distance from the end of an axis.

The device, as shown at rest in FIGS. 1 and 2, comprises a cylinder 1 in which is mounted a piston 2 provided with a rod 3 and held in abutment against one end of the cylinder 1 by a spring 4 working in compression between the piston

2 and a plug 5 screwed to the end of the cylinder 1. This plug 5 is pierced with an axial hole 6 and it is connected by a duct 7 to a source of compressed air 8 provided with a suitable valve. Piston 2 and rod

3 have four longitudinal grooves 9, 10, 11 and 12 (fig. 1a and 2) extending over the entire length of the piston and its rod. The end of the body of the cylinder 1 situated on the side of the rod 3 has a cylindrical recess 13. At rest, the rod 3 exceeds this end of the body of the cylinder 1. The length of the piston 2 and of its rod 3 are such that when the spring 4 is completely compressed (fig. 3), the rod 3 exceeds the bottom of the recess 13 by a length equal to the diameter of the section of the O-ring 14 which must be put in place. As for the diameter of the recess 13 it is determined on the one hand by the section of the O-ring 14 and on the other hand by the diameter of the part of revolution 15 in the groove 16 from which the O-ring 14 must be put in place . The diameter of the recess 13 must in all cases be less than the diameter of the part of revolution 15 increased by twice the diameter of the section of the O-ring 14, so that the O-ring is compressed between the part of revolution 15 and the wall of the hollow 13. The diameter of the hollow 13 is preferably equal to the diameter of the part 15 increased by 1.4 to 1.8 times the diameter of the section of the O-ring.

The positioning of the O-ring 14 in the groove 16 of the part of revolution 15 will now be described with the aid of FIGS. 2 to 5.

The O-ring 14 is first of all threaded by hand onto the end of the rod 3 (fig. 21). The internal diameter of the O-ring 14 being equal to the diameter of the rod 3, this installation is done very easily. It is obvious that this equality of diameters should only be very approximate.

The piece of revolution 15 is then brought coaxially, by means of an automatic mechanism, against the end of the rod 3 and with sufficient pressure to push back the rod 3 and com5

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completely override the spring 4. In this position, shown in fig. 3, the end of the rod 3 is located inside the recess 13 and exceeds the bottom of this recess by a length equal to or slightly less than the diameter of the section of the O-ring 14. This O-ring is therefore taken between the bottom of the hollow 13 and the end of the part 15.

Compressed air is then sent to the cylinder 1, through the conduit 6 and the grooves 9 to 12. At the end of the rod 3, these grooves are closed on the one hand by the O-ring 14 and on the other hand by the end of the part 15. Consequently, under the effect of the air pressure, the O-ring 14 extends elastically by increasing the diameter until this diameter reaches the diameter of the recess 13 (fig. 4). In this position, the O-ring 14 continues to close the air passage and it is therefore driven and compressed between the shoulder 17 formed by the end of the part 15 and the wall of the recess 13. Once the seal O-ring 14 is located above the groove 16, it expands elastically in this groove 16 (fig. 5) and the part 15 can be withdrawn back and replaced by another part 15. The process can of course take place automatically , pneumatically for example.

The depth of the recess 13 is a function of the length of the shoulder 17. This shoulder can be relatively long in the case of a groove formed on a rod or an axis. An example is shown in fig. 6. The part 17 ′ separating the end of the part 15 from the groove 16 is relatively long. Consequently, the depth of the recess 13 ′, corresponding to the recess 13, is also relatively large. For the rest, the device shown in FIG. 6 is identical to that shown in FIGS. 2 to 5. Fig. 6 shows the device in its compressed position, as in FIG. 3. Under the effect of compressed air, the O-ring 14 is driven between the part 17 and the wall of the cylindrical recess 13 ′ to finally come to relax in the groove 16.

Fig. 7 illustrates the installation of an O-ring 14 in a groove 18 formed between two bearing surfaces 19 and 20 of an axis 21. The internal diameter of the groove is therefore equal to the diameter of the shaft 21. In this case also the groove 18 is located at a certain distance from the end of the shaft 21. The chamber 13 ", corresponding to the chamber 13 'of FIG. 6, is therefore also deep. This recess 13" opens in a second part 22 whose diameter is equal to the diameter of the recess 13 "increased by the difference between the diameter of the bearing surface 19 and the diameter of the shaft 21. As in the previous embodiments, the space between the shaft 21 and the wall of the chamber 13 ′ is less than the diameter of the section of the O-ring 14, for example equal to the diameter of the shaft 21 increased by 1.4 to 1.8 times the diameter of the section of the O-ring. 7 shows the device in its compressed position, as in Fig. 3. Under the effect of air c omitted, the O-ring 14 first extends to the diameter of the recess 13 "and it is driven between the shaft 21 and the floor of the recess 13" until it comes to abut against the bearing 19 in the recess 22. It can then extend further to pass over the span 19 and come to partially relax in the groove 18.

Claims (3)

Claims 1. Method for placing an O-ring in the groove of a part or part of a part of revolution, characterized in that the O-ring is threaded on an auxiliary cylindrical rod with a diameter substantially equal to that of the O-ring , that the end of the part of revolution is applied coaxially against the end of said rod and that the O-ring of the rod is passed over the part of revolution by means of compressed air. 2. Device for implementing the method according to claim 1, characterized in that it comprises a source of compressed air (8), a cylinder (1) connected to this source of compressed air and containing a piston (2) integral with a rod (3) of diameter at least approximately equal to the internal diameter of the O-ring (14) and projecting from the cylinder body and a spring (4) working in compression between the bottom of the cylinder and the piston , the piston and its rod having grooves (9 to 12), and the end of the cylinder body surrounding the piston rod having a cylindrical recess (13) coaxial with the rod and of a diameter such that it allows the O-ring compressed to pass between the part of revolution and the wall of the recess, the stroke of the piston being such that when the spring (4) is completely compressed, the end of the piston rod is located in the recess and exceeds the bottom of this hollow of equal length the diameter of the section of the O-ring. 3. Device according to claim 2, characterized in that the diameter of the recess is equal to the diameter of the part of revolution increased from 1.4 to 1.8 times the diameter of the section of the O-ring. 5 10 15 20 25 30 35 40 45 50 55 60 65 3