The invention relates to a sealing plug, for example for sealing a hole in the wall of a container for fluid. More particularly, the plug is insertable into the hole, and securable therein, by access only from the outside (i.e. the non fluid-containing side) of the wall. Plugs which are radially expandable into engagement with the surface of the hole are known, for example the type of plug described in GB 2 381 301 B and commercially available under the name AVSEAL II (AVSEAL is a Registered Trade Mark).
In order for the body of the plug to be sufficiently radially expandable in a ductile manner and to a certain extent axially deformable (as described in GB 2 381 301 B), it must be made of a material which is sufficiently soft, e.g. aluminium. However, this has the disadvantage that it restricts the range of fluids which can be contained in the container when its wall has thus been sealed, because the material of the plug body can be subject to attack from certain fluids, for example acids, effluent and some bio-fuels, or subject to erosion, for example via fluid cavitation, or abrasion.
It is an object of the present invention to overcome this disadvantage.
The present invention provides, in one of its aspects, a sealing plug as defined in the appended Claim 1.
Further additional aspects of the invention are as defined in appended Claims 2 to 9.
Embodiments of the invention will now be described by way of example, and with reference to the accompanying Figures (which are all axial sections unless otherwise specified), in which:
The part of the sealing plug which is common to all of these examples is designed to seal a circular cross-section hole 11 in a steel wall 12 of a container for liquid or gas. The plug comprises a radially expandable body provided by a cylindrical shell 13. This shell is radially expandable by means of access to only the upper end of the shell, through which protrudes an elongated stem 15. The protruding part is provided with circumferential ridges and grooves 16 by means of which the stem can be engaged by the jaws 34 of an installation tool shown in
The plug so far described is commercially available under the trademark AVSEAL II, and its construction and use, and that of the corresponding installation tool, will be familiar to those skilled in the art.
The sealing plug of this example also comprises a cylindrical closed-end sealing cap 24 made of stainless steel. It has an internal cavity 25 of a diameter in which the shell 13 is a sliding fit. Its lower end 26 is closed, and its upper end 27 is open. The upper end is formed with an external protruding rim 28. In this example, the cap 24 is 14.5 mm in length, and of 0.25 mm thickness. The rim protrudes radially by approximately 0.5 mm.
According to one example embodiment, the sealing cap 24 is first inserted into the hole 11 in the wall 12, as illustrated in
The sealing plug is used in conjunction with a hydro-pneumatic powered installation tool illustrated at 29 in
In use, the stem 16 is inserted into the tool until the end face of the spigot contacts the upper end face 14 of the shell 13, and the jaws 34 are then closed together to engage the stem. The tool is then moved so as to insert the shell 13 and stem head 21 into the cap 24 in the hole 12, until the tool nosepiece face 32 contacts the rim 28 at the upper end face of the cap. This is the position shown in
This causes the shell to contract axially and expand radially, thus pushing the adjacent part 30 of the cap radially outwardly into contact with the shell wall, as illustrated in
Increasing force exerted by the installation tool on the stem causes the stem to break at the breakneck 22, leaving the sealing plug securely locked in the hole, as illustrated in
According to a second example embodiment, the radially expandable body 13 is pre-assembled inside the sealing cap 24, as illustrated in
For example, this could be provided by a radially-inwards deformation of the sealing cap in the form of an annular deformation 38 above the shell 13, as illustrated in
The pre-assembled plug is engaged with the installation tool in a similar way to the first embodiment, and the plug is then inserted in the hole 11, as illustrated in
A further embodiment is illustrated in
Another possible enhancement of the performance of the sealing plug would be to increase the strength of engagement of the cap with the hole wall, so as to increase even more the force needed to remove it. One embodiment of this is illustrated in
In the foregoing examples, the stainless steel cap 24 is of annealed stainless steel AISI 304 grade, with a hardness of Hv 150. The plug shell 13 is of annealed aluminium to AA 6061, with a hardness of Hv 40.
The embodiments of the invention as described above can provide several advantages in use. For instance, the cap can offer improved resistance to high temperatures. It can be more suitable for use with food-processing or medical applications. The harder cap resists axial scratches to the plug's external surface, e.g. when being handled, or inserted off-centre, or at an angle, into a hole. Such scratches might create leak paths. It avoids corrosion of the steel stem head used in the Avseal II. The externally ribbed version illustrated in
The invention is not restricted to the details of the foregoing examples. For instance, the cap could be made of some other suitable material such as titanium, or a hard copper alloy. The shell could be of soft copper or some other soft and ductile metal.
Number | Date | Country | Kind |
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GB 0622304.4 | Nov 2006 | GB | national |