The present invention relates to a fastener for insertion through aligned apertures in workpiece members thereby to secure the members together, and particularly for fasteners suitable for low grip applications, i.e. applications wherein the total width of the workpiece members being secured together is relatively small.

A currently known fastener for insertion through aligned apertures in workpiece members is commercially available under the Registered Trade Mark AVTAINER, as illustrated in Figures 1 a to 3. The known fastener 2 comprises a pin 6 (as shown in Figure 1 a), and a body 4 (as shown in Figure 1 b). The pin comprises a shaft 42, a head 44, and a breakneck point 46. The body comprises a shell 8 and a nylon sleeve 10. The shell 8 comprises a radially enlarged head 12 at one end and an elongated shank 14 protruding therefrom, and a bore 16 extending axially completely through the body 4. The sleeve 10, which is located inside the elongated shank 14 of the shell 8, forms a first engaging means, and a barbed portion 52 comprising a plurality of annular barbs 18 on the pin 6 form a second engaging means. Figures 2a and 2b illustrate the installation sequence of fastener 2 into a workpiece comprising workpiece members 20, 22. Firstly, as shown in Figure 2a, the pin 6 is driven into the aligned apertures 54, 56 provided in the workpiece members 20, 22, by applying a force to the pin head 44. A plain portion 78 of the pin shank 42 is a press fit within the workpiece apertures 54, 56. Figure 2a shows the pin 6 after it has been driven into the aligned apertures 54, 56. Subsequently the body 4 is pushed, shank 14 first, onto the protruding end of the pin shank 42, until the leading end of the sleeve 10 abuts the barbed portion 52 of the pin 6. Figure 2b shows the fastener after this stage has been completed. The installation of the fastener 2 is completed by using a tool (not shown) to simultaneously pull the pin 42 shank and force the body 4 further along the pin shank 42 until the barbs 18 of the pin 6 mutually engage with the sleeve 10 of the body 4, and the underside surface 58 of the shell head 12 abuts the outer face 72 of workpiece member 22 remote from the pin head 44. The pin shank 142 is pulled until the it fails in tension at the breakneck point 46.

Figure 3 shows the fastener 2 fully installed into the workpiece to secure workpiece members 20, 22 together, wherein the barbs 18 of the pin 6 are embedded into sleeve 10 of the body 4. The grip, i.e. the total thickness of the workpiece members 20, 22, is indicated by S. To provide the necessary tensile strength of the installed fastener 2, all barbs 18 must be engaged with the sleeve 10, and therefore the grip S must be greater than the length L of the shank 14, because the sleeve 10 is enclosed within this length, and this length must be less than the grip S to ensure that the joint is secured. Although the minimum grip could be reduced by reducing the length of the fastener 2, this would also result in an unacceptable reduction in tensile strength of the installed fastener. A reduction in the length over which the barbs 18 mutually engage with the sleeve 10 would result in an unacceptable reduction in the tensile strength of the installed fastener 2. Accordingly, the minimum grip of the prior art fastener is restricted by the length of the shell, as the fastener cannot be used for grip values below the value of the shell length. An aim of the present invention is to provide a fastener in which the minimum grip value is not limited by the length of the shell. Accordingly the present invention provides, in a first aspect, a fastener as claimed in claim 1 of the appended claims.

The head of the body may be formed of a radiused member, wherein underhead contact surface is provided on an annular flange of the radiused member.

The first engaging means preferably comprises a nylon sleeve, and the second engaging means preferably comprises a plurality of barbs. The present invention provides, in a further aspect, a method of securing a workpiece together using a fastener according to claim 5 of the appended claims.

An embodiment of the present invention will now be described by way of example and with reference to the accompanying drawings in which:

Figure 4 is a cross-sectional view of the shell of a fastener in accordance with the present invention; Figure 5 is a cross-sectional view of the body of a fastener in accordance with the present invention; Figure 6 is a side view of a pin of a fastener in accordance with the present invention; Figure 7 is a partial cross-sectional view of the first stage of installation of a fastener in accordance with the present invention into a workpiece;

Figure 8 is a partial cross-sectional view of the second stage of installation of a fastener in accordance with the present invention into a workpiece;

Figure 9 is a partial cross-sectional view of a fastener in accordance with the present invention, having a relatively long pin, fully installed into a workpiece having a relatively large grip S; and

Figure 10 is a partial cross-sectional view of a fastener in accordance with the present invention, having a relatively short pin, fully installed into a workpiece having a relatively small grip s.

Referring to Figures 4 to 6, the fastener of the present invention comprises a first part comprising a body 104 (Figure 5) and a second part comprising a pin 106 (Figure 6). The body 104 comprises a steel shell 108 (Figure 4) and a nylon sleeve 1 10. The shell 108 comprises a radially enlarged head 1 12 provided at a head end 162, and a tubular elongated shank 1 14 extending away from the head 1 12. The sleeve 1 10 is positioned within a cylindrical bore 1 16 which runs throughout the shell 108.

The shell head 1 12 is formed by an outwardly extending member having a first annular radiused edge 126 and a second annular radiused edge 132, further away from the axial centre of the shell 108 than the first annular radiused edge 126. The form of the member 124 is such that an annular space 130 is formed underneath the shell head 1 12. Beyond the second annular raised edge 132, the shell head extremity 180 (i.e. the part of the shell head 1 12 which is furthest from the body shank 1 14) is formed by an annular flange 134. The annular flange 134 defines an underhead surface 158 (which forms a contact surface on installation of the fastener into a workpiece).

The tail end 164 of the shell 108 is formed with an inwardly extending flange 136. The sleeve 1 10 extends from the inwardly extending flange 136 nearly to the top of the shell head 1 12, i.e. a small clearance remains between the level of the top of the shell head 1 12 and the top of the sleeve 1 10. The exterior diameter 138 of the sleeve 1 10 is such that the sleeve 1 10 is a push fit in the bore 1 16 of the shell shank 1 14, and the internal diameter 140 of the sleeve 1 10 is less than that of the aperture defined inside the inwardly extending flange 136 at the tail end of the shell 108. The sleeve 1 10 also has a bore, 184, extending throughout its length.

The sleeve 1 10 has a leading end 166 and a trailing end 168. As illustrated, the underhead surface 158 of the shell head 1 12 is at an axial distance 'x' from the leading end 166 of the sleeve 1 10, and at an axial distance 'y' from the trailing end the shell head 1 12 are both disposed at an axial level which is at a midpoint of the sleeve 1 10.

The pin 106 is also formed of steel, and comprises an elongated shank 142 and a radially enlarged head 144 having a flat underhead surface 176. The pin shank 142 comprises a plain portion 178 immediately below the pin head 144, a barbed portion 152 (which forms a second engaging means) comprising a plurality of barbs 1 18 below the plain portion 178, a breakneck point 146, and a pin tail 148 provided with pulling grooves 150 to allow for installation of the fastener 102.

The external diameter of the pin tail 148 is a sliding fit within the bore 184 of the sleeve, and the maximum external diameter of the barbed portion 152 is greater than the internal diameter 140 of the sleeve 1 10. Figures 7 and 8 illustrates the first and second stages of installing the into a workpiece comprising a first workpiece member 120 and a second workpiece member 122.

The first step of installation is to insert the pin shank 142 through the apertures 154, 156 provided in the workpiece members 120, 122. The plain portion 178 of the pin shank 142 is a press fit within the workpiece apertures 154, 156. until the underside surface 176 of the pin head 144 abuts the outer face 170 of the first workpiece member 120, and the pin tail 148 protrudes from the outer face 172 of the second workpiece member 122. Figure 7 shows the pin 106 fully inserted in the apertures 154, 156 as above. The second step of installation is to position the body 104 manually, shank 1 14 first, over the pin tail 148, until the leading end 66 of the sleeve 1 10 abuts the barbed portion 152 of the pin 106. Due to the maximum external diameter of the barbed portion 152 being greater that the internal diameter 140 of the sleeve 1 10, it is not possible to manually insert the body 106 any further along the pin shank 142.

A suitable tool is then used to complete the installation of the fastener 102. This stage of the installation will not be described in detail as it is well known. In summary, the tool applies pressure to the first radiused edge 126of the shell head 1 12, and the pulling grooves 150 provided on the pin shank 142 enable the pin shank 142 to be pulled relative to the body 104. During the pulling of the pin shank 142, the barbed portion 152 is forced into the sleeve 1 10, thereby causing the barbed portion 152 and the sleeve 1 10 to mutually engage. The pin shank 142 is pulled until the underhead surface 158 of the shell head 1 12 contacts the outer face 172 of the second workpiece member 122, and subsequently the pin shank 142 fails in tension at the breakneck point 146. The workpiece members 120, 122 are thereby secured together.

The breakneck point 146 is sufficiently close to the barbed portion 152, (i.e. the clearance between the trailing end 168 of the sleeve 1 10 and the top of the shell head 1 12 is sufficient) that the broken end of the pin 106 does not protrude beyond the level of the end of the shell head 1 12.

Figures 9 and 10 show the fastener 102 fully installed to secure into the workpiece members 120, 122 together. Figure 9 illustrates the fastener 102 installed into a workpiece having a relatively large grip S, and Figure 10, a relatively small grip, s. (The shell is of an equal length L in both Figures 9 and 10, however the pin 6 of Figure 9 is longer than that of Figure 10).

It can be seen that, because the underhead surface 158 of the shell head 1 12 which contacts the outer face 172 of second workpiece member 122, lies at a level midway between the leading end 166 and the trailing end 168 of the sleeve 1 10, part of the sleeve 1 10, part of the shell shank 1 14 surrounding it, and also part of the barbed portion 152, extend beyond the outer surface 172 of the second workpiece member 122. Accordingly, full engagement of the barbed portion 152 and the sleeve 1 10 will always be attained on installation of the fastener 102, even if the grip of the workpiece is less than the length of the shell 1 10. This is illustrated in Figure 10, wherein, even though the relatively small workpiece grip 's' is less than the length 'L' of the shell, full engagement of the barbs 1 18 into the sleeve 1 10 is achieved. In the embodiment shown in Figure 10, the grip 's' of the workpiece can be equal to or greater than approximately half of the length 'L' of the shell.