NZ766206B2 - Securing device - Google Patents

Abstract

drive transmission device for transmitting a driving force from a driving tool to a securing device for securing an article, the securing device comprising: a main shaft portion and a securing portion on the main shaft portion, wherein the securing portion is a substantially helical elongate portion defining a central space, said drive transmission device comprising a connecting member for connecting the drive transmission device to the driving tool and a receiving portion for receiving at least part of the securing device; wherein the receiving portion defines a recess for receiving a mounting member of the securing device, the receiving portion having an end face and the recess having an end opening in the end face; wherein the receiving portion comprises a force transmission wall for engaging the securing device, the force transmission wall extending axially from said end opening, whereby the force transmission wall can engage the mounting member to transmit the driving force to the securing device, and the receiving portion comprises a second wall opposite said force transmission wall; wherein the recess has a main region extending axially inwardly from the end opening, the main region being defined between the force applying wall and the second wall, and the recess has a support region extending radially outwardly from the main region to a side opening in a side of the receiving portion; and wherein the support region has a support formation comprising a support surface for supporting the securing device when the mounting member is received in the support region of the recess, the support formation extending from the second wall transverse thereto, and the support formation being provided opposite said force transmission wall. The support region and support surface allow the user to load the securing device into the force transmission arrangement, carry it using the force transmission arrangement. The user can also drive the securing device into the ground so that the securing device releases itself from the force transmission arrangement automatically by sliding along the main recess when the force transmission arrangement reaches the ground. on defining a central space, said drive transmission device comprising a connecting member for connecting the drive transmission device to the driving tool and a receiving portion for receiving at least part of the securing device; wherein the receiving portion defines a recess for receiving a mounting member of the securing device, the receiving portion having an end face and the recess having an end opening in the end face; wherein the receiving portion comprises a force transmission wall for engaging the securing device, the force transmission wall extending axially from said end opening, whereby the force transmission wall can engage the mounting member to transmit the driving force to the securing device, and the receiving portion comprises a second wall opposite said force transmission wall; wherein the recess has a main region extending axially inwardly from the end opening, the main region being defined between the force applying wall and the second wall, and the recess has a support region extending radially outwardly from the main region to a side opening in a side of the receiving portion; and wherein the support region has a support formation comprising a support surface for supporting the securing device when the mounting member is received in the support region of the recess, the support formation extending from the second wall transverse thereto, and the support formation being provided opposite said force transmission wall. The support region and support surface allow the user to load the securing device into the force transmission arrangement, carry it using the force transmission arrangement. The user can also drive the securing device into the ground so that the securing device releases itself from the force transmission arrangement automatically by sliding along the main recess when the force transmission arrangement reaches the ground.

Description

Securing Device This invention relates to securing devices. This invention also s to methods of using ng devices. Embodiments of the invention relate to securing pins and to methods of using securing pins. This invention also relates to erosion control securing devices. This invention also relates to methods of using n control ng devices. This invention also relates to securing arrangements incorporating securing pins. More ularly, but not exclusively, this invention relates to erosion control pins and to methods of using erosion control pins. The invention may also relate to drive transmission devices for transmitting driving forces to ng devices. The invention may also relate to securing arrangements comprising securing devices and drive transmission devices. This invention also relates to holding devices and to indicating s.

It is often necessary to provide some sort of erosion control system on areas of land susceptible to erosion. This can be carried out by laying matting over the area, and ng the matting thereto by the use of securing s, such as pins, pegs or staples. However, these securing s can be easily removed, which can lead to failure of the n control system.

In a first aspect, the present invention es a drive transmission device for transmitting a driving force from a driving tool to a securing device for securing an article, the securing device comprising: a main shaft portion and a ng portion on the main shaft portion, wherein the securing portion is a substantially helical elongate portion defining a central space, said drive transmission device comprising a connecting member for connecting the drive transmission device to the driving tool and a receiving portion for receiving at least part of the securing device; wherein the receiving portion defines a recess for receiving a ng member of the ng device, the receiving portion having an end face and the recess having an end opening in the end face; wherein the receiving portion comprises a force transmission wall for engaging the securing device, the force transmission wall extending axially from said end opening, whereby the force transmission wall can engage the mounting member to transmit the driving force to the securing device, and the receiving portion ses a second wall opposite said force transmission wall; wherein the recess has a main region extending axially inwardly from the end opening, the main region being d between the force applying wall and the second wall, and the recess has a support region extending radially outwardly from the main region to a side opening in a side of the receiving n; and n the t region has a support ion comprising a t surface for supporting the securing device when the mounting member is received in the support region of the recess, the support formation extending from the second wall transverse thereto, and the support formation being provided te said force transmission wall.

A related invention is bed and claimed in our New Zealand Patent Specification No. 728441, from which the present specification was divided. A full description of these inter-related inventions has been ed herein for clarity.

A securing device for securing an article may be provided, the securing device comprising a main shaft portion and a ng portion on the main shaft portion, wherein the securing portion is substantially helical. The securing portion may define a central space around which the securing portion extends.

The securing portion may extend radially beyond the main shaft portion.

The securing portion and the main shaft portion may together comprise an elongate A securing device for securing an article may be provided, the securing device comprising an elongate member, the elongate member comprising a main shaft portion and a securing portion on the main shaft portion, wherein the securing portion is substantially helical.

The securing device may comprise a securing pin. The securing device may comprise an erosion control pin.

The securing device may be suitable for securing articles to the ground, such as a substantially flat article or substantially flat portion of an article. The article may comprise a geotextile material or another geotextile article. The securing device may be le for securing other articles, such as fencing, to the ground, particularly fencing having a lower region extending flat along the ground. The ng device may be suitable for securing other articles, such as an indicating device, for e a boundary marker or a surveying marker.

An indicating device may be provided comprising a base portion in which an aperture is defined, and a projecting portion which projects from the base portion, wherein a securing device can extend through the aperture to secure the indicating device to the ground The indicating device may comprise a base portion in which an aperture is defined h which the securing device can extend, and a projecting portion which projects from the base portion. The base portion may be substantially flat. The base portion may be substantially circular. The projecting portion may be substantially cylindrical or substantially frustoconical. The indicating device may comprise a cup.

The securing device may also be suitable for securing erosion control matting to the ground. The securing device may comprise an n control ng device. bly, the securing device comprises an erosion control securing pin.

The securing portion may be coaxial with the main shaft portion.

The securing portion may extend over a minor proportion of the length of the te member. The main shaft n may extend over a major proportion of the length of the elongate member.

The securing device may comprise an engaging portion on the main shaft portion.

The engaging portion may be ured for engaging the article. The e may comprise an erosion control mat. The securing device may be used to secure other articles, or portions of articles, to the ground. For example, where fencing has a lower region extending flat along the ground, the securing device may be used to secure the lower region to the ground.

The securing device may comprise a mounting member configured for mounting the securing device on a g arrangement for g the securing device. The g arrangement may comprise a driving tool and may further include a drive transmission device for transmitting a g force from the driving tool to the securing device. The mounting member may be configured for mounting the securing device on the drive transmission device.

The main shaft portion may have proximal and distal opposite ends. The securing portion may be provided at the distal end of the main shaft n. The engaging portion may be provided at the proximal end of the main shaft portion.

The engaging portion may be substantially planar. The ng portion may comprise a substantially ar member. The mounting member may be substantially coplanar with the engaging n. The mounting member may extend inwardly of the engaging portion.

The ng member may be configured to cooperate with the driving arrangement.

The mounting member may comprise a connecting member to connect the engaging portion to the main shaft portion. The mounting member may comprise a substantially straight member.

The securing device may comprise a holding member for holding the e to the ground In one embodiment, the holding member may comprise a substantially axially extending member on the engaging member. In this embodiment, the holding member may be te and may extend alongside the shaft. The holding member of this embodiment may extend substantially parallel to the shaft portion. The holding member may be integral with the securing pin. The axially extending member may be integral with the engaging member. The provision of the holding member may render the securing device and the securing arrangement particularly suitable for use with fencing, such as fencing having a lower region ing flat along the ground.

.A ng arrangement may be provided comprising a securing device as described above and a holding device for holding the article to the ground. The provision of the holding device may render the securing device and the ng arrangement particularly suitable for use with g, such as fencing having a lower region extending flat along the ground. The holding device may comprise a first portion, which may define an aperture through which the shaft can .

A holding device may be provided comprising a first portion, wherein the first portion defines a formation through which the shaft can extend. The formation may be an aperture.

When the securing arrangement includes the holding device of this embodiment, the engaging portion may engage the holding device.

The first n may cover a part of the article in use.

The holding device may further include a skirt element extending from the first portion. The skirt element may extend substantially wholly around the first portion.

The first portion may be substantially flat. The first portion may be ntially circular. The skirt t may be substantially cylindrical.

The skirt element may have a free edge, which may define at least one recess configured to extend over a part of the article in use. The free edge of the skirt element may define a plurality of recesses spaced from one another around the skirt element, each being configured to extend across a respective part of the article.

Alternatively, the holding device may comprise a first portion for ing the main shaft portion therethrough. The holding device may further include a second n extending transverse to the first portion. The second portion may extend substantially at right angles to the first portion. The holding device may comprise two of the aforesaid second portions, which may be ed opposite each other on the first portion. The first portion may extend between the two second portions.

The first n may comprise a first formation through which the shaft can extend.

In one ment, the first formation may be a first slot defined by the first portion.

The first slot may be substantially ‘L’ shaped, and may extend from an edge of the first portion to allow the main shaft portion to be received therein via said edge. The first n may be substantially flat. The securing device may extend through the first portion to hold the holding device on the ground.

The, or each, second portion may be substantially flat. The, or each, second portion may comprise a second formation in which the article can be received thereby g the article at a d distance from the ground in a first orientation of the holding device. In one embodiment, the, or each, second formation may be a second slot defined by the respective second portion. The, or each, second slot may extend from an edge of the respective second portion.

The, or each, second portion may have a free end. The, or each, second slot may extend from said edge towards a free end of the second portion. The, or each, second slot may have a dogleg shape. When the holding device is in the first orientation, the securing device may secure the g device to the ground in a position so that the second portion extends upwardly from the ground.

The, or each, second portion may comprise a ground ng formation. The, or each, second portion may be configured to be inserted into the ground in a second orientation of the holding device. When the g device is in the second orientation, the first n may engage article between the first portion and the ground. When the g device is in the second orientation, the first portion may engage the article between the two second portions. When the holding device is in the second orientation, the securing device may secure the holding device to the ground in a position so that the second portion extends into the ground.

The, or each, ground piercing formation may comprise a tapered or pointed free end to facilitate being inserted into the ground.

The first portion may comprise a spiral region through which the shaft may extend.

The first portion may be formed of an elongate member deformed into said spiral region. The spiral region may se a wound region of the first portion.

The, or each, second portion may have hook formations at the free end thereof for receiving the article, thereby g the article at said desired distance from the ground. Where the holding device has two of the second portions, the hook formations may extend in opposite directions from the second portions.

The holding device may be formed of an te member, such as a wire.

An indicating arrangement may be ed comprising a securing device as described above and an ting device, the indicating device defining an re through which the securing device can extend.

The securing device may extend through the aperture in the indicating device to secure the indicating device to the ground. The indicating device may comprise a base portion in which the aperture is defined, and a projecting portion which projects from the base portion.

The base portion may be substantially flat. The base n may be substantially circular. The projecting portion may be substantially cylindrical or substantially frustoconical. The indicating device may comprise a cup.

According to another aspect of this invention, there is provided a method of using a securing device, the securing device comprising a main shaft portion and a securing portion on the main shaft portion, wherein the securing portion is a substantially helical elongate portion defining a central space, wherein the method comprises inserting the securing portion through an article on the ground, ing a drive transmission device as described above, mounting the ng device on the ission device, and g the securing device into the ground by rotating the securing device about the main shaft portion.

The article may se erosion control matting, and the method may be a method of securing erosion control matting to the ground.

The step of driving the securing device into the ground may be continued until the engaging portion s the article. The method may comprise providing a holding device having a first portion through which the main shaft n can extend, and the step of driving the securing device into the ground may comprise driving the securing device so that the shaft moves through the holding device. The holding device may comprise a skirt element having a free edge, said free edge defining at least one recess configured to extend over a part of the article in use, and the method may comprise arranging the holding device so that the, or each, recess extends across a respective part of the article and effecting engagement between the engaging portion and the first portion of the holding device.

Where the holding device comprises an axially extending member, the step of driving the securing device into the ground may comprise g the ng device until the holding device is driven into the ground.

The method may include mounting the securing device on a driving arrangement.

The step of mounting the securing device on the driving ement may comprise arranging the securing device on a drive transmission device to transmit a driving force from the driving arrangement. The drive transmission device may be mountable on the driving arrangement. ing to another aspect of this invention, there is ed a securing ement comprising a securing device and a drive transmission device as described above for transmitting a g force from a driving arrangement to the securing device, wherein the securing device comprises a main shaft portion and a ng portion on the main shaft portion, and wherein the securing portion is a substantially helical elongate portion defining a l space.

The recess may be a rectangular recess, and may be defined by substantially parallel opposite walls of the receiving portion. The recess may have ntially gular side and end profiles.

The connecting member may be rical or hexagonal for connecting to a chuck of the driving tool. A frustoconical portion may extend between the connecting member and the receiving portion.

The force transmission wall may extend radially outwardly from a central region of the receiving portion to said side opening. The force transmission wall may be one of said walls of the recess.

In use, the drive transmission device is rotated by the drive arrangement so that the force transmission wall engages the mounting member to rotatably urge the securing device, thereby driving the securing portion into the ground. During such rotation, the mounting member moves along the force transmission wall to exit from the recess via the end opening. This provides the advantage in the embodiment described herein that the securing device is released from the drive ission device when the securing device is driven into the ground. A further advantage provided by the embodiment described herein is that the securing device is driven into the ground to a position where the engaging portion is flush with the ground.

The support formation may comprise a support surface.

The t formation may extend transverse to said force transmission wall. The second wall may be one of said walls of the recess.

The support formation may extend from said second wall. The t formation may be arranged transverse to said second wail. The support formation may be ntially orthogonal to said second wall. The t formation provides the advantage in the second embodiment that when the mounting member is received in the recess, the mounting member can be supported on the support formation and, thereby, the securing device may be supported by the drive transmission device.

The drive transmission device may comp-rise a sleeve extending over the ing portion. The sleeve may hold the ng portion of the securing device to prevent the engaging portion uncoiling. The sleeve may define an open end through which the engaging portion of the securing device can be can be received by the receiving portion of the drive transmission device. The sleeve may have an opposite end and a cover extending across the opposite end. The cover may define an aperture through which the connecting member can extend.

Embodiments of the invention will now be described with reference to the accompanying gs, in which: Figure 1 is a side view of a securing ; Figure 2 is a view along the lines ll-Il in Figure 1; Figure 3 is a side view of the securing device in use; Figure 4 shows the securing device inserted through an article; Figure 5 is a side view of a first embodiment of a drive transmission device for use with the securing device; Figure 6 is a view along the lines Vi-Vl in Figure 5; Figure 7 is a perspective view from below of the securing device mounted on the drive transmission device; Figure 8 is a ctive view from above of the securing device mounted on the drive transmission device; Figure 9 is a view in a first direction of a second embodiment of the drive transmission device; Figure 10 is a view in a second direction erse to the first direction of the second embodiment of the drive transmission device; Figure 11 is a perspective view from below of the second embodiment of the drive transmission device; Figure 12 is a bottom view of the second embodiment of the drive transmission device; Figure 13 shows the securing device about to be d on the second embodiment of the drive ission device; Figure 14 shows the securing device being mounted on the second ment of the drive transmission device; Figure 16 shows the securing device mounted on the second embodiment of the drive transmission device, in which the drive transmission device is in a driving position relative to the securing device; Figures 16A to 16C show the arrangement of the securing device on the drive transmission device; Figure 17 shows a modified version of the second embodiment of the drive transmission device; Figure 18 is a sectional view of the drive transmission device shown in Figure 17;Figure 19 shows a further version of the second embodiment of the drive transmission device with a long ting member; Figure 20 is a sectional view of a modification of the drive ission device shown in Figure 19; Figure 21 shows a further embodiment of a securing device; Figure 22 shows an article in the form of fencing secured by a plurality of the securing devices shown in Figure 21; Figure 23 shows a holding device forming part of an embodiment of the securing device; Figure 24 is a side view of a further embodiment of a securing device incorporating the holding device shown in Figure 23; Figure 25 is a bottom plan view of the holding device shown in Figure 23 in use; Figure 26 is a sectional view of an indicating arrangement comprising a securing device and an indicating device; Figure 27 shows the indicating arrangement in use; Figure 28 is a side view of a securing arrangement comprising the securing device shown in Figure 1 and a further holding device in a first orientation; Figure 29 is a top perspective view of the ng ement shown in Figure Figure 30 is a bottom perspective View of the securing arrangement shown in Figure 28; Figure 31 is a side view of the ng arrangement shown in Figure 28 in which the further holding device is in a second orientation; Figure 32 is a side perspective view of the securing arrangement shown in Figure Figure 33 is a bottom ctive View of the securing arrangement shown in Figure 31; Figure 34 shows the further holding device shown in Figures 28 to 33; Figure 35 shows a top plan view of another embodiment of the further g device; Figure 36 is a front view of the embodiment of the further holding device shown in Figure 35; Figure 37 is a perspective view of the embodiment of the further holding device shown in Figure 35; Figure 38 shows the further holding device of Figures 35 to 37 in use in a first orientation; and Figure 39 shows the further holding device of Figures 35 to 37 in use in a second orientation.

Figures 1 to 4 show a securing device 10 comprising a securing pin 11. In at least one embodiment described herein, the securing device 10 ses an erosion control securing pin for securing an article in the form of geotextile matting 100 (see Figures 3 and 4) to the ground 101 to reduce erosion of the ground 101. However, it will be appreciated by the skilled person that the securing device 10 could be used to secure other products to the ground, for example, fences, other geotextile materials or geotextile articles, or indicating devices The securing device 10 is formed as one piece and comprises an elongate member 12 comprising a main shaft portion 14 having distal and proximal ends 16, 18. The securing device 10 r es a ng portion 20 formed at the distal end 16 of the main shaft portion 14. An engaging portion 22 and a mounting member 24 are formed at the proximal end 18 of the main shaft portion 14.

The securing portion 20 is substantially helical to allow the ng device 10 to be screwed into the ground. The securing portion 20 defines a l space 20A (see Figure 7) around which the ng portion 20 extends. The securing portion 20 extends radially outwardly from the main shaft portion 14. The securing portion 20 and the main shaft portion 14 are coaxial with each other.

The ng portion 20 extends a minor proportion of the length of the elongate member 12. in the embodiment shown, the length of the securing portion 20 along the elongate member 12 is about 20% of the length of the elongate member 12.

This provides an advantage in the embodiment described herein that any t to remove the securing device 10, by simply pulling it out of the ground, will create an upward force from the securing portion 20 against a frustum of soil above the securing portion 20, thereby requiring a r force to remove the securing device than prior art pins.

Referring to s 3 and 4, the securing device 10 is shown in use with a region of the matting 100. It will be iated by those skilled in the art that the region of the matting 100 shown in s 3 and 4 is only a small part of the matting 100, and that it extends over a much larger area of the ground 101. The ground 101 is represented by a broken line in Figure 4, so that the elongate member 12 can be seen.

The engaging portion 22 at the proximal end 18 of the elongate member 12 engages the matting 100 when the securing device 10 has been driven a sufficient distance into the ground 101. As the securing device 10 is driven into the ground 101, the engaging portion 22 urges the matting 100 against the ground 101, thereby securing the matting 100 to the ground 101.

As indicated above, the matting 100 extends over a much larger area than shown in Figures 3 and 4. In view of this, the use of a ity of the securing pins 10 may be required.

Referring again to Figure 2, a top view of the securing device 10 is shown, depicting the engaging portion 22 and the mounting member 24. The engaging portion 22 comprises a circular member 26 defining a further central space 26A.

The mounting member 24 comprises a substantially straight attaching member 28 attaching the engaging portion 22 to the main shaft portion 14.

Referring to Figures 5 to 8, the mounting member 24 is provided to mount the securing device 10 on a drive arrangement comprising a drive ission device 102 and a driving tool (not shown). The g tool can be any suitable known hand operated drill.

The drive transmission device 102 comprises a receiving portion 104 for receiving the mounting member 24 of the securing device 10. The receiving portion 104 defines a gular recess 106, in which the mounting member 24 can be received. When the ng member 24 is received in the recess 106, the ing portion 104 is received by the engaging portion 22, as shown in Figure 7 and 8. This has the advantage, in the ments described herein, of stabilising the securing device 10 on the drive transmission device 102.

The drive transmission device 102 also includes a connecting member 108 for connecting the drive transmission device 102 to the driving tool. The ting member 108 is substantially cylindrical and can be received by a standard chuck of a hand operated drill.

A frustoconical portion 110 extends between the connecting member 108 and the receiving portion 104.

In use, the drive transmission device 102 is connected to the hand operated drill in a manner that would be tood by those skilled in the art. The securing device is mounted n by inserting the mounting member 24 into the recess 106 of the receiving portion 104, so that the receiving portion is received by, and extends through, the engaging portion 22.

While so mounted on the drive ission device 102, the securing portion 20 is disposed against the matting to be secured to the ground. The user then operates the drill, thereby rotating the securing device 10 about the main shaft portion 14.

By pressing down on the drill, the securing device 10 is screwed into the ground until the engaging portion 22 engages the matting 100. The driving tool can then further drive the securing device 10 to urge the matting 100 into tighter engagement with the ground 101, thereby securing the matting 100 to the ground 101.

Figures 9 to 20 show a further embodiment of a drive transmission device generally designated 202. The drive ission device 202 ses a receiving portion 204 for receiving the mounting member 24 of the securing device 10. The receiving portion 204 defines a generally ‘L‘ shaped recess 206, in which the mounting member 24 can be received.

The recess 206 has a main region 206A, which is d by a force transmission wall 208 and a second wall 210 opposite the force transmission wall 208. The main region 206A extends axially from an end opening 211A in an end face 212 of the receiving portion 204. The main region 206A of the recess 206 and the end opening 211 extend ly outwardly from a central region 214 of the receiving portion 204. The main region 206A also has an axially extending side opening 211 B.

The recess 206 also has a support region 2068, which extends laterally from the main region 206A in a side of the receiving portion 204. The t region 2068 of the recess 206 has a support formation in the form of a support surface 218 which extends from the second wall 210 transverse thereto. The support region 2063 of the recess 206 extends radially inwardly from a laterally extending side opening 211C. The laterally extending side opening 211C extends laterally ve to the axially ing opening 21 1 B.

Figures 13 to 15 show the mounting of the securing device 10 on the drive transmission device 202. The mounting member 24 is received in the support region 2063 of the recess 206. When so received, the ng member 24 engages the support e 218 to be supported by the support surface 218.

Thus, the securing device 10 can be carried by the drive transmission device 202 when the mounting member 24 is suppoted by the t e 218.

When the mounting member 24 is received in the recess 206, the receiving portion 104 is received by the engaging portion 22, as shown in Figures 14 and 15. this provides the advantage, in the embodiments described herein, of stabilising the securing device 10 on the drive transmission device 202.

Figures 16A to 168 show the ement of the securing device 10 on the drive transmission device 202 and the driving of the securing device 10. In Figure 16A, the drive transmission device 202 and the securing device 10 are shown separate from each other. Figure 163 shows the drive transmission device 202 in engagement with the securing device 10 after the mounting member 24 has been received in the recess 206. In this position, the force transmission wall 208 is in engagement with the mounting member 24 and can thereby rotatably drive the securing device 10. Figure 16C shows the rotation of the drive transmission device 202 in the direction indicated by the arrow A to drive the securing device 10 into the ground in the direction indicated by the arrow B.

The drive transmission device 202 also includes a connecting member 220 for ting the drive transmission device 202 to the driving tool. The ting member 220 is in the form of an elongate member which may be substantially cylindrical or have a hexagonal profile. The connecting member can be received by a chuck of a rd hand operated drill.

Figures 17 and 18 show a sleeve 219 provided around the receiving portion 204.

The sleeve 219 defines an open end 221A through which the engaging portion 22 of the securing device 10 can be received. The sleeve has an opposite end 2218 having a cover 223 extending across the receiving n 204. The cover defines an aperture 225 through which the connecting member 220 extends.

Where the ground is hard, the rotational force applied by the drive transmission device 202 tends to uncoil the engaging portion 22, which has the effect of making it difficult to drive the securing device 10 into the . The sleeve 219 has the effect of holding the engaging portion 22 to prevent the engaging portion 22 from ing.

Figures 19 and 20 show a ed version of the second embodiment of the drive transmission ement 202, in which the connecting member 220 is replaced by a long connecting member 220A to allow the user drive the to reach inaccessible places and to avoid continually bending down, and thereby providing health benefits to the user. Figure 19 shows the drive transmission device 202 without the sleeve 219. Figure 20 shows the drive transmission device 202 having the sleeve 219. In use, the drive transmission device 202 is connected by means of the ting member 220 to a drill in a manner that would be understood by those skilled in the art. The securing device 10 is mounted thereon by inserting the mounting member 24 into the recess 206 of the receiving portion 204, so that the receiving portion is received by, and extends through, the engaging portion 22.

The mounting member 24 is positioned in the support region 206B of the recess 206 to be supported by the support surface 218. This allows the user to position the securing device 10 in the desired location simply by moving the drill tool as riate, and without any need for the securing 10 to be held in the user’s hand.

While so mounted on the drive transmission device 202, the securing portion 20 is disposed t the matting to be secured to the . The user then operates the drill, thereby rotating the force transmission device 202 so that force transmission device 202 is in a driving position ve to the securing pin. In this position, the force applying wall 208 is moved into engagement with the mounting member 24.

Continued rotation of the force transmission device 202 rotates the securing device about the main shaft portion 14. By pressing down on the drill, the user moves the drill towards the ground as the securing device 10 is screwed into the ground.

When the end face 212 of the drive transmission device 202 engages the g, the continued rotation of the securing device 10 by the drill screws the securing device 10 further into the ground, which causes the mounting member 24 to move along the main region 206A and the ng portion 22 to move along the receiving portion 204.

Continued rotation of the drive transmission device 202 by the drill moves the mounting member out of the recess 206 via the end opening 210. Thus, the embodiment shown in s 9 to 20 provides the advantage that the securing device 10 is driven into the ground until it tightly s the matting and is released automatically form the drive ission arrangement when such tight engagement occurs.

There is thus described a securing device 10 that can be used to secure geotextile matting 100 to ground 101 susceptible to erosion. The embodiment of the securing device 10 described herein provides the age that it is not easily removed from the ground 101, requiring a greater force than prior art securing pins to do so.

In addition, the use of the embodiments of the drive transmission arrangements described above provide the advantage that the securing device 10 is driven into the ground until the engaging portion 22 is flush with the surface of the ground.

Various modifications can be made without departing from the scope of the invenfion.

Figure 21 shows a securing device 250, which has all the features of the securing device 10 described above. A holding member, in the form of an y extending member 252, is provided on the securing device 250. The axially extending member 252 is provided on the engaging n 22 and extends alongside the shaft portion 14, substantially parallel therewith. The axially extending member 252 is formed integrally with the engaging portion 22 and thereby integrally with the ng device 250.

Figure 22 shows the securing device 250 in use to secure a lower region 226 of fencing 228. The fencing 228 is supported by posts 220. The lower region 226 extends substantially flat along the ground. The fencing 228 is formed of wires 222 which extend in a grid formation. in Figures 21 and 22, the securing devices 250 are driven into the ground so that some of the wires 222 are held between the y extending member 252 and the shaft portion 14. In Figure 21, one of the wires 222 is shown in broken lines.

Figures 23, 24 and 25 show the securing device 10 in use with a holding , generally designated 312. The holding device 312 comprises a first portion in the form of a substantially circular cover portion 314 and a downwardly extending substantially cylindrical skirt portion 316 attached to the outer edge of the cover portion 314. The skirt portion 316 has a lower edge 318 ng a plurality of recesses 320. The cover n 314 defines a central aperture 322 through which the shaft portion 14 of the securing device 10 extends in use.

As shown in Figure 25, the holding device 312 can be arranged at a junction of two of the wires 222 forming part of the lower region 226 of the fencing 228, or along one of the wires 222. In each case, the holding device 312 is arranged so that the recesses 320 are disposed over the wires to avoid damaging them.

In order to install the securing device 10, the holding device 312 is first arranged over the respective wire or wires 222, as bed above. The securing device 10 is then inserted through the aperture 322 by screwing the securing portion 20 through the aperture 322 and then into the ground beneath. The securing device is then screwed into the ground until the ng portion 22 engages the cover portion 314. The engagement of the engaging portion 22 with the cover portion 314 secures the holding device 312 onto the ground, y securing to the ground the wire or wires 222 ed through the recesses 320.

Figures 26 and 27 show an indicating arrangement 330 sing a securing device 10 and an indicating device 332 in the form of a boundary marker or a surveying marker. The securing device 10 secures the ting device 332 to the ground.

The indicating device 332 is in the form of a cup having a base portion 334 defining an aperture 336 through which the shaft portion 14 extends. A substantially cylindrical projecting portion 338 is attached to the base portion 334. The securing device 10 can be screwed through the aperture 336 into the ground in the same way in which the securing device 10 is screwed through the aperture 322 as bed above. The engaging portion 22 engages the base portion 334 and thereby secures the indicating device 332 to the ground.

When so d, the projecting portion 338 projects from the ground to provide a le indicator for the user. The projection portion may be of a suitably high visibility colour. s 28 to 33 show a securing device 10 and a holding device 340. Figures 28 to 30 show the holding device 340 in use in a first ation. Figures 31 to 33 show the holding device 340 in use in a second orientation.

The holding device 340 is shown more clearly in Figure 34 and comprises a substantially flat first portion 342. A pair of second portions 344 extend from the first portion 342. The second portions 344 extend from the first portion 342 in the same direction as each other, and are disposed at right angles to the first portion 342.

The first portion 342 is substantially flat and has a first formation in the form of a substantially ‘L' shaped first slot 346 defined by the first portion 342. The first slot 346 extends inwardly of the first portion 342 from an edge 348 thereof. As ned below, the first slot 346 receives the shaft portion 14 of the securing device 10, so that the securing device 10 can extend through the first portion 342 to clamp the first portion 342 and, therefore the holding device 340, to the ground in either the first orientation or the second orientation.

Each second portion 344 is also substantially flat has a second formation in the form of a second slot 349 defined by the second portion 344. The second slot 349 extends inwardly of the second portion 344 from an edge 350 f. Each second slot 349 extends upwardly (as viewed when the holding device 340 is in the first orientation) from the edge 350 and has a dogleg shape.

Each second slot 349 can receive therethrough an elongate article 352 in the form of a fence wire when the holding device 340 is in the first orientation shown in s 28 to 30. Each second slot 349 is defined in the respective second portion 344 a predetermined distance from the first portion 342. Therefore, when the g device 340 is clamped to the ground in the first orientation shown in Figures 28 to 30, the elongate article 352 is held a predetermined distance above the ground.

Each second portion 344 has a ground piercing formation in the form of an ly tapered free end 354. Each tapered free end provides a point to facilitate inserting the second portions 344 into the ground when the g device is in the second orientation shown in Figures 31 to 33, as also explained below.

In Figures 28 to 30, the holding device 340 is shown in a first orientation. The securing device 10 is arranged to extend through the first portion 342 by passing the shaft portion 14 into the first slot 346 via the edge 348. The ng device 10 is then screwed into the ground 101 as described above.

When the holding device 340 is in the first orientation, the second portions 344 project upwardly from the ground 101, as shown in Figure 28, and the engaging portion 22 of the securing device 10 is disposed between the second portions 344.

The elongate e 352 can then be received in the second slots 349, thereby ensuring that the elongate article 352 is held the predetermined distance above the ground.

Referring to Figures 31 to 33, the holding device 340 is shown in the second orientation. The securing device 10 is arranged to extend through the first portion 342 by passing the shaft portion 14 into the first slot 346 via the edge 348, but the engaging portion 22 is disposed on the opposite side of the first portion 342 compared to the position of the engaging portion 22 when the holding device 340 is in the first orientation.

When the holding device 340 is in the second orientation, the second portions 344 are driven into the ground 101 when the securing device 10 is screwed into the ground 101. Thus, the holding device 340 can be arranged so that one of the wires 222 can be clamped between the first portion 342 and the ground 101 (see Figure 31 ). thereby securing the wire 222 in place.

Figures 35 and 36 show another embodiment of the holding device, lly designated 360, which is formed of an te article, such as a wire. The holding device 360 can be used in first or second orientations, similar to the holding device 340 described above.

The holding device 360 shown in Figures 35 and 36 ses a first portion 362.

A pair of second portions 364 extend from the first n 362. The second portions 364 extend from the first portion 362 in the same direction as each other, and are disposed at right angles to the first portion 362.

The first portion 362 includes a first formation in the form of a Spiral region 366 through which the shaft portion 14 of the ng device 10 can be received. Each second portion 364 has a hook portion 368 at its free end for holding an elongate article, which may be a fence wire 352 (shown in broken lines in Figure 38). The hook formations 368 extend from the second portions in opposite directions, as shown in Figure 37, to help prevent the elongate article from being ged from the hook formations 368.

When the holding device 360 is in the first orientation, shown in Figure 38, the securing device 10 is arranged so that the shaft 14 extends through the spiral region 366. When the securing portion 20 is screwed into the , the engaging portion 22 clamps the spiral region 366 to the ground, y clamping the holding device 260 to the ground. The second portions 364 extending upwardly from the engaging portion 22. The fence wire 352 can then be received in the hook formations 368. The fence wire 352 is thus held at a predetermined distance above the ground.

When the holding device 360 is in the second orientation, shown in Figure 39, it can be used to clamp the lower region of a fence to the ground, such as a fence wire 222 of the lower region 226 of the fence 228 shown in Figure 22. The fence wire 222 is shown schematically in Figure 39 in broken lines. The second portions 364 are inserted into the ground in a position so that one of the wires 222 is received between the second portions 364.

The ng device 10 is ed through the spiral region 366 and screwed into the ground as described above. The engaging portion 22 clamps the spiral region 366 to the ground with the second portions 364 driven into the ground by the securing device 10. The first portion 362 is clamped onto the wire 222 to secure the lower region 226 of the fence 228 to the ground.

Claims (20)

Claims 1.

1. A drive transmission device for transmitting a driving force from a driving tool to a securing device for securing an article, the securing device comprising: a main shaft portion and a securing portion on the main shaft portion, n the securing portion is a substantially helical elongate portion defining a central space, said drive transmission device comprising a connecting member for connecting the drive transmission device to the driving tool and a receiving portion for receiving at least part of the ng device; wherein the receiving portion defines a recess for receiving a mounting member of the securing device, the receiving portion having an end face and the recess having an end opening in the end face; wherein the receiving portion comprises a force transmission wall for engaging the securing device, the force transmission wall ing axially from said end opening, whereby the force transmission wall can engage the mounting member to transmit the driving force to the securing device, and the ing portion comprises a second wall opposite said force transmission wall; wherein the recess has a main region extending axially inwardly from the end opening, the main region being defined between the force applying wall and the second wall, and the recess has a support region extending radially outwardly from the main region to a side opening in a side of the receiving portion; and wherein the support region has a t formation comprising a support surface for supporting the securing device when the mounting member is received in the support region of the recess, the support formation extending from the second wall transverse thereto, and the support ion being provided te said force transmission wall.

2. A drive ission device according to claim 1, n the recess has substantially rectangular side and end profiles.

3. A drive transmission device according to claim 1 or 2, wherein the ting member is cylindrical or nal for connecting to a chuck of the driving tool, and wherein a frustoconical portion extends between the connecting member and the receiving portion.

4. A drive ission device according to any one of the preceding claims, wherein the force transmission wall extends radially outwardly from a central region of the receiving portion to said side opening.

5. A drive transmission device according to any one of the preceding claims, wherein the support formation comprises a support surface.

6. A drive transmission device according to any one of the preceding claims, wherein the support formation s transverse to said force transmission wall.

7. A drive transmission device according to any one of the preceding claims, wherein the support formation extends from said second wall, and the support formation is arranged transverse to said second wall.

8. A drive transmission device according to any one of the preceding claims, wherein the drive transmission device comprises a sleeve extending over the receiving portion, the sleeve being ured to hold an engaging portion of the securing device to prevent the engaging portion uncoiling.

9. A drive transmission device according to claim 8, wherein the sleeve defines an open end through which the engaging portion of the securing device can be received by the receiving portion of the drive transmission device, and the sleeve having an te end and a cover extending across the te end, the cover defining an aperture through which the connecting member can extend.

10. A ng ement sing a securing device and a drive transmission device as d in claim 1 for transmitting a driving force from a driving arrangement to the securing device, n the securing device comprises a main shaft portion and a securing portion on the main shaft portion, and wherein the securing portion is a substantially helical elongate portion ng a central space.

11 A method of using a securing device, the securing device comprising a main shaft portion and a securing portion on the main shaft portion, wherein the securing n is a substantially helical elongate portion defining a central space, wherein the method comprises inserting the securing n through an article on the ground, providing a drive transmission device as claimed in claim 1, mounting the securing device on the transmission device, and driving the securing device into the ground by rotating the securing device about the main shaft portion.

12. A method according to claim 11, n the article comprises erosion control matting, and the method comprises a method of securing erosion control matting to the .

13. A method according to claim 11 or claim 12, wherein the step of driving the ng device into the ground is ued until the engaging portion engages the

14. A method according to any one of claims 11, 12 or 13, wherein the method comprises providing a holding device having a first portion h which the main shaft n can extend, and the step of driving the securing device into the ground comprises driving the securing device so that the shaft moves through the holding device.

15. A method according to claim 14, n the holding device comprises a skirt element having a free edge, said free edge defining at least one recess configured to extend over a part of the article in use, and the method comprises arranging the holding device so that the, or each, recess extends across a respective part of the article and effecting engagement between the engaging portion and the first n of the holding device.

16. A method according to claim 15, wherein the step of driving the securing device comprises arranging the securing device on the drive transmission device in a position to transmit a driving force from a driving arrangement.

17. A method according to claim 16, wherein the drive transmission device comprises a force transmission wall and the method includes rotating the drive transmission device so that the force transmission wall s the mounting member to rotatably urge the securing device, thereby driving the securing portion into the ground, whereby during such rotation, the ng member moves along the force ission wall to exit from the recess via the end opening.

18. A drive transmission device according to claim 1, substantially as herein described or exemplified with reference to the accompanying drawings.

19 A securing arrangement according to claim 10, substantially as herein described or exemplified with reference to the accompanying gs.

20. A method according to claim 11, substantially as herein described or exemplified with reference to the accompanying drawings. 57 all!!! till-“1WA 210 208 206A .iiig-_1