Patent Application
20120195707
This application claims priority, under 35 U.S.C. §119, to European Patent Application No. EP11150522.8, filed on Jan. 10, 2011, titled “Metal Wall Anchor for a Screw,” which is incorporated herein by reference.
This application relates to wall anchors.
Wall anchors, which are manufactured by punching, cutting and bending a sheet metal strip of uniform thickness, are described, for example, in patent publication nos. GB-A-2 140 889, GB-A-2 379 722 and EP-A-1 338 803. The wall anchors of GB-A-2 140 889 and GB-A-2 379 722 are for securing articles to a hollow wall of the type widely used as partition walls in industrial buildings, office blocks and domestic residences. A hole is drilled through the skin of the hollow wall, usually plasterboard or hardboard, at the accessible side and the wall anchor is inserted by hand. Next, the wall anchor is set by pulling the tail collar towards the head collar to bend and collapse the plastically deformable bars. The pulling can be effected by turning the screw with a screw driver. Alternatively, the screw can be pulled by a setting tool of the type described by patent publication no. GB-A-2 289 006. Upon collapse, the plastically deformable bars spread from the axis in the manner of the spokes of an umbrella to hold the skin of the hollow wall against the transverse head flange of the head collar. The screw is subsequently re-used to secure the article to the hollow wall.
The wall anchor of EP-A-1 338 803 is capable of securing articles to hollow walls and solid walls i.e. a wall made of brick. A hole is drilled at the accessible side of a wall and the wall anchor is inserted by hand. Next, the wall anchor is set by pulling the tail collar towards the head collar. In the case of a hollow wall, the plastically deformable bars collapse, and spread from the axis in the manner of the spokes of an umbrella, to hold the skin of against the transverse head flange of the head collar. In the case of a solid wall, the plastically deformable bars rest against the wall inside the hole with sufficiently great force and contact pressure to resist withdrawal of the wall anchor. The screw is subsequently re-used to secure the article to the hollow wall.
While these types of wall anchors may be reliable and effective they suffer from certain drawbacks. One such drawback is that certain stages of the manufacturing process require pre-forming the nut with means for engagement with a threaded shaft of a screw. In the case of the wall anchors disclosed by GB-A-2 140 889 and EP-A-1 338 803, a screw thread must be formed inside the nut. This involves extruding the metal into a tubular skirt coaxial with the axis. Next, the tubular skirt is subjected to thread-cutting, also known as tapping, with a separate thread cutting machine, in order to form an internal screw thread. The screw thread must axially long enough for adequate engagement with the threaded shaft of the screw. The tapping process requires lubrication too. Metal strips pre-coated with anti-corrosion material cannot be used because tapping eliminates the coating and its anti-corrosive properties. As such, a separate anti-corrosion coating process must be applied to the wall anchor after tapping and cleaning processes. This is because a corroded thread impairs operation of the wall anchor and is to be avoided. Also, the wall anchor must be assembled with a screw of specific thread pitch to match that of the nut. This limits choice and adds cost.
In the case of the wall anchors disclosed by GB-A-2 379 722, a proper screw thread is not formed inside the nut. Instead, a radial slit is cut into each of two circular members folded upon the tail collar of the wall anchor. According to GB-A-2 379 722, these radial slits are bent upwardly slantingly to form a guide for guiding the thread of a screw. This requires additional stages to the manufacturing process in order to form and align the radial slits.
Another drawback of this type of wall anchor is a weakness in the connection between the nut and the tail collar in certain situations. In the case of the wall anchors of GB-A-2 140 889 and EP-A-1 338 803, the nut is attached to the tail collar by a web on one side and, at the other diametrically opposed side, by an anchor, or dove-tail lug, folded into a complementary recess in the abutting edges of the adjacent tail collar. Certain applications require high forces to deform the bars sufficiently to gain a good grip of a work-piece i.e. setting the wall anchor in a blind hole in solid material. If a setting tool is not at hand, then a screw driver cannot deliver enough torque to turn the screw to properly set the wall anchor. An alternative is a power tool, like, for example, an electric screw driver or a drill driver. Use of such power tools may be desirable because they can set a wall anchor quickly and easily. This is a significant benefit when several wall anchors need to be set. However, such power tools can deliver torque above a threshold sustainable by the connection between nut and tail collar which sheers before the bars are fully deformed and the wall anchor is properly set. When the connection sheers the nut spins with the screw and the bars can deform no more. The wall anchors of GB-A-2 379 722 have the same drawback above because the nut, in the form of two circular members, is connected to the tail collar by two diametrically opposed webs which risk sheering in the same way.
An additional drawback of the wall anchors of GB-A-2 379 722 is that the middle of a 180° rotational space between webs is occupied by the abutting edges at the join of the tail collar. Tensile forces acting along the screw tend to fold the circular members inside the tail collar. The tail collar bursts open at its join and the circular members collapse inside. The webs offer little or no resistance because they are at right angles to the radial direction in which the tail bursts open.
In one aspect, a wall anchor for a screw, the wall anchor comprises a longitudinal axis, a cylindrical head collar located at one end, a cylindrical tail collar located at an opposite end, and a plurality of plastically deformable substantially longitudinal bars which connect the head collar to the tail collar. The head collar has an internal free passage for a threaded shaft of a screw and a transverse head flange for abutment with a transverse head of a screw. The tail collar has an internal free passage for a threaded shaft of a screw and a nut for engagement with a threaded shaft of a screw. The bars are uniformly distributed about an internal free passage for a threaded shaft of a screw. The internal free passages of the wall anchor are substantially coaxial with the axis. The nut is a stack of at least three rings arranged substantially transverse the axis upon an annular end face of the tail collar, wherein an internal hole through each respective ring is substantially coaxial with the axis, and wherein a side of each ring is connected to the tail collar by a respective web.
Implementations of this aspect may include one or more of the following features.
The webs of the rings may be arranged at equiangular intervals about the axis. This evenly distributes the rings in the wall anchor's sheet metal blank and avoids overcrowding. It ensures that 120° rotational space exists between webs of the wall anchor. As such, radial forces in adjacent webs have a component tending to unite the abutting edges at the join of the tail collar and to resist the tail collar bursting open to let the rings collapse inside.
The length of each web may correspond to the axial distance between the annular end face of the tail collar and the respective ring to which each web is connected. This ensures that the rings are neatly and compactly stacked substantially transverse the axis. The webs may be integral with the rings and the tail collar. This avoids the need for additional machinery and manufacturing steps to connect the rings and the tail collar i.e. welding the rings to the tail collar.
Each ring of the stack may have a recess to accommodate the web of the or each ring subsequently stacked upon the annular end face of the tail collar. The webs may be neatly accommodated within the outer diameter of the rings and the tail collar. This avoids an oversized hole in the wall to accommodate a wall anchor with radially protruding webs. Also, the webs of rings axially further from the tail collar brace the axially closer rings against torque applied a turning screw. This is particularly so for ring arranged upon the annular end face. It is braced by all the webs to prevent it collapsing inside the tail collar. The webs may form a protective cage around the stack of rings which strengthens connection to the tail collar.
The rings may have flat annular faces arranged substantially transverse the axis. The rings may be stacked evenly and may be easily cut from sheet metal. The nut may be a stack of three rings. This combines efficient use of sheet metal and adequate engagement with the threaded shaft of the screw. The head collar may have at least one gripping member. The gripping member may be used to penetrate and grip surrounding wall material and prevent the wall anchor rotating when an article is being screwed to the wall or the wall anchor is being set with a screwdriver. The gripping member may protrude radially from the head collar or axially from the transverse head flange in the direction of the tail collar.
The bars may be plastically deformable to bend away from the axis. The bars may spread like the spokes of an umbrella to hold the skin of a hollow wall against the transverse head flange of the head collar. Alternatively, the bars may rest forcefully against the wall inside the hole of a solid wall to prevent withdrawal. The wall anchor may be made of one piece of sheet metal. This may avoid the need for additional machinery and manufacturing steps to connect the various components of the wall anchor i.e. by welding, adhesive, or inter-connection.
The anchor may further include a screw with a threaded shaft disposed in the internal free passages of the wall anchor, wherein the screw has a transverse head for abutment with the transverse head flange of the head collar and the threaded shaft has a tapered end for leading the threaded shaft into engagement with the at least three rings as the screw is turned. Several types of standard screw with a tapered threaded shaft may be used in the assembly, e.g., a wood screw, a sheet metal screw or a self-tapping screw. The screw may be a wood screw. A wood screw's threaded shank may have a relatively coarse pitch and can grip the wall anchor's sheet metal between adjacent thread crests. This may foster good engagement with the rings. Wood screws are commodities commonly available in virtually all conceivable shaft lengths and thread diameters. A wood screw may be an ideal and inexpensive component for assembly with the wall anchor. It may also avoids the expense and space of storing specially adapted screws.
In another aspect, a method of making a wall anchor includes the steps of (i) progressively punching and cutting a sheet metal strip to form outline shapes of the head collar, the transverse head flange, the longitudinal bars, the tail collar and the at least three rings; (ii) progressively bending the head collar, the longitudinal bars and the tail collar about the longitudinal axis to form a substantially cylindrical shape; (iii) folding the head flange to lie substantially transverse the axis; and (iv) sequentially folding each of the at least three rings about a respective web to form a stack of at least three rings arranged substantially transverse the axis upon an annular end face of the tail collar. In one implementation, the sheet metal may be pre-coated with anti-corrosion material. This may eliminate an anti-corrosion coating process from the method of making a wall anchor. This may save time and materials and ultimately reduces the cost of the wall anchor.
Advantages may include one or more of the following. The wall anchor may be manufactured without a separate step associated with pre-forming the nut with means for engagement with a threaded shaft of a screw. This has the advantage of removing the additional machinery, components, time and cost involved. The stack of at least three rings needs no such pre-forming in order to be able to engage with a threaded shaft of a screw. The combined axial thickness of the at least three rings provides adequate engagement with the threaded shaft of the screw.
The wall anchor may also facilitate a stronger connection between the nut and the tail collar. That is because the at least three rings have at least three respective webs. That is an at least 50% increase on prior art wall anchors discussed above. As such, the wall anchor may be set using an electric screw driver or drill driver and yet withstand the additional torque delivered by such a power tool without sheering the connection between the rings and the tail collar. As mentioned above, use of such a power tool is often desirable because it saves time and effort. The wall anchor of the present invention may be set using a screw driver or a setting tool as well.
Unlike prior art wall anchors (e.g., those in GB-A-2 140 889 and EP-A-1 338 803 that must use a particular screw with a thread pitch to match the thread tapped into the nut), this wall anchor suffers can use any type of screw provided it has a sufficiently long tapered threaded shaft. The tapered shaft automatically aligns itself and engages with the rings as the screw rotates. These and other advantages and features will be apparent from the description, the drawings, and the claims.
Referring to
The head collar 14 and the tail collar 16 have internal free passages 20,22 for a threaded shaft 102 of a screw 100. The bars 18 are uniformly distributed about an internal free passage 24 for the threaded shaft of the screw. The internal free passages 22,24,26 of the wall anchor are substantially coaxial with the axis A.
The head collar 14 has a head flange 26 at the one end for abutment with a transverse head 104 of the screw. The tail collar 16 has a nut 28 at the opposite end for engagement with the threaded shaft 102 of the screw 100.
The bars 18 of the wall anchor all have the same shape. Each bar has a narrow part 30 joined to the head collar 14 and a broader, parallel sided, part 32 joined to the tail collar 16. The narrow part 30 of each bar 18 tapers slightly in width towards shoulders 34 at which its meets the broader part 32. Each broader part 32 has a central longitudinally disposed rib 36 pressed into it i.e. the sheet metal is deformed to provide an elongated ridge on one side and corresponding depression on the other wherein the depression faces inwardly towards the axis A. The depression makes the broader part 32 stiffer than the narrow part 30.
Each bar 30 is shaped longitudinally so that, traversing the bar from the head collar 14 to the tail collar 16, the narrow part 30 is inclined radially outward to meet the shoulder 34. Here the bar folds and the broader part 32 is inclined radially inward to meet the tail collar 16. A circle circumscribing the bars 18 at the shoulders 34 is the same as the outer diameters of the head collar 14 and the tail collar 16.
Referring to
Referring to
While the head flange 26 is still flat in the metal strip, a central hole is punched out and extruded to form a hollow tubular skirt 48. When the head flange is bent about the hinge line 44 the tubular skirt 48 comes to lie coaxially with the axis A. The head flange 26 abuts the end of the head collar 14. A dovetail-shaped lug 50 diametrically opposite the bridge piece 42 and projecting at right angles to the head flange 26 is received within an undercut recess 52 provided in part by a rebate 52′ in the head collar at one side of the joining line 38 and in part by a rebate 52″ symmetrically disposed at the other side of the joining line 38.
Referring to
The three rings are stacked transverse the axis A upon the annular end face 58 of the tail collar. The bottom ring 28′ of the stack is bent about the web 54′ to lie upon the annular end face 58 with its internal hole 56′ coaxial with the axis A. The middle ring 28″ of the stack is bent about the web 54″ to lie upon the bottom ring 28′ with its internal hole 56′ coaxial with the axis A. The top ring 28″ of the stack is bent about the web 54″ to lie upon the middle ring 28″ with its internal hole 56′″ coaxial with the axis A. The length of each web corresponds to the axial distance between the annular end face of the tail collar and the respective ring to which each web is connected. As such, the bottom ring 28′ has the shortest web 54′, the middle ring 28″ has the intermediate length web 28″, and the top ring 28′″ has the longest web 54′″. The different lengths of the webs maintain a small transverse gap X of approximately 0.3 mm between the bottom ring 28′ of the stack and the annular end face, between the bottom ring 28′ and the middle ring 28″ of the stack, and between the middle ring 28″ and the top ring 28″ of the stack. The stack of three rings 28′,28″,28′″ is the nut 28 for engagement with the threaded shaft 102 of the screw.
The webs 54′,54″,54′″ are arranged at 120° rotational intervals about the axis A when viewed from the opposite end of the tail collar 16. The webs are accommodated within the outer diameter of the stack of rings and the tail collar. Each ring has a peripheral recess to accommodate the web of the, or each, ring subsequently stacked upon it. As such, the bottom ring 28′ has a pair of recesses 60″,60a′″ to accommodate the webs 54″,54′″ of the middle and top rings 28″,28′″, respectively. The webs 54″,54′″ help to brace the bottom ring 28′. The middle ring 28″ has a recess 60b′″ to accommodate the web 54′″ of the top ring 28′″. The web 54′″ helps to brace the middle ring 28″. The top ring 28′″ has no such recess because no additional rings are stacked upon it. However, the skilled person in this technical field will easily recognise that additional rings may be stacked upon the top ring provided that they are attached to the tail collar by their own respective webs and the existing three rings each have a peripheral recess to accommodate those webs within the outer diameter of the stack of rings and the tail collar. The skilled person may choose to do this to enhance the capability of the nut 28 to engage a threaded shaft of a screw or because thinner sheet metal is used to make the wall anchor 10.
When assembling the wall anchor 10 and the screw 100, whether prior to, or during, setting the wall anchor, the advancing threaded shaft 102 engages the rings 28′,28″,28′″ in sequential order, from the bottom ring 28′ to the top ring 28′″, as the screw rotates in the wall anchor. Engagement between the threaded shaft and the rings has two components: (a) the sheet metal of each of the rings wedges itself between thread crests C; and (b) the sheet metal which is not so wedged instead yields to the passing thread in a manner similar to tapping the rings. The small transverse gap X of about 0.3 mm between adjacent rings 28′,28″,28′″ and between the bottom ring 28′ and the annular end face 58 of the tail collar 16 is to accommodate small axial and transverse movement caused by engagement between the threaded shaft 102 and the rings.
As will be seen from the foregoing description, the manufacture of the wall anchor 10 is economical due to its omission of thread tapping and grease cleaning stages. This has the added advantage of permitting the use of sheet metal strip pre-coated with anti-corrosive material.
The sheet metal used to manufacture the wall anchor 10 must be suitable for cutting and plastic deformation. An appropriate material is unalloyed mild steel. The sheet metal is between 0.7 mm thick for smaller diameter wall anchors i.e. 7 mm and 1 mm thick for larger diameter wall anchors up to 13 mm.
Referring to
The nut 28 formed by the stack of three rings 28′,28″,28′″ is part of a wall anchor set in a hollow wall like that disclosed by GB-A-2 140 889. The skilled person in this technical field will easily recognize that there is nothing to prevent the nut 28 from being part of a wall anchor set in a solid wall like that disclosed by EP-A-1 338 803. This is expressly contemplated because of the nut's enhanced strength and resistance to torque.
These and other implementations are within the scope of the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| EP1115022.8 | Jan 2011 | EP | regional |
