Description of the Related Art In prior art dovetail jigs, it has been common practice to provide a metal or phenolic template, or separate router guide fingers, mounted on top of the jig and serving to support the base plate of a router, while guiding a router bit projecting downwardly past the template or guide fingers. It is a disadvantage of such an arrangement that the template or guide fingers must be sufficiently rigid to support the downward pressure of the router base plate.

One prior art dovetail jig of that type has double-ended guide fingers, each with a male guide at one end and a female guide at the opposite end. If the fingers are uneven, the router tends to be deflected upwardly and downwardly during the cutting of the dovetail pins and tails, causing a step to be formed in the joint. The router is not supported beyond the ends of the fingers. In use, guide fingers are clamped onto guide rails and, to change from male to female guides, or vice versa, the guide rail, together with the guide fingers, must be removed from the jig, rotated and then reinstalled and repositioned on the jig for through dovetails or rotated end-to-end for half blind dovetails. Such an

arrangement is complex and difficult to learn, and makes repeatability of the finger settings difficult to achieve. Furthermore, because the fingers are double-ended, and therefore long, the workpiece, which is horizontal, must be clamped relatively far from the end of the workpiece, which makes it difficult to clamp the workpiece rigidly.

It is also common, in prior art dovetail jigs, to clamp a horizontal workpiece down onto a top surface of a jig body and to clamp a vertical workpiece against a front surface of the jig body. When the workpieces have been thus clamped down onto or up against the jig body, the guide finger assembly has to be lowered down onto the top surfaces of the workpieces, adjusted into position and locked in place. This contributes to the complexity of such dovetail jigs and, also, adds to the manufacturing costs.

BRIEF SUMMARY OF THE INVENTION According to the present invention, there is provided a woodworking jig, comprising a workpiece clamp and router guide members for guiding a router bit during cutting of a workpiece held by the clamp, characterized by a pair of horizontally elongate co-planar router plate guide surface areas spaced apart from one another, an elongate opening between the router plate guide surface areas, the workpiece clamp being mounted below the opening, a guide member support extending along the opening and a plurality of router guide members releasably interengageable with the guide member support to locate the router guide members in operative positions above the workpiece clamp and below the level of the router plate guide surface areas.

When this woodworking jig is in use, workpiece is clamped with an end edge of the workpiece located below the opening. A router is then positioned above the jig, with a base plate of the router in sliding, guided engagement with the router plate guide surface areas and with a router bit projecting downwardly from the router into the opening, so as to be guided by the guide members mounted on the guide member support. The

downward pressure of the router is thus supported by the router plate guide surface areas, and not by the guide members.

In a preferred embodiment of the invention, the guide member support comprises a row of locating formations which are interengageable with corresponding formations on the guide members. By spacing the locating formations in a uniform manner along the guide member support, the guide members can be easily located at various spacings apart from one another along the guide member support and these spacings can be readily restored when the guide members are removed from and subsequently reinstalled on the guide member support.

The guide members preferably comprise dovetail pin guides and dovetail tail guides which are separate from the dovetail pin guides, and may be readily engageable with the guide member support by snap-action engagement of the guide members onto the guide member support. However, the guide members may alternatively be shaped and utilized for cutting e. g. mortice and tenon joints, box joints, finger joints and decorative joints.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be more readily understood from the following description of preferred embodiments thereof given, by way of example, with reference to the accompanying drawings, in which:- Figure 1 shows an isometric view of a dovetail jig according to the present invention installed on a workbench; Figure 2 shows a view corresponding to Figure 1, but with parts of the jig removed; Figure 3 shows a view corresponding to Figures 1 and 2, but with further parts of the jig broken away to reveal components in the interior of the jig;

Figure 4 shows a broken-away view taken in horizontal section through the jig of Figure 3; Figure 5 shows a broken-away isometric view of parts of the jig of Figures 1 through 4; Figure 6 shows an isometric view of a dovetail pin guide forming part of the jig of Figures 1 through 4; Figures 7 and 8 show successive steps in the interengagement of the dovetail pin guide of Figure 6 with a guide member support on the jig of Figures 1 through 4; Figures 9 and 10 show broken-away plan views of parts of the jig of Figures 1 through 4 set up for cutting dovetail tails and dovetail pins, respectively, for a through dovetail joint; Figures 11 and 12 show views taken in vertical cross-section along the lines 11-11 of Figure 9 and the lines 12-12 of Figure 10, respectively, during the cutting operations of Figures 9 and 10, respectively; Figures 13 and 14 show views corresponding to Figures 9 and 10 but with the jig set up for a half-blind dovetail joint; Figures 15 and 16 show views corresponding to Figures 11 and 12 and taken in vertical cross-section along the lines 15-15 and 16-16 of Figures 13 and 14, respectively, but during the cutting operations of Figures 13 and 14, respectively; Figure 17 shows a broken-away isometric view of parts of the jig of Figure 1; Figure 18 shows a view in vertical cross-section along the line 18-18 of Figure 17;

Figure 19 shows a broken-away isometric view of a modified router bit guide arrangement for use in the jig of Figure 1; Figures 20A and 20B show diagrammatic views in front elevation of alternative joints which can be produced by a jig according to the present invention; Figure 21 shows a view taken in horizontal cross-section through a modification of the jig of Figure 1; Figure 22 shows a diagrammatic view in vertical cross-section through a further modified jig according to the present invention; Figure 23 shows a view corresponding to that of Figure 22 but through a still further modified jig according to the invention; Figures 24A and 24B show views in perspective of a modification of the jig of Figure 1 with a removable housing top portion; Figure 25 shows a view corresponding to Figure 14 but including modified guide members; Figures 26 and 27 show views in perspective of one of the modified guide members of Figures 25, the guide member of Figure 27 being partially broken away; Figures 28 and 29 shows views in horizontal cross-section and vertical cross-section, respectively, through a further modified jig according to the invention; and Figure 30 shows a view in horizontal cross-section through yet another modified jig according to the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT In Figure 1 of the accompanying drawings, there is shown a dovetail jig indicated generally by reference numeral 10 mounted on an edge of a workbench 12.

The dovetail jig 10 has a jig body in the form of a housing 14, formed as a casting, which is rectangular in plan view and which has, on its top, a router support comprising a pair of parallel, horizontally spaced raised top portions 16, which are elongate and straight and which extend along opposite sides of an horizontally elongate, rectangular, upwardly open top opening 18 between the raised portions 16. The raised portions 16 have flat, co-planar upper guide surfaces 20 which provide guide surface areas for slidably supporting and guiding a base plate 22 of a router 24, as shown in Figures 11 and 12. The raised portions 16 serve to raise the router base plate 22 above any dust or chips which may accumulate on the top of the housing 14.

At the front of the jig 10, a recess 26 is formed in the top of the housing 14, and at the rear of this recess 26 a vertical safety plate 28, made of glass, is inserted downwardly into a vertically open slot 30 in the housing 14, so that the safety plate 28 forms a closure for a front opening 32 in the housing 14. The housing is thus closed at its front and is also closed at opposite ends and, except for the opening 18, at its top, so that wood chips and dust produced during routing are contained within the housing.

In the top opening 18 of the housing 14, and extending along front and rear edges of the opening 18, there is provided a router bit guide arrangement comprising mutually opposed elongate guide member supports 35 and 36 (Figure 11). As illustrated more clearly in Figures 7 and 8, the guide member support 36 is provided, along its length, with locating formations 38 in the form of serrations or teeth. More particularly, the guide member support 36 is in the form of a rail which has a horizontal T-shaped cross-section, with upper and lower flanges 36a and 36b, with the locating formations 38 formed in a linear row along the upper flange 36a of the guide member support 36 and facing rearwardly of the jig, and with the locating formations 38 being uniformly spaced along

the guide member support 36. The guide member support 35 is similar to the guide member support 36.

Figure 1 shows a plurality of male guide members in the form of dovetail pin guide members 40 mounted on the guide member support 36. The guide members 40, in the present embodiment of the invention, are made of plastic material, but they may alternatively be made of metal. One of these guide members 40 is shown in greater detail in Figure 6, from which can be seen that this guide member 40 comprises a finger portion 42 which is partially bifurcated at one end to form opposed base portions 44a and 44b.

The base portion 44a is provided with formations 46 in the form of teeth or serrations, which correspond to and are interengageable with the locating formations 3 8 on the guide member support 36.

Also, while in the present embodiment the guide members 40 and female guide members in the form of dovetail members 40a, described below, are shaped for the cutting of dovetail pins and tails, it will be apparent that they may be modified as other male and female guide members for the cutting of other types of joint.

More particularly, as shown in Figure 7, the guide member 40 is mounted on the guide member support 36 by firstly interengaging the base portion 44a with the locating formations 38 on the guide member support 36 and by then rotating the finger portion 42 downwardly as indicated by arrow A in Figure 7, so as to engage the base portion 44b of the guide member, by a resilient snap-action interengagement, with the lower flange 36b of the guide member support 36. The guide member 40 is similarly mountable on the guide member support 35.

Within the housing 14, as illustrated in Figure 3, there is provided a clamping arrangement including a horizontally closable clamp 48, indicated generally by reference numeral 48, which comprises two clamp jaws in the form of clamp bars 50 and 52. To effect the horizontal closure and opening of this clamp 48, the clamp bars 50 and 52 are horizontally displaceable to and fro, relative to one another, by rotation of threaded shafts

53 and 55 provided at opposite ends of the clamp bars 50 and 52. The shafts 53 and 55 are interconnected by means of a belt and sprocket drive 54, which is provided with a belt tensioner 51, and are rotatable by insertion of an actuating knob 56, shown in Figure 1, through vertical circular openings 58 in a front wall 60 of the housing 14. The knob 56 has a hexagonal pin 62 (Figure 5) which is releasably engageable with a corresponding hexagonal end recess in each of the shafts 53 and 55, and in other shafts as indicated by arrows A, for rotating the shafts.

The clamp bars 50 and 52 are each made of sheet metal bent to form hollow bars of rectangular cross-section and plates 59 (Figure 4) are secured to one. interior wall of the clamp bar 52. The shafts 53 and 55 are in threaded engagement with the plates 59.

Helical compression springs 61, which are co-axial with the shafts 53 and 55, are seated at opposite ends of the springs 61 on the plates 59 and on plates 63 which extend around the shafts 53 and 55 and are fixed to the exterior of the clamp bar 50, the shafts 53 and 55 being freely rotatable relative to the plates 63. Consequently, on rotation of the shafts 53 and 55, the clamp bars 50 and 52 are moved horizontally together against the action of the springs 61 or apart from one another, under the action of the springs 61, depending on the direction of rotation of the shafts 53 and 55.

The clamp bars 50 and 52 extend at one end to respective blocks 66 and 68 (Figure 3), which are carried on a shaft 70 extending transversely of the lengths of the clamp bars 50 and 52. The shaft 70 is fixedly mounted at opposite ends thereof in the jig housing 14 and carries a pair of blocks 72 and 74, which are secured by screws (not shown) to a rectangular plate 76.

The plate 76, the blocks 68,72 and 74 and the clamp bar 52 are thus fixed to one another to form an assembly which is slidable to and fro along the shaft 70. A helical tension spring 78, secured at opposite ends to the block 72 and the housing 14, resiliently biases the assembly towards the rear of the jig 10. An adjustment screw 77, provided with a lock nut 79, serves as an adjustable stop for this assembly, and the assembly can be manually displaced away from the stop against the action of the spring 78. Locking knobs

80 and 82, in threaded engagement with the blocks 66 and 68, respectively, can be tightened to releasably secure the clamp bars 50 and 52 one at a time to the shaft 70.

The clamping arrangement of the jig 10 also includes a vertically closable clamp indicated generally by reference numeral 86 in Figure 3. The clamp 86 comprises a vertically movable clamp bar 88 co-operating with a downwardly facing clamp surface 90 (see Figure 11) formed on the interior of the housing 14 at the rear of the jig 10.

The clamp bar 88 is suspended, at each end of the clamp bar 88, on a vertical threaded member 92. As shown in Figure 5, which shows one of the threaded members 92, a threaded plate 94 provided within and fixed to the clamp bar 88 is in threaded engagement with the threaded member 92, the lower end of which carries a sprocket 96.

A belt 98 interconnects the sprockets 96 on the two threaded members 92 and extends along and within the hollow interior of the clamp bar 88. The top of the housing 14 is formed with cylindrical recesses 100 for receiving heads 102 on the threaded members 92, which are also formed with annular flanges 104. The flanges 104 are rotatably slidably supported on the bottoms of the recesses 100 and the heads 102 are formed with hexagonal recesses 105 for receiving the hexagonal pin 62 to facilitate rotation of the threaded members 92 for raising and lowering the clamp bar 88.

The use of the jig 10 for cutting a through dovetail joint is illustrated in Figures 9 through 12.

In Figure 9, tail guide members 40a are shown mounted on the guide member support 36, in a manner similar to the guide members 40, the tail guide members 40a being located at the required spacings from one another along the guide rail support 36. A vertically extending workpiece 110 is clamped between the horizontally closable clamp bars 50 and 52 and, as shown in Figure 11, the workpiece abuts the undersides of the tail guide members 40a and also abuts one of the stops 125a and 125b (Figures 3 and 4) and the router 24 is positioned so that the router base plate is slidably supported on the guide surfaces 20 above the top of the housing 14. A dovetail router bit 112 is shown extending

downwardly, with a slidable guide portion 114 of the router 24 engaging one of the tail guide members 40a and with a cutting portion 116 of the router bit 112 having cut through the thickness of the workpiece 110.

When the required tails 118 (Figure 9) have been cut in this manner in the workpiece 110, the tail guide members 40a are disengaged from the guide member support 36 and the workpiece 110 is removed and replaced by another workpiece 120 (Figures 10 and 12), which is clamped between the clamp bars 50 and 52. The dovetail bit 112 in the router 24 is then replaced by a straight bit 122, and the tail guide members 40a are replaced by the pin guide members 40, as shown in Figure 12.

During the cutting of the pins, the position of the plate 76 and thus the position of the clamp bar 52 are determined by adjustment of the adjustment screw 77 to correspondingly adjust the size of the pins.

The tail guide members 40a and the pin guide members 40 are each formed with a position marker 124 (Figures 9 and 10). When the tail guide members 40a are mounted on the guide member support 36 as shown in Figure 9, pencil markings may be inscribed on the jig housing, opposite the indicator markings 124. When the tail guide members 40a are then replaced by the pin guide members 40, the markings 124 on the pin guide members 40 can be aligned with these pencil markings in order to ensure correct positioning on the guide member support 36.

In each case, the workpieces 110 and 120 are located in abutment with one or the other of two stops 125a and 125b (Figures 3 and 4) on the jig.

Figures 13 through 16 show views corresponding to those of Figures 9 through 12, respectively, but with the jig being employed for the cutting of half blind dovetails, instead of through dovetails.

For this purpose, the plate 76 is displaced towards the front of the jig 10 through a distance sufficient to bring the block 66 into abutment with a stop 128 (Figure 3) depending from the top of the housing 14 to thereby locate the clamp bar 50 in the position in which it is shown in Figure 15 for the cutting of the tails.

By adjusting the clamp bar 52 towards the clamp bar 50, a vertically extending workpiece 130 is then clamped in the horizontally closable clamp 48 and, as can be seen from Figure 13, this workpiece 130 is then positioned correctly for the cutting of half blind tails instead of through tails.

As shown in Figure 13, blocking members 127 are inserted between the tail guide members 40a to prevent the entry of the router bit between the tail guide members 40a.

The blocking members 127 are secured to the guide member support 36 in the same manner as the tail guide members 40a.

In order to enable the pins to be cut in this case, as illustrated in Figures 14 and 16, a horizontally extending workpiece 132 is inserted through an opening 134 in the rear of the jig housing 14 and secured by means of the vertically closable clamp 86, and pin guide members 135 are mounted on the guide member support 36.

By mounting one of the guide members 135 on the guide member support 35 and subsequently on the guide member support 36, the jig 10 may be employed to cut a tenon.

The depth of cut of the router bit during the cutting operations shown in Figures 15 and 16 determines the fit of the half-blind dovetails and pins.

The safety plate 28 may be removed to allow a workpiece to project to the front of the jig, 10, e. g. for cutting a mortice in the workpiece.

As shown in Figure 17, the end of the opening 134 is formed with a shoulder 136, the purpose of which is to accommodate a workpiece 138 formed with a rabbet 140. It is to

be noted that the shoulder 136 serves as a reference stop which determines the position of the workpiece during the cutting of the half-blind pins. Consequently, the pins are cut so as to be correctly aligned with the tails.

Figure 18 shows a securing bolt 142 inserted through a boring in the workbench 12 into threaded engagement with a threaded hole 144 in the housing 14 for releasibly securing the housing 14 to the workbench 12.

Figure 18 also shows a shouldered securing screw 146 which is inserted through a washer 148 and which abuts the plate 76 and extends through a slot 150 in the plate 76 into threaded engagement with a post 152 depending from housing 14 and serving to support the plate 76.

As shown in Figure 3, the blocks 66 and 68 are provided with upstanding pointers 156, which project upwardly through a slot 158 (Figure 1) in the top of the housing 14. A scale 159 on the top of the housing 14 adjacent the slot 158 can be used for centering the workpiece and to enable the clamp bar 52 to be readjusted back into a previous position, when required.

The raised portion 16 at the front of the jig 10 near the safety plate 28 is provided on a metal strip 160, which is releasibly secured to the jig housing 14 by screws 162. On removal of the strip 160, a rectangular template (not shown) can be secured to the jig housing 14 by bolts (not shown) engaged through slots 164 formed in ledges 165 at opposite ends of the opening 18 and secured by nuts (not shown). The template may be formed with a straight slot or slots of other shapes, e. g. in the form of letters or numbers or decorative shapes.

Figure 19 shows a broken-away view, in perspective, of a modification of the router bit guide arrangement of the jig 10 of Figures 1 through 18.

In this modified router bit guide arrangement, the elongate guide member support 36 has been replaced by an elongate guide member support 236 which, instead of the T-shaped locating formations 38, is provided with vertically upwardly extending cylindrical projections 23 8, which are uniformly spaced apart from one another in a linear row along the top of the guide member support 236. The guide member support 35 has also been replaced by a modified guide member support (not shown) which is similar to the guide member support 236.

The router guide member, which in this case is indicated by reference numeral 240, is similar to the guide member 40 shown in Figure 6 but, instead of the teeth 46 of the guide member 40, is formed with a row of openings 246. These openings 246 are elongate and are dimensioned and spaced apart so as to be interengageable with the cylindrical projections 238, as shown in Figure 19, for securing the guide member 240 to the guide member support 236.

As will be readily apparent to those skilled in the art, other types of interengageable locating formations may alternatively be provided on the guide members and the guide member support for releasibly securing the guide members to the guide member support.

The guide members 40 and 240, referred to above and illustrated in the drawings, are shaped to form conventional dovetail joints. However, as will also be readily apparent to those skilled in the art, the shapes of the guide members and, more particularly, the surfaces of the guide members used for guiding contact with the router may be modified to produce other, unconventional shapes such as the joints indicated generally by reference numeral 250 in Figure 20A and reference numeral 252 in Figure 20B.

The angle of the dovetails cut by the present jig can be varied in a very simple manner by replacing the guide members 40 or 240 by similar guide members having different angles.

Figures 20A and 20B also show mortice and tenon joints, indicated generally by reference numerals 254 and 256, of unconventional shape, which can be cut employing the present woodworking jig.

Figure 21 shows a view in horizontal cross-section through a modification of the clamping arrangement of the jig of Figure 1.

In Figure 21, in which the jig housing is indicated by reference numeral 300, first and second clamp bars are indicated by reference numerals 302 and 304, respectively. The clamp bar 302 is supported, at opposite ends of the clamp bar 302, by a pair of threaded shafts 306 and 308 which arejoumalled in horizontally split bearings 310 on the housing 300. The threaded shafts 306 and 308 are in threaded engagement with opposite solid ends 312 and 314 of the clamp bar 302. A belt and sprocket transmission, indicated generally by reference numeral 316, interconnects the shafts 306 and 308, so that rotation of the shaft 308 will cause a corresponding rotation of the shaft 306. For this purpose, the shaft 308 is formed, at its end facing the front of the housing 300, with a socket 318, into which an actuating knob 56 can be inserted, through an opening 320 in the front of the housing 300. The shafts 306 and 308 and the belt and sprocket transmission 316 thus form an adjustment mechanism for adjustably displacing the clamp bar 302 horizontally to and fro.

The clamp bar 304 is connected to the clamp bar 302 by a connection which comprises a pair of threaded shafts 322 and 324, which are freely rotatably secured to the clamp bar 304 and which are in threaded engagement with the end members 312 and 314 of the clamp bar 302. Helical compression springs 325 on the shafts 322 and 324 bias the clamp bars 302 and 304 apart from one another. The shafts 322 and 324 are interconnected by a belt and sprocket transmission indicated generally by reference numeral 326, and the shaft 324, at its end facing the front of the housing 300, is formed with a socket 328, so that an actuating knob similar to the actuating knob 56 can be inserted through an opening 330 in the front of the housing 300 into engagement with the

shaft 324 for rotating the shafts 322 and 324 and, thereby, moving the clamp bar 304 horizontally towards or away from the clamp bar 302.

For limiting the movement of the clamp bar 302 towards the rear of the housing, an adjustable stop in the form of a knurled threaded bush 332 and a knurled locking nut 334 are in threaded engagement with the shaft 308 and are manually accessible through a side opening 336 in the housing 300.

Belt tensioners, indicated generally by reference numerals 338 and 340 are secured to the rear wall of the housing 300 and to the clamp bar 304, respectively, and each comprise a replaceable cylindrical roller 342 on a screw 344, the roller 342 being in rolling engagement with the respective belt and being replaceable by a roller of larger diameter when necessary to tighten the belt.

It is to be understood that the clamping arrangement illustrated in Figure 21 replaces that shown in Figure 3 in a jig which is otherwise similar to that of Figure 1 and which, therefore, includes a router support, on the top of the housing 300, which is similar to that described above with reference to the jig 10, a router bit guide arrangement similar to that described above with reference to Figures 1 through 18 or Figure 19, and front and rear openings in the housing, similar to those described above with reference to the embodiment of Figures 1 through 18.

Figure 22 shows, in a diagrammatic vertical cross-sectional view, a modification of the above-described jigs which is a simplified clamping jig, indicate generally by reference numeral 400, for use in cutting dovetail joints only.

In Figure 22, the housing of the jig 400 is indicated generally by reference numeral 402 and, corresponding to the above-described jigs, has a router support comprising guide surfaces 404 provided on the top of the housing 402 around and above an opening 406, which is of elongate, rectangular shape and has, along one side of the opening, a guide

member support 408 which is similar to the guide member supports 36 of Figures 1 through 18 and which, therefore, will not be described in greater detail.

The guide member support 408, together with guide members similar to the above- described guide members 40, form a router bit guide arrangement which is located between the router support and a clamping arrangement indicated generally by reference numeral 410.

The clamping arrangement 410 has an elongate clamp member in the form of a clamp bar 412, which has, on opposite sides of the clamp bar 412, first and second oppositely directed clamping surfaces 414 and 416.

The clamping arrangement 410 also includes a fixed first abutment, indicated generally by reference numeral 418 and an adjustable second abutment, indicated generally by reference numeral 420.

The first abutment 418 is formed by a pair of vertically spaced, horizontal flanges 422 and 424 on the housing 402, which are formed with co-planar first abutment surfaces 426 and 428.

The second abutment 420 comprises a U-shaped channel member 430 having a pair of vertical co-planar second abutment surfaces 432 and 434 facing towards the front of the housing 402.

The surfaces 426 and 428, and also the surfaces 432 and 434, are spaced apart vertically from one another by a distance sufficient to allow the clamping bar 412 to pass therebetween, so that the clamping bar 412 can be moved between a first operational position, in which it is located between the surfaces 426 and 428 and in which it is shown in full lines in Figure 22, and a second operational position, in which it is located between the surfaces 432 and 434 and in which it is shown in broken lines in Figure 22.

The second elongate abutment 420 is mounted for displacement towards and away from the first elongate abutment 418 by means of an adjustment device indicated generally by reference numeral 440 in Figure 22. This adjustment device comprises a threaded shaft 442, which is rotatably adjustable by means of the adjustment knob 56, which is not shown in Figure 22 but which engages a head 443 of the shaft 442. The shaft 442 is in threaded engagement with the clamping bar 412 and is provided with a stop in the form of a knurled threaded bush 444, which is rotatably engaged in the abutment 420, and a knurled lock nut 446.

In a first operational clamping position, the clamp bar 412 is spaced from the co-planar surfaces 432 and 434 by a distance D1 for clamping a workpiece during the cutting of through dovetail pins or through dovetail tails in the workpiece.

By adjusting the position of the channel member 430, by means of the threaded bush 444 and the lock nut 446, the thickness of the dovetail pins can be adjusted to fit the tails of the joint.

To clamp a workpiece for cutting half-blind tails, the clamping bar 412 is adjusted into a second operative or clamping position, shown in broken lines in Figure 22, in which a workpiece can be clamped between the second clamping surface 414 and the first abutment surfaces 426 and 428, which are spaced apart by a distance D2.

It is an advantage of the above-described jigs according to the invention that, once the position of one of the horizontally closable clamp bars has been adjusted, workpieces of different thicknesses are accommodated by the horizontally closable clamp during the cutting of through dovetails and, therefore, there is no need for the users to subsequently readjust the jigs, as was necessary in prior art jigs.

Thus, in the embodiment of Figures 1 through 20B, when the adjustment screw 77 has once been adjusted and locked, no further adjustment is necessary. In the embodiments

of Figures 21 and 22, the threaded bush 332 and the adjustment device 446 can each be adjusted once and subsequent readjustment is then not necessary.

Also, the jigs can be used to cut half-blind dovetails without readjustment to take into account different workpiece thicknesses.

Thus, in the jig of Figures 1 through 20B, the block 66 is simply moved back into abutment with the stop 128, as described above, for this purpose. In the embodiment of Figure 21, a stop (not shown) acting as an abutment for the clamp bar 304 serves the same purpose, and in the embodiment of Figure 22 the abutment surfaces 426 and 428 are fixed and therefore do not require readjustment.

It is also an advantage of the jig according to the present invention that it is simple to use, without requiring any special tools. The cutting region, at which the router bit cuts the workpiece, is fully enclosed in the jig housing, thus reducing the risk of injury to the user.

The router is supported on the jig housing, and not on the pin and tail guide members, and is supported on both sides of the opening in the jig and therefore cannot tip. The safety glass plate allows the user to safely observe the router bit and the workpiece while protecting the user from flying wood waste and shattered router bit pieces. The pin and tail guide members can be positioned securely and incrementally and can readily be repositioned to provide precision repeatability.

In prior art jigs employing a removable finger assembly for guiding the router, there has been a risk that the finger assembly may be secured in a position which is not parallel to the workpiece. With the present jigs, however, the guide member supports are fixed to the jig housing and the clamp bars, and thus the workpiece, are maintained parallel to the guide member supports.

Figure 23 shows a view in vertical cross-section through a clamping arrangement in a further embodiment of the present invention. As shown in Figure 23, a jig housing indicated generally by reference numeral 502 has, at its top, an opening 506,

corresponding to the opening 18 of Figure 1, and a pair of elongate parallel raised top portions having coplanar router guide surfaces 504, corresponding to the surfaces 20 of Figure 1, and also a pair of parallel elongate guide member supports 508 extending along opposite sides of the opening 506 for supporting guide members 40,40a, in a manner which will be apparent from the above description of the embodiment of Figure 1.

The housing 402 includes a pair of flanges 510 and 512, in which there is journalled a shaft 514 provided at one end with a head 516 for engagement with the adjustment knob 56, the shaft 514 having opposed threads 518 and 520 in threaded engagement with a pair of clamping bars 522 and 524 so that, on rotation of the shaft 514, the clamping bars 522 and 524 are moved towards or away from one another, depending on the direction of rotation of the shaft 514.

An endless belt 526 engages sprockets on the shaft 514 and on a further shaft (not shown) corresponding to and parallel to the shaft 514 and likewise in threaded engagement with the clamping bars 522 and 524, so that both shafts are rotated simultaneously.

The clamping arrangement illustrated in Figure 23 is suitable for some types of midboard joinery, such as the male joint element of mortice and tenon joints, housing joints and dowelled joints, which require a vertically clamped workpiece to be always centered in the jig mouth or opening 506.

In the above-described embodiments, the opposed elongate guide member supports, e. g. the supports 35 and 36 of the embodiment of Figure 1, are formed in one piece with the j ig housing. It is, however, alternatively possible to provide these guide member supports on an elongate, rectangular removable top portion or section, indicated generally by reference numeral 601, as shown in Figure 24A, of a jig housing 604, which is otherwise similar to the housing 14 of Figure 1. The top section 601 of the housing 604 is formed with an opening 603, corresponding to the opening 18 of figure 1, with a flat surface 605 on opposite sides and at opposite ends of the opening 603. The surface 605 is located above the level of the tops of the guide members 40 and 40a, when they are installed in

the opening 605 on the guide member supports 35 and 36, so that a router base supported on the surface 605 does not contact the guide members 35 and 36.

When this top section 601 has been removed from the housing, it may be replaced by a template, indicated generally by reference numeral 600 in Figure 24B, which as can be seen fits into a recess 602 in the top of the housing 604.

The rectangular template defines an opening 606, corresponding to the opening 18 of Figure 1, with guide fingers 608 formed in one piece with the template 600 and projecting into the opening 606.

Along opposite sides of the opening 606, the upper surface 610 of the template 600 is spaced upwardly from the tops of the guide members 608 so that, as will be apparent from the above description, a router base plate (not shown) may be supported on the surface 610 above the fingers or guide members 608 so that the router does not exert a downward force on the guide members 608.

Half-blind dovetail joints which are cut by use of the template 600 require that the dovetail pins be offset from the dovetail tails by an amount equal to half the pitch of the template 600, which is indicated by P in Figure 24. For this purpose, there is provided under the template 600 a pivotal stop arm 612 which can be swung rearwardly so as to abut against one of a pair of flanges 613 at opposite ends of the housing. The arm 612 has a width which is dimensioned to off set the pin workpiece, when it is clamped in the horizontal clamping arrangement, so that the pin workpiece is stepped away from the flange 613 by an amount equal to half the pitch P of the template 600, thus ensuring that the joint is cut by means of the template 600 is correctly aligned.

The flanges 613 are also provided in the embodiment of Figures 1 to 16 and are employed as stops for the edges of the workpiece during the cutting of half-blind pins, as shown in Figure 14, and for other horizontally clamped workpieces.

In this way, the correct offset is set automatically and it is not necessary for the user of the jig to adjust anything on the jig in order to produce the correct amount of offset when cutting half blind dovetail joints, as is required with conventional templates and dovetail jigs.

The hinged stop arm 612 is secured beneath the housing 604 by a screw 616, extending through either of a pair of openings 617 in the template, so that the arm 612 can be readily removed from one end of the template for installation at the opposite end of the template 600.

Figure 25 shows a broken-away view corresponding to that of Figure 14 but showing a pair of modified dovetail pin guide members 135a which allow the user of the jig to position a workpiece for the correct cutting of half blind dovetail joint pins.

One of the guide members 135a is shown in greater detail in Figures 26 and 27 and is similar to the guide members 135 except that it has an adjustable abutment, indicated generally by reference numeral 700, into which there is threaded an adjustment screw 702. The adjustment screw 702 is provided with an annular shoulder 704 which, on tightening ofthe screw 702, seats against a shoulder 706, which extends around a slot 708 extending along longitudinally of the guide member 135a. As will be apparent from Figure 25, the two abutments 700 of the two guide members 135a engage the end edge of the workpiece 132 for limiting the distance to which the work piece 132 extends beneath the guide members 135 and 135a and, thus, define the depth of the half blind pins cut in the work piece 132.

As will be apparent to those skilled in the art, the embodiments of the present invention described above are useful for cutting joints between two workpieces which are intended to extend at right angles to one another when the joints are assembled. However, it is also desirable to be able to cut joints in workpieces which enable the workpieces to be assembled at an angle of 45° to 90° relative to one another, and Figures 28 and 29 show

a woodworking jig clamping arrangement, embodying the present invention, which is useful for that purpose.

As shown in Figures 28 and 29, a jig housing indicated generally by reference numeral 800 is provided with a top opening 802, guide members 804 extending along opposites sides of the opening 802, and raised router guide surfaces 806 which are coplanar and extend along opposite sides of the opening 802, all for the purposes which will be readily apparent from the description of the preceding embodiments.

The housing 800 is also formed with two flanges 808 and 809, in which a shaft 810 is journalled, the shaft 810 being provided with a head 812 engageable with the adjustment knob 56. The shaft 810 is one of a pair of similar parallel shafts, the other of which is indicated by reference numeral 814 in Figure 28, the shafts 810 and 814 being interconnected by a drive belt 816 for simultaneous rotation, as will also be apparent from the description of the above embodiments of the invention.

The shafts 810 and 814 are in threaded engagement with cylindrical members 816 which, therefore, are moved to and fro along the shafts 810 and 814 on rotation of the latter.

Each cylindrical member 816 has a lateral pivot pin 818, and the pins 818 engage in respective flanges 820 at opposite ends of a clamp bar 822. The clamp bar 822, therefore, can be rotatably adjusted about the common axis of the pins 818, and locking screws 824, in threaded engagement with the flanges 820, can lock the clamp bar 822 in position relative to the pins 818.

A second clamp bar 826, which is carried by and parallel to the clamp bar 822, is adjustable to and fro relative to the clamp bar 822 by means of threaded shafts 828, which are interconnected by a drive belt 830 for simultaneous rotation. The clamp bars 822 and 826 rotate together about the axis of the pins 818 on loosening of the screws 824.

The shaft 810 and 814 are provided with lock nuts 832, which can be used to limit the distance by which the cylindrical members 816 can be moved along the shafts 810 and 814.

As can be seen from Figure 29, a workpiece 834 can be supported at an angle to the horizontal and to the vertical, beneath the opening 802, for cutting of a correspondingly inclined joint, the degree of inclination of the workpiece being determined by the locking screws 824.

Figure 30 illustrates a clamping arrangement according to a still further embodiment of the present invention. In this clamping arrangement, a pair of clamp bars 902 and 904 are in threaded engagement, at opposite ends, with respective pairs of threaded shafts 906 and 908. The shafts 906 are connected, for simultaneous rotation, by an endless belt 910 and the shafts 908 are likewise connected by an endless belt 912.

The shafts 906 and 908 are journalled in bearings 914 and 916 formed on a housing, which is indicated generally by reference numeral 918, and are provided with heads 920 which are engageable by the adjustment knob 56.

The housing 918 is formed with an opening in the top of the housing, guide member supports extending along the opening and router guide surfaces extending along opposite sides of the opening, all in a manner which will be readily apparent from the description of the above embodiments.