The present invention relates to a plate joiner including a fence support, a drive, and a fence system. The fence support includes a cutter and a contact surface, which defines a cutter slot. The cutter is arranged and configured to protrude from fence support through cutter slot to make a plunge cut into a surface of a workpiece when the contact surface is pressed against the surface and the cutter is plunged into the workpiece by pushing on a rearward handle portion of the tool. A motor is connected to the drive, which is arranged and configured to rotatably drive the cutter.
A preferred fence system includes an angle adjustment system arranged and configured to position the fence at a wide range of fence angles and, at any selected distance from a top face of the workpiece to the fence, the distance from the top face of the workpiece to the cutter remains constant as the front fence angle is adjusted. A preferred fence system includes a trunnion which pivotally couples the front fence to the fence system. A preferred fence system also includes an angle segment member, which has two slots used to position the fence in two ranges of fence angles.
A plate joiner makes a plunge cut in a joint surface of a piece of wood which allows the piece of wood to be joined to another piece of wood having an oppositely disposed groove. A biscuit (a thin plate of wood or other material) and glue are placed in the grooves, and the pieces of wood are joined to provide an accurate and strong joint. A plate joiner generally includes a housing, a drive unit, and a rotating cutter. A portion of the housing contacts a joint surface and, as a portion of the housing is pushed forward, the rotating cutter moves forward, engages the joint surface at the desired location, and cuts into the joint surface. Releasing forward pressure on the housing then retracts the cutter. Thus, a plate joiner provides an easy method of producing a strong and aesthetic joint in wood.
The cutter is driven by a drive including a motor located within the housing, and a gear system driven by the motor and located in a forward gear housing portion of the housing. The gear system includes a motor driven shaft rotatably driven by the motor, a generally right angle coupling of the motor driven shaft, using beveled gear, to a cutter shaft that rotatably drives the cutter. The rotating cutter is configured to cut into the joint surface.
The preferred plate joiner tool can be configured into many highly versatile configurations. The plate joiner system is arranged and configured with a fence that can be positioned in a wide range of fence angles and, at any selected distance from a top face of the workpiece to the fence, the distance from the top face of the workpiece to the cutter remains constant as the front fence angle is adjusted. The plate joiner is configured for substantially continuous adjustment of fence height while restraining lateral and tortional movement of the fence and providing an accurate measure of the height of the fence from any point in the thickness of the blade. The plate joiner system is also arranged and configured to provide a plurality of release positions that reduce the distance traveled in making a plunge cut for a smaller blade and to prevent a blade from protruding from the tool in a release position. Such versatility is found in no other plate joiner system.
To accomplish this, the present plate joiner system preferably includes a fence system including an angle adjustment system having a trunnion and an angle segment member. The angle segment member includes two slots used to position the fence in two ranges of fence angles. The plate joiner system, preferably, also includes a height adjustment system including an adjustment screw arranged and configured to provide substantially continuous adjustment of fence height and guide pins which restrain lateral and tortional movement of the fence at the height it is adjusted and locked. A preferred plate joiner system also includes a cutter plunge system 86 arranged and configured for sliding the cutter from one of a plurality of release positions to a plunge position. A preferred plate joiner includes a cutter inside a removable cutter base cover.
The preferred plate joiner system includes a fence support 14, a drive 170, and a fence system 129 (see
A preferred fence system 129 includes a front fence 12 and an angle adjustment system 39, which is arranged and configured for adjusting an angle of front fence 12. Using this preferred fence system 129, at any selected distance from a top face of the workpiece to the front fence 12, the distance from the top face of the workpiece to cutter 113 remains constant as the angle of front fence 12 is adjusted. The preferred mechanism for accomplishing this is described further below. Front fence 12 includes a planar face 40, which, at a fence angle of 0°, is coplanar with contact surface 24. At fence angles greater than 0°, planar face 40 of front fence 12 defines a plane that intersects with the plane of contact surface 24. The distance from this intersection to any particular part of cutter 113 is the distance from a top face of the workpiece to any particular part of cutter 113. As shown in
Front fence 12 pivots with respect to fence support 14 and cutter 113 by employing angle adjustment system 39. Angle adjustment system 39 and front fence 12 define an axis on which front fence 12 pivots. When this pivot axis is not in the plane of contact surface 24, that is, when this pivot axis is in front of or behind the contact surface, the distance from the top face of the workpiece to any particular part of cutter 113 changes as the front fence angle is varied. Advantageously, angle adjustment system 39 and front fence 12 are arranged and configured to provide a pivot axis substantially in a plane defined by contact surface 24. This orientation of the pivot axis is a way to achieve a fence system in which, at any selected distance from a top face of the workpiece to any particular part of cutter 113, [the distance from the top face of the workpiece to the particular part of cutter 113], remains constant as a front fence angle is adjusted.
Advantageously, angle adjustment system 39 employs a trunnion 41 to pivot front fence 12 on a pivot axis in a plane defined by contact surface 24. A trunnion typically includes a cup shaped receptacle which supports a rod or disk on which a device swivels. For example, the two opposite gudgeons on which a cannon swivels or pivots vertically form a trunnion. In this respect, a trunnion is particularly useful for providing a consistent vertical pivot motion without substantial lateral play.
Trunnion 41, in which a generally semicircular cup 42 receives a generally semicircular disk 43, is a mechanism that provides a pivot axis that is in the plane of contact surface 24. Cup 42 is defined by an arcuate ridge member 44. Disk 43, is a portion of groove member 45, which defines an arcuate groove 46 around disk 43. Arcuate groove 46 pivotally engages ridge member 44 in a manner such that disk 43 is retained in cup 42. Preferably, front fence 12 includes groove member 45 and rear fence 13 includes ridge member 44.
In the embodiment shown in the Figures, rear fence 13 includes a rear fence member 47 and a trunnion member 48, which includes a groove member 45. Generally, ridge member 44 can be a component of either front fence 12 or rear fence 13, groove member 45 can be a component of whichever of front fence 12 or rear fence 13 does not include ridge member 44, and trunnion member 48 can include either ridge member 44 or groove member 45.
In the embodiment shown in the Figures, trunnion 41, includes left side trunnion pivot member 31 including ridge member 44 and groove member 45, and a right side trunnion pivot member 32 including ridge member 44 and a groove member 45. Generally trunnion 41 will include two trunnion pivot members, although a single member can include the features of both right side and left side trunnion pivot members.
Trunnion 41 can be arranged and configured to provide a pivot axis in a plane defined by contact surface 24, in a plane defined by planar surface 40 of front fence 12, in both of these planes, or in neither of these planes.
A preferred embodiment of the plate joiner system includes, as part of the system for adjusting the fence angle, an angle segment member 15 arranged and configured to position front fence 12 at a selected angle between a plane defined by planar surface 40 of front fence 12 and a plane defined by contact surface 24. Angle segment member 15 defines first slot 49 and second slot 50, which are arranged and configured to position the fence in a first and second range of fence angles, respectively.
First angle scale 29 and second angle scale 30 are each associated with an angle indicator, first angle indicator 54 and second angle indicator 55, respectively. When front fence 12 is positioned in the first range of fence angles, first angle indicator 54 is generally adjacent to first angle scale 29 and indicates the fence angle on first angle scale 29. When front fence 12 is positioned in the second range of fence angles, second indicator 55 is generally adjacent to second angle scale 30 and indicates the fence angle on second angle scale 30.
Advantageously, first angle indicator 54 is not adjacent to first angle scale 29 when front fence 12 is positioned in the second range of fence angles. That is, angle segment 15 moves so that first angle indicator 54 is dissociated from first angle scale 29 when front fence 12 is positioned in the second range of fence angles (see-
In another preferred embodiment, angle adjustment system 39 is arranged and configured to provide a positive stop at one or more fence angles. For example, angle segment member 15 can include a stop member, such as tab 56, that contacts another portion of the fence system to provide a positive stop. Such a positive stop can be adjustable if either tab 56 or the part contacted by tab 56 includes a stop adjustment mechanism, such as an adjustable set screw.
Front fence 12 can be retained at a desired fence angle. Angle adjustment system 39 includes an angle locking system 57. Angle locking system 57 includes angle locking knob 3 that is arranged and configured to bias against angle segment member 15. Angle locking knob 3 is threadably engaged on a pin (not shown) that slidably engages slots 49 and 50 in angle segment member 15. Knob 3 when tightened on the threaded pin biases angle segment member 15 against rear fence 13.
The preferred plate joiner system includes a height adjustment system 58, which is a subsystem of fence system 129. Height adjustment system 58 is preferably arranged and configured to adjust the distance from the top face of a workpiece to the cutter in a substantially continuous manner and with torsional and lateral stability. Optionally, height adjustment system 58 can provide a combination of rapid, discontinuous height adjustment to approximately the desired fence height, and substantially continuous adjustment to achieve the desired fence height.
Height adjustment system 58 achieves substantially continuous adjustment of fence height using a threaded rod 59. Threaded rod 59 is supported by and rotatably retained by a vertical member 60 portion of fence support 14 and threadably engages rear fence 13. Vertical member 60 and rear fence 13 are both substantially perpendicular to cutter 113. Threaded rod 59 does not move vertically relative to vertical member 60, and as threaded rod 59 is rotated, rear fence 13 moves up and down relative to vertical member 60 and cutter 113. Since front fence 12 is pivotally attached to rear fence 13, front fence 12 also moves vertically with rear fence 13 and relative to cutter 113.
Threadable engagement of rear fence 13 with threaded rod 59 results in substantially continuous vertical adjustment of the fence. Small increments of rotation allow small increments of vertical movement on the incline of the threads. In a preferred embodiment, by knowing the pitch of the thread, each revolution or partial revolution provides a predetermined height adjustment. Optionally, using a quick release screw 80 rear fence 13 can disengage from the threads of threaded rod 59, for rapid, discontinuous height adjustment. When the approximate fence height is achieved by discontinuous adjustment, rear fence 13 can reengage the threads of threaded rod 59 for continuous adjustment to the desired fence height.
Height adjustment is achieved with torsional and lateral stability by using first guide rod 61 and second guide rod 18 to guide vertical adjustment of rear fence 13. As shown in the Figures, first guide rod 61 and second guide rod 18 are components of fence support 14. Guide rod frames 62 and 63 are components of rear fence 13. In this way, guide rods 18 and 61 are retained by fence support 14 vertical member 60, and cannot move vertically relative to vertical member 60. Yet, guide rods 18 and 61 slidably engage rear fence 13, so that rear fence 13 can slide vertically relative to the guide rods for height adjustment.
As shown in
Height adjustment system 58 includes a height locking system 82 for securing front fence 12 at the desired height and for providing reproducible lateral and torsional positioning and stability of front fence 12 at different heights. Height locking system 82 includes height locking knob 84, threaded pin 66 and plug 19. Height locking system 82 is arranged and configured to bias against a second guide rod 18 and to bias first guide rod 61 against first guide rod frame 62. Individual components of height locking system 82 are configured to bring this about. Turning knob 84 threadably advances threaded pin 66 into rear fence 13 which biases plug 67 against guide rod 18. As this biasing continues rear fence 13 is moved laterally through a distance less than the space surrounding first guide pin 61, and first guide pin 61 is biased against guide rod frame 62. Biasing guide rod 61 against guide rod frame 62 provides reproducible and stable lateral and torsional positioning of rear fence 13, and front fence 12.
The preferred fence system also includes a height gauge 68, which is arranged and configured to provide a reading of fence height relative to any point on the thickness of cutter 113, which corresponds to any point in the thickness of the slot cut by cutter 113. In an especially preferred embodiment, height gauge 68 provides an accurate reading of fence height at any fence angle.
Height gauge 68 includes a scale 10 and a height indicator 69. As shown in the figures, height scale 10 is arranged on a surface of fence support 14 vertical member 60, and height indicator 69 is on rear fence 13 generally adjacent to vertical member 60. Height indicator 69 includes a visible indicator 70 with a thickness along the height scale 10 substantially equivalent to the thickness of the cutter that indicates fence height using height scale 10. In one preferred embodiment, visible indicator 70 is in the shape of a raised rectangle.
As a consequence of this arrangement, by visualizing measurement along the thickness of the visible indicator 70, height gauge 68 indicates the distance from a face of the workpiece to any point in the thickness of cutter 113. With this arrangement of the height gauge and a preferred embodiment of the angle adjustment system, in which at any selected distance from a top face of the workpiece to the fence, the distance from the top face of the workpiece to the cutter remains constant as the front fence angle is adjusted, the height gauge is accurate each selected front fence angle.
In making a plunge cut with the plate joiner, cutter 113 starts in a release position and, as contact surface 24 is pressed against the workpiece, by pushing on a rearward handle portion of the tool, cutter 113 moves forward to a plunge position while cutting a slot in the workpiece. Preferably, in a release position, cutter 113 is completely within fence support 13, which includes cutter housing cover 16, and cutter housing base 17. If such a plate joiner has only a single release position and can use different sized blades, a smaller blade must travel a greater distance before it contacts the workpiece, which is an inconvenience for the plate joiner operator.
Preferred cutter sizes include diameters of about 4 inches and about 2 inches. A more convenient arrangement provides a plurality of release positions to reduce the distance from release position to plunge position for smaller blades.
A preferred embodiment of the plate joiner system includes a cutter plunge system 86 arranged and configured for sliding cutter 113 from one of a plurality of release positions to a plunge position. The release positions are configured to reduce the distance between the release and plunge positions as cutter size is reduced. Preferably the distance from the forward edge of the blade in the release position to the contact surface is approximately constant for different sized blades in different release positions.
Cutter plunge system 86 includes safety lever system 71, which is arranged and configured to position the cutter at one or more release positions. Safety lever system 71 includes pivot pin 28, which can be a rivet, safety lever 25, and guide pin 26. Safety lever 25 pivots on pivot pin 28 and guide pin 26 engages an aperture 72 in blade housing cover 16 and stoppably engages lower gear housing 73 to retain the cutter in the release position.
The plurality of release positions configures the plate joiner system to advantageously house cutters of two more different sizes. For example, a four inch cutter is advantageous for general use, and a smaller, two inch, cutter is advantageous for applications such as joining face frames. The preferred plate joiner system can house either a two inch blade or a four inch blade, and the cutter plunge system 86 provides for reduced travel of the two inch cutter.
In the release position providing reduced travel for a smaller blade, safety lever 25 prevents installing a larger blade, preferably by physically blocking installation of the larger blade. In such a manner, a safety lever prevents installing a large blade in a release position in which it would protrude from the cutter slot in the release position. The larger blade is accommodated at a more rearward release position.
In a forward position, safety lever 25 is configured to direct cutting dust toward dust aperture 74. The slightly arcuate shape of safety lever 25 provides smooth circulation of air and dust when safety lever 25 is in a rearward release position, and aids in directing dust towards aperture 74 when safety lever 25 is in a forward release position.
The above specification, examples and data provide a complete description of the manufacture and use of the composition of the invention. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.
The present application is a Continuation and claims priority under 35 U.S.C. § 120, to U.S. patent application Ser. No. 10/603,280 now U.S. Pat. No. 6,896,016 entitled: Plate Joiner, filed on Jun. 25, 2003 which in turn is a Continuation and claims priority under 35 U.S.C. of §120, to U.S. patent application Ser. No. 10/042,536, now U.S. Pat. No. 6,612,349 entitled: Plate Joiner, filed on Jan. 8, 2002 (issued Sep. 2, 2003), which in turn is a Continuation and claims priority under 35 U.S.C. §120, to U.S. patent application Ser. No. 09/276,393, now U.S. Pat. No. 6,422,275 entitled: Plate Joiner, filed on Mar. 25, 1999 (issued Jul. 23, 2002) which in turn is a Continuation and claims priority under 35 U.S.C. §120, to U.S. patent application Ser. No. 08/872,015, now U.S. Pat. No. 6,336,483 entitled: Plate Joiner Fence Angle Adjustment System, filed on Jun. 9, 1997 (issued Jan. 8, 2002) all of which are hereby incorporated by reference in their entirety.
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Number | Date | Country | |
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Parent | 10603280 | Jun 2003 | US |
Child | 11080122 | US | |
Parent | 10042536 | Jan 2002 | US |
Child | 10603280 | US | |
Parent | 09276393 | Mar 1999 | US |
Child | 10042536 | US | |
Parent | 08872015 | Jun 1997 | US |
Child | 09276393 | US |