Power Tool

Information

  • Patent Application
  • 20230058597
  • Publication Number
    20230058597
  • Date Filed
    October 26, 2022
    2 years ago
  • Date Published
    February 23, 2023
    a year ago
Abstract
A power tool having a housing and a motor assembly arranged to rotate a cutting tool. The power tool has at least one guide post slidably mounted to the housing and a base fixed to the guide post. A plunge locking lever is mounted to the housing. The plunge locking lever is moveable between a locked position wherein the guide post is fixed with respect to the housing and an unlocked position wherein the guide post is slidable with respect to the housing thereby adjusting the distance between the base and the housing wherein the plunge locking lever is biased to the locked position. A catch mechanism engages the plunge locking lever in the unlocked position. The catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.
Description
FIELD OF THE INVENTION

The present invention relates to a power tool and in particular a plunge router.


BACKGROUND OF THE INVENTION

A power tool such as a router may be utilized by tradesmen, craftsmen, hobbyists, and other users to perform various tasks. For instance, a router may be used to perform intricate cutting projects, such as decorative profiles and trimming laminates on the edges or perimeters of a workpiece. A router also may be utilized to form grooved areas in woodworking and other material as well as to remove excess material on workpieces. Routers may utilize various types of cutting tools or router bits in order to perform these and other types of tasks.


A router normally comprises one or more handles allowing the user to grip the router during operation. This means that the user can manoeuvre the router with respect to the workpiece. It is known for a router to vary the height of the cutting tool with respect to the workpiece during operation. This is also known as a “plunge” mode of operation. The plunge mode allows the user to plunge the cutting tool of the router into the workpiece in order to cut a hole in the middle of the workpiece. The user may select between the plunge mode and a fixed mode whereby the cutting tool is maintained at a fixed distance during operation.


One router is shown in U.S. Pat. No. 6,261,036 having a plunge router locking system. The plunge router locking system has a lock lever arm which has two positions, a locked and unlocked position. In the unlocked position, the lock lever arm may be held in place by the operator or by a mating catch device. When the operator wants to move the lock arm lever back to the locked position, the operator applies sufficient force to the lock arm lever and the mating catch device releases the lock arm lever.


A problem with this arrangement is that the lock arm lever can be accidentally knocked by the user and the lock arm lever will return to the locked position. Furthermore, the mating catch device is prone to failure over time because the user must keep applying force on the lock arm lever to release the lock arm lever.


Examples of the present invention aim to address the aforementioned problems.


SUMMARY OF THE INVENTION

According to an aspect of the present invention there is a power tool comprising: a housing; a motor assembly arranged to rotate a cutting tool, the motor being mounted in the housing; at least one guide post slidably mounted to the housing; a base fixed to the at least one guide post; a plunge locking lever mounted to the housing moveable between a locked position wherein the at least one guide post is fixed with respect to the housing and an unlocked position wherein the at least one guide post is slidable with respect to the housing thereby adjusting the distance between the base and the housing wherein the plunge locking lever is biased to the locked position; and a catch mechanism arranged to engage the plunge locking lever in the unlocked position; wherein the catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.


Optionally, the plunge locking lever is moveable to a manually held unlocked position between the locked position and the unlocked position.


Optionally, the catch mechanism comprises a first part mounted on the release lever engageable with a second part mounted on the plunge locking lever.


Optionally, the first part is a hook, and the second part is a reciprocal groove.


Optionally, the release lever is pivotable between a first position wherein the catch mechanism is engaged and a second position wherein the catch mechanism is disengaged.


Optionally, the release lever is biased to the first position.


Optionally, the plunge locking lever is fixed to a rod releasably engageable with the at least one slidable guide post.


Optionally, the rod is threaded through a spring arranged to bias the plunge locking lever.


Optionally, the plunge locking lever is rotatable between the locked position and the unlocked position.


Optionally, an axis of rotation of the plunge locking lever intersects with a pivot axis of the release lever.


Optionally, at least a portion of the release lever extends adjacent to the plunge locking lever when the plunge locking lever is engaged in the unlocked position.


Optionally, the plunge locking lever comprises a rotatable inner surface engageable with an outer surface of the release lever.


Optionally, the rotatable inner surface engages the outer surface the plunge locking lever is in the locked position and urges the release lever into the second position.


Optionally, the plunge locking lever and the release lever are mounted adjacent to a handle of the router.


Optionally, the plunge locking lever and the release lever are actuatable with a user's thumb when the user grips the handle.


Optionally, the power tool is a router, a plunge saw, a drill, a multitool, an oscillating tool.


According to another aspect of the present invention there is a locking system for a power tool comprising a housing, a motor assembly arranged to rotate a cutting tool, the motor being mounted in the housing, at least one guide post slidably mounted to the housing, and a base fixed to the at least one guide post, the locking system comprising: a plunge locking lever moveable between a locked position wherein the at least one guide post is fixed with respect to the housing and an unlocked position wherein the at least one guide post is slidable with respect to the housing thereby adjusting the distance between the base and the housing wherein the plunge locking lever is biased to the locked position; and a catch mechanism arranged to engage the plunge locking lever in the unlocked position; wherein the catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.


According to yet another aspect of the present invention there is a plunge base for a power tool, the plunge base comprising: a tool mount for mounting the power tool to the plunge base; at least one guide post slidably mounted to the tool mount; a base fixed to the at least one guide post; a plunge locking lever mounted to the tool mount moveable between a locked position wherein the at least one guide post is fixed with respect to the tool mount and an unlocked position wherein the at least one guide post is slidable with respect to the tool mount thereby adjusting the distance between the base and the tool mount, wherein the plunge locking lever is biased to the locked position; and a catch mechanism arranged to engage the plunge locking lever in the unlocked position; wherein the catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.


Various other aspects and further embodiments are also described in the following detailed description and in the attached claims with reference to the accompanying drawings, in which:





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 shows a front view of a router according to an example;



FIGS. 2a, 2b, 2c show close up-front views of a router in different modes according to an example;



FIG. 3 shows an exploded perspective view of a locking system of a router according to an example;



FIG. 4 shows a perspective view of a locking lever according to an example;



FIG. 5 shows a cross sectional side view of a locking system of the router according to an example;



FIG. 6 shows a cross sectional side view of a locking system of the router according to an example; and



FIGS. 7a and 7b show plan cross sectional views of a locking system of the router according to an example.





DETAILED DESCRIPTION


FIG. 1 shows a front view of a power tool 100 according to an example. The power tool 100 as shown in FIG. 1 is a router 100. Hereinafter, the power tool 100 will be referred to as a router 100, but in other examples any other type of power tool can be used such as a plunge saw, a drill, a multitool, or an oscillating tool mounted on a plunge base.


The router 100 comprises a housing 102. The housing 102 comprises a clam shell type construction having two halves which are fastened together. The halves of the housing 102 are fastened together with screws but in alternative examples any suitable means for fastening the housing 102 together may be used such as glue, clips, bolts and so on. For the purposes of clarity, the fastenings in the housing 102 are not shown.


A motor (not shown) is mounted in the housing 102 for driving a collet 104. A cutting tool (not shown) can be mounted in the collet 104 for engaging a workpiece (not shown).


As shown in FIG. 1, the router 100 comprises a base 106 for engaging the workpiece. The base 106 comprises an aperture through which the cutting tool projects. The base 106 is mounted to the housing 102 via first and second guide posts 108, 110. The first and second guide posts 108, 110 are slidably mounted to the housing 102 for adjusting the relative distance of the base 106 from the collet 104. In some examples, the first and second guide posts 108, 110 are removeable. This means that the router 100 can be used without the base 106 engaging the workpiece.


The housing 102 comprises a first and second handle 112, 114 for the user to grip during operation. The first handle 112 comprises a main trigger switch 116 for operating the router 100. In some examples, the first handle 112 also comprises a lock button 118 for selectively locking the main trigger switch 116 into an “ON” status. This means that the user does not have to constantly keep pressure maintained on the main trigger switch 116 during operation of the router 100. In some examples, the main trigger switch 116 can be replaced with a momentary switch (not shown).


The motor is electrically connected to an electric power source. In some examples, the electric power source is a mains electrical supply. In some other examples, the electrical power source is a battery (not shown). The battery can be removeably mountable to the housing 102 or integral to the housing 102. In some examples, the router 100 can be powered either from both a battery source and/or a mains electrical supply.


The router 100 as shown in FIG. 1 is a plunge router. Accordingly, the router 100 can be selectively operated in different modes. In a first mode, the router 100 is in a locked position. In the locked position, the first and second guide posts 108, 110 are fixed with respect to the housing 102. This means that the housing 102 and the collet 104 are fixed with respect to the base 106. Accordingly, the cutting tool can be maintained at a set height above the workpiece. This means that the user of the router 100 can select how far the cutting tool projects through the aperture in the base 106.


In a second mode, the router 100 is in an unlocked position. In the unlocked position the first and second guide posts 108, 110 are slidable with respect to the housing 102. This means that the user can push down on the first and second handles 112, 114 and the first and second guide posts 108, 110 slide into or through the housing 102. In this way, the distance between the base 106 and the housing 102 can be adjusted. This means that the user can position the router 100 above the workpiece and then push the housing 102 towards the workpiece and the cutting tool plunges into the workpiece.


As discussed hereinafter, the router 100 is configured to be set in a plurality of unlocked positions for different operation modes of the router 100.


The user can select between the locked and unlocked position of the router 100 by using a locking system 120 mounted on the router 100. In some examples, the locking system 120 is actuatable when the user grips the second handle 114. For example, the user can grip the second handle 114 and actuate the locking system 120 with their thumb or their fingers.


Turning to FIGS. 2a, 2b and 2c, the locking system 120 will be described in more detail. FIGS. 2a, 2b, 2c show close up-front views of a router 100 in different modes according to an example. The close-up front views of the router 100 are of the dotted box A as shown in FIG. 1.


As can be seen from FIG. 2a, the locking system 120 comprises a plunge locking lever 200 and a release lever 202.



FIG. 2a shows the plunge locking lever 200 in a locked position. In some examples, the plunge locking lever 200 is in the locked position in a vertical orientation. The plunge locking lever 200 is mechanically coupled to the first or second guide posts 108, 110 such that relative movement of the first and second guide posts 108, 110 is prevented when the plunge locking lever 200 is in the locked position. In some examples, the plunge locking lever 200 actuates a locking bolt 300 (as shown in FIG. 3). In this way, the locking bolt 300 exerts a frictional force against the first or second guide posts 108, 110 when the plunge locking lever 200 is in the locked position. Accordingly, the locking bolt 300 clamps against the first or second guide posts 108, 110 preventing relative movement therebetween. In some examples the locking bolt 200 optionally engages a reciprocal hole or detent (not shown) in the second guide post 110 and the housing 102. In other examples, an additional second locking bolt (not shown) is used to also engage with the first guide post 108. In other examples, other mechanisms can be used to lock the first and second guide posts 108, 110 such as a latch-catch mechanism, a ball bearing engaging a detent in the first and second guide posts 108, 110 or any other suitable mechanism.


The plunge locking lever 200 is moveable between the locked position shown in FIG. 2a and first and second unlocked positions as respectively shown in FIGS. 2c and 2b. In some examples, the plunge locking lever 200 is rotatable between the locked position and the first and second unlocked positions about the longitudinal axis X-X of the locking bolt 300 (as shown in FIG. 3). In some other examples, the plunge locking lever 200 is slidable between the locked position and the first and second unlocked positions. Mechanical linkages (not shown) may be coupled between the plunge locking lever 200 and the locking bolt 300 for actuating engagement between the locking bolt 300 and the first and second guide posts 108, 110.



FIGS. 2b and 2c show that the plunge locking lever 200 has been rotated into the first and second unlocked positions from the locked position. Optionally, in some examples the plunge locking lever 200 is biased to the locked position. In this way, the plunge locking lever 200 is urged to return to the safer locked position when manually held in the second unlocked position.


In some examples, the plunge locking lever 200 is biased with a torsion spring 302 wound around the locking bolt 300 (as shown in FIG. 3). The torsion spring 302 comprises a first end 304 which projects through a hole 306 in the plunge locking lever 200. The torsion spring 302 also comprises a second end 308 which is received in a reciprocal hole (not shown) in the housing 102. Accordingly, when the plunge locking lever 200 is rotated, the torsion spring 302 is compressed and urges the plunge locking lever 200 to return to the locked position.


In some examples, the plunge locking lever 200 is not biased and the user must manually move the plunge locking lever 200 between the locked and the first and second unlocked positions. In some other examples, the plunge locking lever 200 is biased with a leaf spring, coil spring, compression spring, extension spring, or any other suitable biasing means. For example, the plunge locking lever 200 can comprise an integral resilient plastic spring for urging the plunge locking lever 200 towards the locked position.


In FIG. 2b, the user maintains the plunge locking lever 200 in a manually held second unlocked position. That is, the user rotates the plunge locking lever 200 until, the locking bolt 300 no longer engages the second guide post 110. When the user releases the plunge locking lever 200 from the second unlocked position, the plunge locking lever 200 returns to the locked position as shown in FIG. 2a.


In FIG. 2c, the plunge locking lever 200 is rotated through the manually held second unlocked position as shown in FIG. 2b and held in place in a first unlocked position. When the plunge locking lever 200 is held in the first unlocked position, the user can freely move the housing 102 with respect to the first and second guide posts 108, 110. Accordingly, the user can plunge the cutting tool into the workpiece without manually holding the plunge locking lever 200 away from the locked position. The plunge locking lever 200 is held in the first unlocked position with a catch mechanism 310 (as shown in FIG. 3 and discussed further below in connection to FIG. 3).


The plunge locking lever 200 is released from the first unlocked position with the release lever 202. The release lever 202 is configured disengage the catch mechanism 310 and release the plunge locking lever 200 from the first unlocked position. The plunge locking lever 200 then rotates back to the locked position as shown in FIG. 2a.


In some examples, the locking system 120 is mounted sufficiently close to the second handle 114 that the user can actuate the plunge locking lever 200 with the user's thumb and actuate the release lever 202 with the user's fingers. In order for the plunge locking lever 200 to freely rotate back to the locked position form the first unlocked position, the user must make sure the user's thumb is not in the path of the plunge locking lever 200.


The plunge locking lever 200 rotates approximately 40 to 45 degrees between the locked position shown in FIG. 2a and the first unlocked position shown in FIG. 2c. The second unlocked position of the plunge locking lever 200 as shown in FIG. 2b requires that the plunge locking lever 200 is rotated between locked position and the first unlocked position. In some examples, the plunge locking lever 200 can be rotated through a greater angle between the locked position and the first and second unlocked positions.


Turning to FIG. 3, the locking system 120 will be discussed in further detail. FIG. 3 shows an exploded perspective view of the locking system 120 of the router 100.


As mentioned above, the locking system 120 comprises a catch mechanism 310 and a release lever 202 mechanically coupled to the catch mechanism 310. The release lever 202 is arranged to disengage the catch mechanism 310 and release the plunge locking lever 200 from the first unlocked position when the release lever 202 is actuated.


The release lever 202 is pivotally mounted to the housing 102. The release lever 202 is configured to pivot about the pivot axis Y-Y. In some examples, the release lever 202 is pivotable between a first position wherein the catch mechanism 310 is engaged and a second position wherein the catch mechanism 310 is disengaged. Engagement and disengagement of the catch mechanism 310 will be discussed further below.


In some examples, the pivot axis Y-Y and the longitudinal axis X-X intersect. In this way, the locking system 120 is compact and does not take up too much space when mounted to the housing 102.


In some examples, the release lever 202 is biased to the first position with a release lever spring 500 (as shown in FIG. 5). The release lever spring 500 is mounted in a spring hole 320 in the housing 102. In some examples, any type of spring or biasing means can be used to urge the release lever 202 to the first position.


The release lever 202 comprises a curved cut-out 312 which engages a pivot surface 316 on reciprocal projecting finger 314 mounted on the housing 102. A portion of the housing 102 is represented with dotted lines in FIG. 3. The locking bolt 300 is configured to be inserted into a reciprocal conduit 318 in the housing 102. The reciprocal conduit 318 and the longitudinal axis X-X intersect with the second guide post 110. In this way, translational or rotational movement of the locking bolt 300 with respect to the longitudinal axis X-X engages the second guide post 110.


In some examples, the catch mechanism 310 comprises a first part 322 mounted on the release lever 202 engageable with a second part 400 (as shown in FIG. 4) mounted on the plunge locking lever 200. In this way, the first part 322 and the second part 400 are respectively integral with the release lever 202 and the plunge locking lever 200.


In some examples, the first part 322 is a hook 322 and the second part 400 is a reciprocal groove 400. The hook 322 comprises an outer camming surface 324 and a first retaining surface 326 in a plane normal to the plane of the release lever 202. The reciprocal groove 400 comprises a second retaining surface 402 (as shown in FIG. 4). The first and second retaining surfaces 326, 402 are arranged to abut each other. When the first and second retaining surfaces 326, 402 are engaged in the first unlocked position, the plunge locking lever 200 is prevented from rotating back towards the locked position.


In some other examples, (not shown) the hook 322 is mounted on the plunge locking lever 200 and the reciprocal groove 400 is mounted on the release lever 202. In some other alternative examples, the catch mechanism 310 can comprise a peg and a reciprocal hole (not shown) or any other suitable mechanism for holding the plunge locking lever 200 in the first unlocked position shown in FIG. 2c.


In other examples the first part 322 of the catch mechanism 310 is not integral with the release lever 202. Indeed, the release lever 202 is mechanically coupled via linkages such that actuation of the release lever 202 causes the linkages to disengage the catch mechanism 310. In some other examples, the release lever 202 is replaced with a depressible button (not shown) which is mechanically coupled to the catch mechanism 310.


In order to release the plunge locking lever 200, the user depresses the release lever 202. The release lever 202 comprises a flat paddle 328. The paddle 328 provides a convenient area for the user to manually depress the release lever 202 with their finger. The paddle 328 is accessible to the user when the plunge locking lever 200 is in the first unlocked position as shown in FIG. 2c. In some examples, the paddle 328 is accessible underneath the plunge locking lever 200 in the first unlocked position. Accordingly, when the user depresses the paddle 328 with their fingers, the user's fingers do not obstruct the path of the plunge locking lever 200 returning to the locked position.


Turning to FIG. 4, the plunge locking lever 200 will be discussed in further detail. FIG. 4 shows a perspective view of the plunge locking lever 200. The plunge locking lever 200 comprise a user actuatable lever arm 404. The user actuatable lever arm 404 comprises a curved path such that the user actuatable lever arm 404 does not obscure the release lever 202 in the held unlocked position as shown in FIG. 2c.


The plunge locking lever 200 comprises a recess 406 for receiving the head 330 of the locking bolt 300. The head 330 of the locking bolt 300 is hexagonal and the recess 406 comprises a plurality of teeth 408 for engaging the sides of the head 330 of the locking bolt 300. Whilst the head 330 of the locking bolt 300 as shown in FIG. 3 is hexagonal, the head 330 can be square or any other suitable shape. The plunge locking lever 200 comprises a fastening hole 410 for receiving a fastening bolt (not shown). The fastening bolt is arranged to project through the fastening hole 410 and into a reciprocal threaded hole 332 in the head 330 of the locking bolt 300. Accordingly, the fastening bolt fixes the plunge locking lever 200 to the locking bolt 300. In this way, rotation of the plunge locking lever 200 is transmitted to the locking bolt 300 and the locking bolt 300 selectively engages the second guide post 110 in dependence of the position of the plunge locking lever 200.


The recess 406 and the plurality of teeth 408 provide a plurality of different relative positions between the head 330 of the locking bolt 300. This aids the correct orientation of the plunge locking lever 200 with respect to the second handle 114 during assembly of the router 100.


The plunge locking lever 200 comprises a rotatable inner surface 412 which is configured to engage the outer camming surface 324 of the release lever 202. The engagement of the rotatable inner surface 412 of the plunge locking lever 200 and the outer camming surface 324 of the release lever 202 will be discussed in further detail below.


The catch mechanism 310 will now be described in further detail in reference to FIGS. 5, 6, 7a and 7b. FIGS. 5 and 6 shows a cross sectional side view of the locking system 120 of the router 100. FIGS. 7a and 7b show plan cross sectional views of the locking system 120 of the router 100.



FIGS. 5 and 7
a show the catch mechanism 310 in engagement and the release lever 202 in the first position. FIGS. 6 and 7b show the catch mechanism 310 in disengagement and the release lever 202 in the second position.



FIGS. 5, 7
a show the plunge locking lever 200 in the first unlocked position as shown in FIG. 2c. The first part 322 of the catch mechanism 310 is engaged with the second part 400 of the catch mechanism 310. In order to release the catch mechanism 310, the release lever 202 is pivoted from the first position as shown in FIG. 5 to the second position as shown in FIG. 6. The release lever 202 is pivoted in the direction of the arrow B as shown in FIG. 5.


Once the release lever 202 is in the second position, the hook 322 is disengaged from the reciprocal groove 400 in the plunge locking lever 200. The plunge locking lever 200 snaps back to the locked position as shown in FIG. 2a.


When the plunge locking lever 200 is in the locked position, the rotatable inner surface 412 engages the outer camming surface 324 of the release lever 202. The rotatable inner surface 412 urges against the outer camming surface 324 and the release lever 202 pivots about the pivot axis Y-Y into the second position as shown in FIGS. 6 and 7b. In this way, the plunge locking lever 200 keeps the release lever 202 and the first part 322 of the catch mechanism 310 out of the path of the plunge locking lever 200. This means that the first part 322 of the catch mechanism 310 can only impede the rotation of the plunge locking lever 200 in the first unlocked position.


In the locked position and the second unlocked position, the first part 322 of the catch mechanism 310 does not interfere with the rotation of the plunge locking lever 200.


The aforementioned locking system 120 allows the user to easily select between a plunge mode and a fixed mode. The locking system 120 requires the user to positively engage the release lever 202 when the locking system 120 has been locked in the plunge mode. This means that the user cannot accidentally force the plunge locking lever 200 to return to the locked position. Furthermore, the locking system 120 does not require the user to force the plunge locking lever 200 past the catch mechanism 310. Accordingly, the locking system is less likely to break due to repeated use.


In some examples the power tool 100 is mountable on a plunge base (not shown). In these examples, the power tool is a router, a plunge saw, a drill, a multitool, an oscillating tool or any other suitable power tool mountable on a plunge base.


The plunge base is engageable with a workpiece and allows the power tool 100 to be plunged towards the workpiece when mounted in the plunge base. In this way, the power tool 100 is operable in the same way as the power tool 100 as previously discussed in reference to the examples shown in the Figures.


The plunge base comprises a tool mount for mounting the power tool 100 to the plunge base. The power tool 100 can be selectively mounted and secured to the tool mount via an attachment mechanism such as a clamp. This means that the power tool 100 can be selectively mounted on the plunge base and be operated with or without the plunge base. The plunge base comprises at least one guide post slidably mounted to the tool mount and a base fixed to the at least one guide post.


The tool mount comprises a plunge locking lever mounted to the tool mount which is moveable between a locked position and an unlocked position. In the locked position the at least one guide post is fixed with respect to the tool mount. In the unlocked position the at least one guide post is slidable with respect to the tool mount thereby allowing the user to adjust the distance between the base and the tool mount, wherein the plunge locking lever is biased to the locked position.


The tool mount further comprises a catch mechanism arranged to engage the plunge locking lever in the unlocked position. The catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position. The plunge locking lever, the catch mechanism and the release lever are the same and operate in a similar way as discussed with respect to previous examples.


In another embodiment two or more embodiments are combined. Features of one embodiment can be combined with features of other embodiments.


Embodiments of the present invention have been discussed with particular reference to the examples illustrated. However, it will be appreciated that variations and modifications may be made to the examples described within the scope of the invention.

Claims
  • 1. A power tool comprising: a housing;a motor assembly arranged to rotate a cutting tool, the motor being mounted in the housing;at least one guide post slidably mounted to the housing;a base fixed to the at least one guide post;a plunge locking lever mounted to the housing moveable between a locked position wherein the at least one guide post is fixed with respect to the housing and an unlocked position wherein the at least one guide post is slidable with respect to the housing thereby adjusting the distance between the base and the housing wherein the plunge locking lever is biased to the locked position; anda catch mechanism arranged to engage the plunge locking lever in the unlocked position;wherein the catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.
  • 2. A power tool according to claim 1 wherein the plunge locking lever is moveable to a manually held unlocked position between the locked position and the unlocked position.
  • 3. A power tool according to claim 1 wherein the catch mechanism comprises a first part mounted on the release lever engageable with a second part mounted on the plunge locking lever.
  • 4. A power tool according to claim 3 wherein the first part is a hook and the second part is a reciprocal groove.
  • 5. A power tool according to claim 1 wherein the release lever is pivotable between a first position wherein the catch mechanism is engaged and a second position wherein the catch mechanism is disengaged.
  • 6. A power tool according to claim 5 wherein the release lever is biased to the first position.
  • 7. A power tool according to claim 1, wherein the plunge locking lever is fixed to a rod releasably engageable with the at least one guide post.
  • 8. A power tool according to claim 7 wherein the rod is threaded through a spring arranged to bias the plunge locking lever.
  • 9. A power tool according to claim 1 wherein the plunge locking lever is rotatable between the locked position and the unlocked position.
  • 10. A power tool according to claim 5 wherein the plunge locking lever is rotatable between the locked position and the unlocked position, and wherein an axis of rotation of the plunge locking lever intersects with a pivot axis of the release lever.
  • 11. A power tool according to claim 10 wherein at least a portion of the release lever extends adjacent to the plunge locking lever when the plunge locking lever is engaged in the unlocked position.
  • 12. A power tool according to claim 10 wherein the plunge locking lever comprises a rotatable inner surface engageable with an outer surface of the release lever.
  • 13. A power tool according to claim 12 wherein the rotatable inner surface engages the outer surface the plunge locking lever in the locked position and urges the release lever into the second position.
  • 14. A power tool according to claim 1 wherein the plunge locking lever and the release lever are mounted adjacent to a handle of the power tool.
  • 15. A power tool according to claim 14 wherein the plunge locking lever and the release lever are actuatable with a user's thumb when the user grips the handle.
  • 16. A power tool according to claim 1 wherein the power tool is a router, a plunge saw, a drill, a multitool, or an oscillating tool.
  • 17. A locking system for a power tool comprising a housing, a motor assembly arranged to rotate a cutting tool, the motor being mounted in the housing, at least one guide post slidably mounted to the housing, and a base fixed to the at least one guide post, the locking system comprising: a plunge locking lever moveable between a locked position wherein the at least one guide post is fixed with respect to the housing and an unlocked position wherein the at least one guide post is slidable with respect to the housing to adjust the distance between the base and the housing wherein the plunge locking lever is biased to the locked position; anda catch mechanism arranged to engage the plunge locking lever in the unlocked position;wherein the catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.
  • 18. A plunge base for a power tool, the plunge base comprising: a tool mount for mounting the power tool to the plunge base;at least one guide post slidably mounted to the tool mount;a base fixed to the at least one guide post;a plunge locking lever mounted to the tool mount moveable and a locked position wherein the at least one guide post is fixed with respect to the tool mount and an unlocked position wherein the at least one guide post is slidable with respect to the tool mount to adjust the distance between the base and the tool mount, wherein the plunge locking lever is biased to the locked position; anda catch mechanism arranged to engage the plunge locking lever in the unlocked position;wherein the catch mechanism is mechanically coupled to a release lever arranged to disengage the catch mechanism and release the plunge locking lever from the unlocked position.
Priority Claims (1)
Number Date Country Kind
2006239.4 Apr 2020 GB national
CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of international patent application PCT/EP2021/059351, filed Apr. 9, 2021, which claims priority from Great Britain Patent Application No. 2006239.4 filed Apr. 28, 2020, the disclosures of which are incorporated herein by reference in their entirety.

Continuations (1)
Number Date Country
Parent PCT/EP2021/059351 Apr 2021 US
Child 17974261 US