1. Technical Field
The present invention relates to a power tool. More particularly, the invention relates to a router having a main unit movable with respect to a base to finely adjust a position of a cutter, thereby adjusting a depth of a groove to be cut in a workpiece. Further, the invention relates to a portable electric router in which a stopper pole is moved with respect to the main unit to move the main unit with respect to the base to adjust the depth of the groove to be cut in the workpiece.
2. Related Art
Electric power tools called routers have been well-known for cutting a groove in a workpiece. The router comprises a base, a main unit, a cutter, and a pair of handles. The base has a sliding surface on which a workpiece slides. The base has a through hole that extends perpendicularly to the sliding surface.
The main unit is supported on the opposite surface to the sliding surface of the base. The main unit can be moved with respect to the base in a direction perpendicular to the sliding surface. A workpiece is generally contact with the sliding surface in a horizontal position. Therefore, a moving direction of the main unit is usually a direction perpendicular to the sliding surface or a vertical direction. Hence, the main unit supported over the base can be usually moved up and down with respect to the base. The main unit has two through holes in which a pair of pillar-shaped members are inserted.
The two pillar-shaped members, called columns, support the main unit to the base. These pillar-shaped members are arranged parallel to each other, each extending perpendicularly to the sliding surface. The pillar-shaped members are fixed at one end to the base. The other end portions of the pillar-shaped members are inserted in the through holes. A fastening member is provided near the through hole in the main unit. The fastening member is designed to fasten one pillar-shaped member to the main unit temporarily to prevent the pillar-shaped member from moving with respect to the main unit. While fastened by the fastening member, the pillar-shaped member is temporarily held immovable.
The main unit has two projections which extend from left and right sides of the main unit, respectively, when the sliding surface extends horizontally, contacting with a workpiece. The router has the pair of handles which are mounted on the distal ends of the projections, respectively. A user may hold the handles with hands, respectively.
The main unit incorporates an electric motor. The electric motor has an output shaft that extends to the base in a direction perpendicular to the sliding surface. The cutter is attached and secured to the distal end of the output shaft. The cutter can move through the through hole of the base downward from the sliding surface, when the main unit is moved down to the base.
A method of cutting a groove in a workpiece by using the router will be described below. The fastening member is operated, thus releasing the pillar-shaped members from the main unit, allowing the main unit to move with respect to the both pillar-shaped members. The user holds the handles with hands, respectively, and then moves the main unit to a desired position with respect to the base. The user operates the fastening member to fix the pillar-shaped members to the main unit, making the main unit immovable with respect to the base The cutter is then projected through the through holes to the workpiece by a desired distance from the sliding surface. The desired distance is the depth of a groove to be cut in the workpiece.
After setting the router in the above state, the user can hold the two handles with the hands, respectively, and move the router over the workpiece, contacting the sliding surface and maintaining the sliding surface in a substantially horizontal position. As a result, the cutter forms a groove in the workpiece because the cutter protrudes downward from the sliding surface. This type of router is disclosed in Japanese Patent Application Publication No. Hei 6-020726.
When using the conventional router described above, the user needs to hold the handles with the hands, respectively in order to support the main unit. The user then moves the main unit to a desired position with respect to the base, and protrudes the cutter by a desired distance to the workpiece from the sliding surface. Therefore, it is difficult to finely adjust the protruding distance of the cutter.
There is another method of using the router. In this method, a support member is secured to the router to support the router to an edge of a so-called router table. That is, the router is used with the base of the router being held upward in a vertical direction with respect to the main unit. The router is then supported at the edge of the router table by means of a support member. In this case, the user holds the handles with the hands, respectively, to move the main unit up and down in the vertical direction against the relatively large weight of the main unit to adjust the protruding distance of the cutter. Inevitably, it is more difficult to finely adjust the protruding distance of the cutter.
A router is proposed which has a fine-adjustment mechanism to finely adjust a moving distance of the main unit with respect to the base. In this case, the main unit needs to be moved first to a position near the desired position prior to the fine adjustment. The user must hold the handles with the hands, respectively to move the main unit. Hence, a mode of using the router need to be switched between the fine-adjusting mode in which the fine-adjustment mechanism adjusts the protruding distance of the cutter and the main-unit moving mode in which the user manually moves main unit to change the position of the main unit with respect to the base considerably. Further, if the user tries to operate the router in either one of the modes without holding the main unit, the user cannot easily move the main unit by handles, nor finely adjust the protruding distance of the cutter.
An object of this invention is to provide a power tool in which a moving distance of a main unit with respect to a base can be fine-adjusted, thereby fine-adjusting a protruding distance of a cutter from the base to a workpiece.
The present invention provides a power tool having: a base, a main unit, a cutter, a bolt, an engagement member, and a unit. The base has a sliding surface slidable on a workpiece, another surface opposite to the sliding surface, and an opening provided through the base between the sliding surface and the another surface.
The main unit is supported on a first side of the another surface and movable in a first direction substantially perpendicular to the sliding surface, the main unit including an electric motor.
The cutter is driven by the electric motor to protrude through the opening from the sliding surface when the main unit is moved to the base.
The bolt has a longitudinal axis and extends in the first direction on the first side, a first male thread portion, and one end supported by the base. The bolt is rotatable about the longitudinal axis.
The engagement member has a first female thread portion threadably engaged with the male thread. The engagement member is movable between an engaged position and a disengaged position. The engaged position is a position at which the first male thread portion is engaged with the first female thread portion. The disengaged position is another position at which the first male thread portion is disengaged with the first female thread portion.
The unit maintains the engagement member at the disengaged position.
The present invention further provides a power tool having: a base, a main unit, a cutter, a bolt, and an engagement member.
The base has a sliding surface slidable on a workpiece, another surface opposite to the sliding surface, and an opening provided through the base between the sliding surface and the another surface,.
The main unit is supported on a first side of the another surface and movable in a first direction substantially perpendicular to the sliding surface. The main unit includes an electric motor.
The cutter is driven by the electric motor. The cutter is configured to protrude through the opening from the sliding surface.
The bolt has a longitudinal axis and extending in the first direction on the first side. The bolt has a first male thread portion and one end supported by the base. The bolt is rotatable about the longitudinal axis.
The engagement member is provided in the main unit and has a first female thread portion threadably engaged with the male thread. The engagement member is movable between an engaged position and a disengaged position. The engaged position is a position at which the first male thread portion is engaged with the first female thread portion. The disengaged position is another position at which the first male thread portion is disengaged with the first female thread portion.
when the engagement member is at the engaged position, rotation of the bolt causes the first male thread portion to thread with respect to the first female thread portion, thereby moving the main unit in the first direction and adjusting a distance of the main unit to the sliding surface. When the engaged member is at the disengaged position, the engaged member is maintained at the disengaged position without any external force.
The aforementioned aspects and other features of the invention are explained in the following description, taken in connection with the accompanying drawing figures wherein:
A router according an embodiment of the present invention will be described with reference to FIGS. 1 to 34. The expressions “front”, “rear”, “above”, “below”, “left”, and “right” are used throughout the description to define various parts when the rooter is disposed in an orientation in which it is intended to be used.
As
A base-through hole 110b is made in a substantially center of the base 100 in an axial direction of the recess 110a. The base-through hole 110b extends between the surfaces 110A and 110B of the base 110 in a direction in which the surfaces 110A and 110Ba are spaced. The diameter thereof is large enough to allow the passage of the cutter 151.
The base 110 holds a dust guide 176, and opposes an outlet port 176B of the dust guide 176, and has an inclined surface 110C, as illustrated in
As
Two pin-insertion holes 110d are made in the base 110, in which the column-insertion recesses 110c are made, and lie on the diameters of the column-insertion recesses 110c located close to the dust-guide receptacle. The pin-insertion holes 110d extend from the left and right sides of the base 110 (in
Two straight grooves 110e are cut in the base 110 on the both sides of the recess 110a (
The base 110 has a bolt hole 110f, in which a bolt 117 (later described) is inserted and held. The bolt hole 110f penetrates the base 110 in a line connecting the surface 110A of the base 110, and the other surface 110B of the base 110. As shown in
A stopper-pole position adjusting mechanism 115 is provided on the base 110. A stopper pole 165 has one end which abuts on the adjusting mechanism 115. As shown in
More specifically, the turntable section 115A has a through hole 115a shaped like a round pillar and extending along the axis as shown in
The projections 115B and 115C are located about the turntable section 115A, respectively at positions of 120° and 240° in the counterclockwise direction from the position of 0°, i.e., the upper position in
With the stopper-pole position adjusting mechanism 115, the router 101 can cut a groove in the workpiece, first making a shallow groove, then deepening the groove step by step, and finally cutting a deep groove in the workpiece. If a relatively deep groove having a 60 mm depth is made, the electric motor 131 (later described) will be overloaded. Such a deep groove is difficult to be cut with a single cutting process. This is why a shallow groove should be made first, and then deepened step by step into a deeper groove.
In such a step-by-step cutting process, the user first adjusts the stopper pole 165, thrusting the cutter 151 by 60 mm from one surface 110A of the base 110, keeping the stopper pole 165 in abutment on the upper surface of the turntable section 115A. The user then turns the projection 115B, making the projection 115B protrude by 40 mm from the upper surface of the turntable section 115A, and turns the projection 115C, making the projection 115C protrude by 20 mm from the upper surface of the turntable section 115A.
Next, the user cuts a groove to a depth of 20 mm, while keeping the stopper pole 165 in contact with the projection 115B that protrudes by 40 mm. Subsequently, the user rotates the turntable section 115A and places the stopper pole 165 in abutment on the projection 115C that protrudes by 20 mm. In this condition, the user performs cutting, increasing the depth of the groove from 20 mm to 40 mm. A groove that is 40 mm deep is thereby made in the workpiece. Next, the user turns the turntable section 115A and brings the stopper pole 165 into contact with the upper surface of the turntable section 115A. Then, the user performs cutting, increasing the depth of the groove from 40 mm to 60 mm. As a result, the router can cut a 60-mm deep groove in the workpiece.
As indicated above, the lower end of the stopper pole 165 abuts on the stopper-pole position adjusting mechanism 115 that has projections 115B and 115C protruding by different distances from the upper surface of the turntable section 115A. Hence, a deep groove can be easily cut in the workpiece, by cutting the workpiece step by step.
The fastening mechanism 115D is located around the turntable section 115A, at position of 0°, i.e., the upper position in
The male screw 115G is inserted from the surface 110A of the base 110 through the fastening-part through hole 110g to the turntable-fastening through hole 115b. Accordingly, the male screw 115G is set in screw engagement with the second female screw cut in one end of the stopper pole 165 at the other surface 110B of the base 110. The stopper pole 165 is therefore fixed to the base 110 and held at the base 110. The moving distance of the stopper pole 165 with respect, to the main unit 130 and the moving distance of the base 110 with respect to the main unit 130 can be detected, as will be described later.
As
The other surface 110B of the base 110, i e., the surface facing away from the workpiece, has a female-screw hole (not shown) in which a dust-guide fastening screw 176E is set in engagement as illustrated in
As seen from
The main unit 130 supports the output shaft 131A of the electric motor 131. The shaft 131A of the electric motor 131 may change in position due to deformation to reduce the cutting precision. To prevent such reduction of the cutting precision, the lower part of the main unit 130 (
In the main unit 130, the electric motor 131 is located almost halfway between the left and right sides of the main unit 130. The output shaft 131A (motor shaft) extends from the electric motor 131 downward (in
The cutter 151 is driven and rotated by the electric motor 131. As the main unit 130 is moved down to approach the base 110, the cutter 151 can project from one surface 110A of the base 110, i.e., the sliding surface, through the base-through hole 110b. Thus, the cutter 151 extending from the base-through hole 110b can bite the workpiece to cut a groove in the workpiece, as the base 110 slides on the workpiece at the sliding surface. As
The electric motor 131 is located, almost halfway between the left and right sides of the electrically conductive casing 130A that constitutes the main unit 130, as illustrated in
As
The two columns 111 and 112 have the same outside diameter. By contrast, the through holes 130b and 130c do not have the same diameter. As shown in
As illustrated in
A compression spring 136 is wound around the outer circumferential surface of each small-diameter column 135. The compression spring 136 abuts at one end on the casing made of resin, and at the other end on the step defined by the other end of the column 111 or 112 and the inner circumferential surface of the annular member 134. Both compression springs 136 are always biased to move the main unit 130 away from the base 110.
As
When the lock lever 137 is rotated, the shaft part 137B is pushed, at the distal end thereof, on the column 112. Then, the main unit 130 is secured to the column 112. When the lock lever 137 is rotated in the opposite direction, the distal end of the shaft part 137B is spaced from the outer circumferential surface of the column 112. In this case, the main unit 130 is released from the engagement with the column 112.
As
A bolt-insertion through hole 138a shaped like a round pillar is made in substantially the center part of the engagement member 138. This bolt-insertion through hole 138a has a diameter larger than the outside diameter of the bolt 117. An arcuate recess 138b is formed in the inner circumferential surface of the bolt-insertion through hole 138a and is located on the right (in
An engagement projection 138B shaped like a round pillar protrudes from the outer circumferential surface 138A of the engagement member 138. The engagement projection 138B extends from the outer circumferential surface 138A of the engagement member 138 to the back of the main unit 130, i.e., to the left in
A recess 138c is made in the distal end of the engagement projection 138B. A screw 141 is inserted in the recess 138c in screw engagement. A washer 140 is mounted on the screw 141, laid on the distal end of the engagement projection 138B and extends in the radial direction of the engagement projection 138B like a flange. The small-diameter part 139B of the drive member 139 abuts on the washer 140. The large-diameter part 139A of the driven member 139 abuts on the outer circumferential surface 138A of the engagement member 138. The distal end of the engagement projection 138B is in flush with the small-diameter part 139B of the drive member 139. The drive member 139 is held between the washer 140 and the outer circumferential surface 138A of the engagement member 138.
A female thread 130f is formed in that inner surface of the bolt-insertion through hole 130e or in the main unit 130 which opposes the male thread 139C of the large-diameter part 139A. The female screw 130f meshes with the male thread 139C of the large-diameter part 139A of the drive member 139. When the drive member 139 rotates around the engagement projection 138B, the drive member 139 moves toward or far from the central axis of the bolt 117.
A lever member 142 is mounted on the small-diameter part 139B of the drive member 139. As illustrated in
When the lever member 142 is held and unable to rotate with respect to the drive member 139, the user may hold and rotate the projection 142A to move the engagement member 138. In this case, the drive member 139 is rotated to move in the direction perpendicular to the axis of the bolt 117. As a result, the engagement member 138 is moved to the engaged position where the female thread provided in the recess 138b meshes with the male thread 117B of the bolt 117. Alternatively, the engagement member 138 is moved to the disengaged position where the female thread in the recess 138b of the engagement member 138 comes out of mesh with the male thread 117B of the bolt 117.
The drive member 139 is rotated to move the engagement member 138 from the engaged position to the disengaged position, or from the disengaged position to the engaged position. Thus, the engagement member 138 remains at the disengaged position unless the drive member 139 is rotated at the disengaged position.
As shown in
The headless screw 143 is turned to move far from the engagement member 138 backwards, enabling the lever member 142 to rotate with respect to the drive member 139. The lever member 142 is rotated, adjusting the angle of rotation. Then, the headless screw 143 is turned and moved to the engagement member 138, disabling the lever member 142 from being rotated with respect to the drive member 139. Thus, the engagement member 138 can be at the engaged position when the projection 142A of the lever member 142 abuts on the rotation-restricting member 144. Alternatively, the engagement member 138 can be at the disengaged position when the projection 142A abuts on the rotation-restricting member 144.
The headless screw 143 is turned and moved backwards, enabling the lever member 142 to be rotated with respect to the drive member 139. The lever member 142 is rotated, adjusting the angle of rotation minutely. Then, the headless screw 143 is turned and moved forward, disabling the lever member 142 from being rotated with respect to the drive member 139. In this case, the meshing of the female thread provided in the recess 138b of the engagement member 138 with the male thread 117B of the bolt 117 can be adjusted finely if the engagement member 138 is at the engaged position when the projection 142A of the lever member 142 abuts on the rotation-restricting member 144. Thus, the female thread can mesh with the male thread 117B in a proper manner.
As FIGS. 6 to 9 show, a compression spring 145 is provided in the bolt-insertion through hole 130e at a position remote from the engagement projection 138B. As shown in FIGS. 6 to 9, the compression spring 145 has one end contacting a part of the main unit 130 in which the bolt-insertion through hole 130e is made, and the other end abutting on the engagement member 138. The compression spring 145 therefore always biases the engagement member 138 to the back of the main unit 130. Hence, the male thread 139C of the drive member 139 is pushed to be engaged with the female thread 130f in the moving direction of the drive member 139. As a result, no play occurs between the male thread and the female thread, and the lever member 142 has no play at all.
As
As
A fine-adjustment knob 149 is fastened to the other end of the shaft coupled to the connecting member 147. The fine-adjustment knob 149 has a round cross section taken along a plane perpendicular to the axis of the shaft 146. The fine-adjustment knob 149 has a radius greater than that of the shaft 146. Hence, the bolt 117 can be rotated by the same angle as the rotating angle of the fine-adjustment knob 149. When the bolt 117 is rotated, the engagement member 138 is moved toward or away from the male thread 117B of the bolt 117. In the bolt-insertion through hole 130e, the engagement member 138 cannot move in the axial direction of the bolt 117. Therefore, the main unit 130 can be moved upward or downward, together with the engagement member 138 in the axial direction of the bolt 117, as the engagement member 138 is moved upward or downward.
As shown in
The digital display unit 160 has housings 163 and 164 (
As illustrated in
A tape 166 having slits of precise dimensions and a detection unit 171 designed to detect the slit are provided in the housings 163 and 164. The joint portion between the housings 163 and 164 is sealed with a seal member (not shown). This structure prevents dust from entering into the housings 163 and 164. Dust is required to be prevented from entering at the communication hole 160a. To this end, a felt member 167 is provided in the communication hole 160a and contacts the stopper pole 165, thus preventing dust from entering the interior.
A part of the stopper pole 165 which lies in the housings 163 and 164 has a notch 165a as shown in
As
As shown in
A knob 168B is mounted on the other end of the shaft 168. The knob 168B has a ring-shaped cross section taken along a plane that is perpendicular to the shaft 168. The knob 168B has a through hole at the center of the cross section. The through hole has a female thread that can mesh with a male screw 169 described later. The male screw 169 is inserted into one end of the through hole and penetrates the through hole. The head of the male screw 169 abuts on the knob 168B. The male screw 169 projecting from the other end of the through hole is set in mesh with the female thread (not shown) formed in the inner surface of a recess (not shown) that is made in the other end of the shaft. The knob 168B can therefore be rotated together with the shaft 168 and can move in the axial direction thereof. As
As shown in
A part of the knob 168B, located at a position in the lengthwise direction of the shaft 168, abuts on parts of the housings 163 and 164 which define the shaft-insertion through hole 160b when no external force pulls the knob 168B outwards. At this time, the pinion 168A meshes with the rack 165B. Thus, the knob 168B may be turned, moving the stopper pole 165 in the lengthwise direction thereof. The position of the stopper pole can therefore be finely adjusted.
When an external force pulls the knob 168B outwards, the knob 168B is moved to the left as shown in
In this condition, the knob 168B may be turned, rotating the shaft 168 and thus setting the shaft 168 from the state of
As
As seen from
As
The light ON/OFF switch 160D is a switch that turns on the backlight of the display unit 160B, when the router 101 is attached to the router table 102 and the base 110 is located above the main unit 130 as illustrated in
The changeover/TABLE switch 160F functions as two switches, i.e., a changeover switch and a TABLE switch. The two functions are switched from one to the other when the switch 160F is kept depressed longer than a predetermined time (3 seconds in this embodiment). When pushed while functioning as changeover switch, the switch 16OF displays the unit of the distance, either “inch” as shown in
A power-supply circuit 173 (
A cord 173A extends from the power-supply circuit 173 to the digital display unit 160. The power supplied through the cord 173A is converted to a voltage of a specific value, which is applied to the digital display unit 160. A cord 173B is connected by a connector 173C to the electric motor 131. The power supplied through the cord 173B is converted to a voltage of a specific voltage, which is applied to the electric motor 131. An ON/OFF switch 173D is provided on the middle part of the cord 173B for supplying power to the electric motor 131. When the switch 173D is turned on, the electric motor 131 is driven. When the switch 173D is turned off, the electric motor 131 is stopped. As shown in
Two handles 130E are provided on the left and right ends of the main unit 130 shown in
As shown in
A speed-changing dial 130I is provided in one of the handles 130E and located near the projection 130H so that the dial may be rotated by the user with the thumb. That is, as shown in
As
As shown in
An insulating member 174 made of electrically insulating material is provided in the notch 130i formed in the main-unit projection 130F. As
The handle 130E has an handle-communication hole 130j that opposes the main-unit projection 130F. Through the hole 130j, the intra-handle space 130G communicates with the exterior of the handle 130E. A part of the insulating member 174 projects into the handle-communication hole 130j. The insulating member 174 can therefore abut on the handle 130E which define the ends in which the handle 130E can be rotated. When the insulating member 174 abuts on the handle 130E, the rotation of the handle 130E is restricted.
The intra-handle space 130G and the intra-main-unit projection space 130h are connected by the handle-communication hole 130j and the main-unit-projection communication hole 130k. The spaces 130G and 130h remain connected, no matter which position the handle has been rotated to. As indicated above, the handle 130E can be rotated about the main-unit projection 130F. Nonetheless, the intra-handle space 130G and the intra-main-unit projection space 130h are required not to be disconnected from each other when the handle 130E is rotated. This is because the cord 175 (see
Accordingly, as shown in
The cord 175 is connected at one end to the electric motor 131 (
Since the handles 130E can be rotated, the user can use the router 101 with the handles 130E set at a desired angle. When the handles 130E are rotated, the intra-handle space 130G always communicates with the intra-main-unit projection space 130h because of the recess 130l made in the handle-communication hole 130j. Hence, the cord 175 can pass through the intra-handle space 130G and intra-main-unit projection space 130h.
As described above, the speed-changing dial 130I designed to adjust the rotation speed of the electric motor 131 is provided in one handle 130E and located near the projection 130H so that the user who holds this handle 130E may rotate the dial with the thumb. Therefore, the user can rotate the dial 130I to set the rotation speed of the electric motor 131 to an optimal speed, while observing the depth of the groove that the cutter 151 is forming in the workpiece.
Referring to
As
As illustrated in
An upper wall 176F is provided on the upper end of the hollow cylindrical part 176A that opposes the main unit 130. The upper wall 176F extends from the outer circumferential surface of the hollow cylindrical part 176A in the radial direction thereof. As
Due to the upper wall 176F, the hollow cylindrical part 176A has a small opening area The upper wall 176F can therefore prevent chips of the workpiece generated by the operating cutter 161 from scattering outside from the space defined by the inner circumferential surface 176C of the hollow cylindrical part 176A. A hose (not shown) may be used to connect the dust guide 176 to a dust collector (not shown). Then, dust can be collected at high efficiency.
A first wall 176G and a second wall 176H are provided on the inner circumferential surface 176C. The first and second walls 176G and 176H have been made by bending a corner of a plate having the same shape as the trapezoidal through holes, thus forming a straight ridge connecting two sides defining the corner. The first wall 176G is one part of the plate bent in the above manner, and the second wall 176H is the other part thereof. The first and second walls 176G and 176H, which are connected at the straight edge, define an obtuse angle.
The first wall 176G inclines clockwise (
Since the first and second walls 176G and 176H are arranged in the above manner, the fan air can flow over the inner circumferential surface 176C, inwardly in the radial direction of the hollow cylindrical part 176A as indicated by arrow in
As illustrated in
The outlet port 176G, which communicates with the hollow cylindrical part 176A, can be connected to one end of the hose of the dust collector (not shown). Chips of the workpiece can therefore be drawn from the hollow cylindrical part 176A into the dust collector through the outlet port 176B of the dust guide 176 when the dust collector (not shown) is driven.
Even if the hose of the dust collector is not connected, the fan air can flow via the through hole of the upper wall 176F into the space defined by the inner circumferential surface 176C and then can flow along the inner circumferential surface 176C in the direction of the arrow shown in
The router 101 incorporates a circuit board, which will be described with reference to the block diagram of
The DC converter 206 is the power-supply circuit 173 that has been described above. The microprocessor 201 is connected through the DC converter 206 to an AC power supply to which the electric motor 131 and the speed controller 205 for controlling the motor 131 at constant speed are connected. The speed-changing dial 130I and a rotation-speed detector 208 are connected to the speed controller 205. The rotation-speed detector 208 is configured to detect the revolutions per unit time of the electric motor 131. The DC converter 206 converts an alternating current to direct current supplied to the microprocessor 201. The microprocessor 201 is connected to the operation keypad 202 and the encoder system 203. The microprocessor 201 outputs display data to the liquid crystal display 204 so that the display 204 displays the data such as the depth of a groove to be cut in the workpiece.
The liquid crystal display 204 corresponds to the LCD 160C of the display unit 160B. The encoder system 203 corresponds to the above-mentioned detection unit 171. As described above, the unit 171 includes two sets of components, each consisting of a light-emitting part 171A and a light-receiving part 171B. The unit 171 is configured to detect the depth of the groove as well as the cutting direction of the groove. The encoder system 203 can output two signals A and B to the microprocessor 201, as shown in
As seen from
A narrow-width pulse is generated at the leading or trailing edge of signal A or B. This pulse, which is called four-segment pulse, is used as up-down clock signal for the up-down counter provided in the microprocessor 201 that receives the signal A or B.
The up-down signal is generated depending on whether the signal A advances or delays in phase with respect to the signal B. As the depth of the groove increases, the up-down signal maintains a high level when the signal A advances in phase by 90° with respect to the signal B, and the up-down counter increments every time the counter receives a up-down clock pulse. On the other hand, as the depth of the groove decreases, the up-down signal falls to and maintains at a low level when the signal A delays in phase by 90° with respect to the signal B, and the up-down counter decrements every time the counter receives a up-down clock pulse.
The operation keypad 202 has switches SW1, SW2 and SW3. The switches SW1, SW2 and SW3 correspond to the light ON/OFF switch 160D, the changeover/TABLE switch 160F, and the zero-setting switch 160E, respectively. As specified above, the switches 160D, 160E and 160F are arranged around the display unit 160B, i.e., the liquid crystal display 204 of the digital display unit 160. The unit in which the value is displayed on the display unit 160B is switched between the inch and the millimeter when the changeover/TABLE switch 160F, or SW2 is operated. If inch is selected as a unit of length, the count of the up-down counter is converted to the length in inches. If millimeter is selected as a unit of length, the count of the up-down counter is converted to the length in millimeters.
The data representing whether the inch or millimeter is selected as a unit of length is stored in a memory (not shown). When the ON/OFF switch 173D is turned on again after the switch 173D has been turned off, the unit of length is changed to the one selected before the switch 173D is turned off.
The arithmetic operation unit reads the data showing whether normal display or inverse display from the memory (not shown). From the data read, it is determined whether the numerical value is displayed on the LCD 160C with a normal-display pattern code or an inverse-display pattern code.
The operation of the microprocessor 201 will be explained with reference to the flowchart of
Next, the process of reading the signals A and B generated as the stopper pole 165 moves (S4). From the changes in the signals A and B, it is determined whether the stopper pole 165 has moved (S5) If Yes in S5, it is determined which direction the stopper pole 165 has moved away from the base 110(S6). If the combination of signals A and B changes from 00 to 01 through 10 and 11, the stopper pole 165 is determined to have moved away from the base 110 (Yes in S6). In this case, the count of the up-down counter is increased by one (S8). Then, it is determined whether the numerical value should be displayed in inches on the display unit 160B (S9).
If the combination of signals A and B changes from 01 to 00 through 11 and 10, the stopper pole 165 is determined to have moved to the base 110 (No in S6). In this case, the count of the up-down counter is decreased by one (S7). Then, it is determined whether the numerical value should be displayed in inches on the display unit 160B (S9). If the output levels of signals A and B do not change, and the motion of the stopper pole 165 is not detected (No in S5), it is determined whether the numerical value should be displayed in inches on the display unit 160B (S9).
If the data stored in the memory (not shown) designates the metric system, the count of the up-down counter is converted to a length in millimeters (S10). If the data designates inch system, the count of the up-down counter is converted to a length in inches (S11).
Then, it is determined whether the normal/inverse display flag stored in the memory (not shown) designates the inverse display (S12). If the flag designates the inverse display (Yes in S12), the cutting depth is displayed upside down on the display unit 160B (S14). If the flag designates the normal display (No in S12), the cutting depth is displayed in normal way on the display unit 160B (S13).
Next, it is determined whether the light ON/OFF switch 160D has been operated (S15) If the light ON/OFF switch 160D has not been operated and the state has not been changed (No in S15), it is determined whether the zero-setting switch 160E has been operated (S19). If the backlight has been turned on because the light ON/OFF switch 160D has been depressed n+1 times, where n is an integer more than or equal to 0 (backlight ON, in S15), the numerical value is displayed on the display unit 160B while the backlight remains on (S18). Then, it is determined whether the zero-setting switch 160E has been operated (S19) The user may depress the ON/OFF switch 160D n+2 times to turn off the backlight and interrupt the displaying of the numerical value (backlight OFF, in S15). In this case, the display unit 160B does not display the numerical value, while the backlight remains off (S16). Then, it is determined whether the zero-setting switch 160E has been operated (S19). If user may depress the ON/OFF switch 160D n+3 times, and the backlight is turned off (backlight OFF, in S15), the display unit 160B displays the numerical value, while the backlight remains off (S17). Then, it is determined whether the zero-setting switch 160E has been operated (S19).
If the zero-setting switch 160E has been operated (Yes in S19), the count of the up-down counter is set to zero (S20). Then, the process for reading the signals A and B starts again (S4). If the zero-setting switch 160E has not been operated (No in S19), the process for reading the signals A and B starts again (S4).
The operation of the router 101 to cut a groove in the workpiece will be explained. The user may hold the router 101 with hands, moves the router 101 to cut a groove in the workpiece. In this case, the base 110 is positioned below the main unit 130 as viewed in the vertical direction, as illustrated in
In this state, the user moves the main unit 130 down along the columns 111 and 112 until the lower end of the stopper pole 165 abuts on the stopper-pole position adjusting mechanism 115. As a result, the cutter 151 protrudes downward through the base-through hole 110b and bites into the workpiece W. The user then moves the router 101 on the workpiece W to form a groove in the workpiece W by the cutter 151.
The distance the cutter 151 projects from the sliding surface of the base 110 is the depth of the groove being cut in the workpiece W. This depth can be adjusted by moving the stopper pole 165 with respect to the main unit 130 to change the distance between the main unit 130 and the base 110. A method of adjusting the depth of the groove will be explained below.
To adjust the depth of the groove, the user first places the router 101 on the workpiece W and then turns on the ON/OFF switch 173D to supply power to the digital display unit 160. Next, the main unit 130 is moved down along the columns 111 and 112 against the bias of the compression spring 136 until the distal end of the cutter 151 touches the upper surface of the workpiece W. When the distal end of the cutter 151 touches the upper surface of the workpiece W, the lock lever 137 is tightened, thereby fixing the main unit 130.
Subsequently, the knob 130D is loosened to release the stopper pole 165. Then, the stopper pole 165 is moved down until the lower end of the pole 165 abuts on the fastening mechanism 115D. The position of the stopper pole 165 corresponds to a depth-zero position. Then, the user pushes the zero-setting switch 160E. The numerical value to be displayed on the LCD 160C is thereby reset to “0” (point-zero setting).
Referring to
The moving distance of the stopper pole 165 is calculated and displayed on the LCD 160C as a numerical value. Looking at the numerical value displayed on the LCD 160C, the user moves the stopper pole 165 up or down until the numerical value becomes equal to the desired depth. When the numerical value becomes equal to the desired depth, the user tightens the knob 168B to fix the stopper pole 165 in position. The depth of the groove to be cut is thus adjusted.
Next, the electric motor 131 is driven to rotate the cutter 151 that is spaced apart from the workpiece W. The main unit 130 is lowered along the columns 111 and 112 until the lower end of the stopper pole 165 abuts on the stopper-pole position adjusting mechanism 115. Then, the main unit 130 is moved by a predetermined distance to cut a groove to the preset depth in the workpiece W. Thereafter, the main unit 130 is lifted by the bias force of the compression spring 136. This sequence of steps may be repeated to cut a groove W1 having a rectangular cross section as illustrated in
The router 101 may be turned upside down and then be secured to the router table 102 as is illustrated in
Before the router 101 is attached to the router table 102, the following steps are performed. First, the knob 130D that fastens the stopper pole 165 to the main unit 130 is loosened. Then, the stopper pole 165 is moved to fix the upper end thereof to the fastening mechanism 115D. The stopper pole 165 is thereby secured to the base 110.
In this state, the main unit 130 can be moved up and down with respect to the base 110 and the stopper pole 165. When the main unit 130 is moved, the rack 165B provided on the main unit 130 causes the pinion 168A and the shaft 23 to rotate. The detection unit 171 generates pulses based on the light beams passing through the slits 166a. The moving distance of the main unit 130 can be calculated based on these pulses in the same way as described above. The calculated moving distance can be displayed on the LCD 160C. In the present embodiment, the distance of the stopper pole 165 and the moving distance of the main unit 130 can be displayed on the LCD 160C.
Next, the router 101 is attached to the router table 102, upside down as shown in
The lever member 142 is rotated to put the engagement member 138 and the male screw 117B into engagement and fix the bolt 117 with respect to the main unit 130. At this time, the main unit 130 is considered to be at a position that corresponds to the depth-zero position. The user pushes the zero-setting switch 160E to reset the numerical value displayed on the LCD 160C to “0” (point-zero adjustment).
Then, the fine-adjustment knob 149 is rotated to turn the bolt 117. The engagement member 138 set in screw engagement with the bolt 117 to move the main unit 130 up in the vertical direction. The distance the main unit 130 is equal to the projecting distance of the cutter 151 from the upper surface of the router table 102, which is also equal to the depth of the groove to be cut. This distance is displayed on the LCD 160C as described above. Seeing the numerical value displayed on the LCD 160C, the user moves the main unit 130 upward until the numerical value becomes equal to the desired depth of the groove to be cut. When the numerical value becomes equal to the depth, the user tightens the lock lever 137 to fix the main unit 130 in position. The depth is thereby adjusted. The cutter 151 therefore protrudes from the upper surface of the router table 102 by the predetermined distance corresponding to the depth of the groove to be cut.
In this embodiment, the position of the main unit 130 can be fine-adjusted easily and readily merely by rotating the fine-adjustment knob 149.
After the depth of the groove to be cut is adjusted as described above, the electric motor 131 is driven to rotate the cutter 151 with the cutter 151 being apart from the workpiece W. Then, the workpiece W is moved on the router table 102. As a result, the cutter 151 cuts the workpiece W to make a groove having that depth.
The above description explains a method to adjust the depth when the router 101 is secured to the router table 102 and the base 110 is positioned above the main unit 130 in the vertical direction. In another embodiment, the depth can be adjusted in the same way when the router 101 cuts a groove without using the router table 102.
As described above, both the moving distance of the stopper pole 165 with respect to the main unit 130 and the moving distance of the main unit 130 with respect to the base 110 are displayed on the LCD 160C, as the depth of the groove to be cut. While looking at these displayed distances, the user can move the stopper pole 165 or the main unit 130 to adjust the depth accurately and easily. The user can adjust the depth of the groove when using the router 101 to the router table 102.
When the user holds the router 101, the rack-pinion mechanism moves the stopper pole 165 with respect to the main unit 130. Thus, the depth of the groove to be cut can be adjusted accurately and easily.
When the router 101 is secured to the router table 102, the knob 130D is turned to move the main unit 130 with respect to the base 110 and thereby adjusting the cutting depth to a prescribed value. In this case, the user can easily switch the display mode from the mode of displaying the moving distance of the stopper pole 165 with respect to the main unit 130 to the mode of displaying the moving distance of the main unit 130 with respect to the base 110.
In the embodiment of this invention, the LCD 160C can display both the moving distance of the stopper pole 165 with respect to the base 130 and the moving distance of the main unit 130 with respect to the base 110, each as a digital value. Hence, the LCD 160C can be made smaller and more compact. In addition, the user can perform the same operation to display the distance on the LCD 160C for both of the case in which the user holds the router 101 with hands, and the case in which the user secures the router 101 to the router table 102. This simplifies the adjustment of the depth of the groove to be cut.
In this embodiment, the moving distance of the stopper pole 165 with respect to the main unit 130 or the moving distance of the main unit 130 with respect to the base 110 is displayed on the LCD 160C, in an upside-down fashion. Therefore, even if the router 101 is attached to the router table 102 upside down, the LCD 160C can display the numerical value in such a way that the user can read the value correctly and easily.
The router according to the present invention is not limited to the embodiment described above. Various changes and modifications can be made, without departing from the scope defined by the claims set forth hereinafter. In the above embodiments, the washer 140 is mounted on the screw 141 and laid on the distal end of the engagement projection 138B (
For example, as shown in FIGS. 35 to 38, the engagement member 138 may not have the engagement projection 138B, and the washer 140 and the screw 141 may not be provided on the distal end of the engagement projection 138B. In this configuration, the knob part 137A (
The digital display unit 160′ is positioned separated from the main unit 130 as shown in
If the router 101′ is used with the digital display unit 160′ removed from the main unit 130, the digital display unit 160′ need not be positioned upside down, regardless of the positional relationship between the base 110 and the main unit 130 in the vertical direction. Hence, the user can correctly read the numerical value on the display unit 160B′.
In this case, the distal display unit 160′ may not be connected to the main unit 130 by a cord. Instead, the numerical data may be exchanged between the digital display unit 160′ and the main unit 130 by radio communication, and the digital display unit may have a power supply separated from the power supply for driving the electric motor.
As shown in
The detection unit is not limited to the type described above. Instead, the detection unit may be a photoelectric type having a photosensor of a light shield, an electrostatic capacitor type that changes in electrostatic capacitance, or a magnetic type that detects the magnetic fluxes emanating from magnetic poles provided on the stopper pole at regular intervals.
The fastening mechanism 115D is located around the turntable section 115A. The mechanism 115D may have a different configuration, except that the mechanism 115D abuts on one end of the stopper pole and holds the stopper pole to disable the stopper pole to move with respect to the base.
The main unit 130 incorporates the centrifugal fan 133. The fan 133 may be replaced with any other type of fan.
The hollow cylindrical part of the dust guide may have a larger inside diameter in the lower end that abuts on the dust-guide receptacle than in the upper end that faces the annular through hole. If the hollow cylindrical part has this structure, the fan air can blow chips outward in the radial direction of the dust guide, or from the center of the hollow cylindrical part toward the inner circumferential surface thereof.
In the above embodiment, the stopper pole 165 is provided. In another embodiment, the stopper pole 165 can be eliminated. In this case, the router may have any unit for detecting the positions of the columns with respect to the main unit or the position of the bolt with respect to the main unit.
Further, the light ON/OFF switch 160D and the zero-setting switch 160E, both shown in
When the engagement member is engaged with the bolt and the bolt is rotated about the longitudinal axis, the engagement member is threaded and moved with respect to the bolt in the perpendicular direction to the base. Accordingly, threading movement of the engagement member moves the main unit with respect to the base. Hence, the position of the main unit can be finely adjusted with respect to the base and the bolt.
Unless the male thread of the drive member is threaded and moved with respect to the first female thread portion, the engagement member is maintained at one of the engaged position and the disengaged position. Hence, the user does not have to do anything to maintain the engagement member at the one of the engaged position and the disengaged position.
The engagement member is moved together with the drive member due to the treading movement of the drive member, so that the engagement member is moved between the engaged position and the disengaged position.
When the engagement member moves together with the drive member due to a threading movement of the drive member, the male thread of the drive member can be urged to the female thread of the main unit. Accordingly, no play develops between the male thread and the female thread.
The engagement member can be moved to the engaged position by an elastic force of the elastic member.
The restricting unit restricts a pivot of the operation member when the engagement member is in one of the engaged position and the disengaged position. Hence, the operation member is prevented from rotating beyond the operational range of the operation member.
When the fastening member is loosened at the coupling portion, the positional relation between the lever member and the drive member is finely adjustable. Hence, when the restricting unit restricts the pivot of the operation member, the position of the drive member can be finely adjusted so that the engagement member can be located at an optimal engaged position or an optimal disengaged position.
Number | Date | Country | Kind |
---|---|---|---|
P2005-151350 | May 2005 | JP | national |