JP2011036972A - Guide attachment of electric drill and boring machine including the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a guide attachment of an electric drill with which boring work can be guided on a target to be bored and a boring depth adjusted during the boring work does not vary. <P>SOLUTION: The guide attachment 5 of the electric drill 3 having a drill bit 2 mounted for guiding the boring work on the target C to be bored includes a nested slide guide 53 comprising a guide holder 51 mounted on the electric drill 3 coupled with a nose block 52 having an insertion opening 61 to which the drill bit 2 is inserted and pushed against the target C. The slide guide 53 comprises a first guide cylinder 70 having one of ends fixed to the nose block 52 and a first guide rod 71 having one of ends screwed with the guide holder 51 which are slidably coupled. The first guide rod 71 has its sliding end position on a contraction side regulated in position by fitting, and also forms an adjustment screw mechanism AS by screwing with the guide holder 51. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a guide attachment of an electric drill that is attached to an electric drill to which a drill bit is attached and guides drilling of an object to be drilled by the electric drill, and a drilling device including the guide attachment.

Conventionally, there has been a depth adjustment mechanism in which a stopper pole is inserted into a hole in a holder portion of a grip attached to an electric drill equipped with a drill bit, adjusted to a desired length (depth), and then tightened and fixed with a knob screw. It is known (see Non-Patent Document 1).
In this depth adjustment mechanism, when drilling with an electric drill proceeds with respect to the drilling target, the tip portion of the stopper pole hits the drilling target, so that a hole with a desired depth can be formed. Yes.

Also, a dust collecting movable part that is attached to the hammer drill and covers the drill attached to the hammer drill, a can body in which the dust collecting movable part can be inserted in the length direction of the drill, and a dust collecting movable part incorporated in the can body There is known a drill attachment (guide attachment) provided with a spring for urging the front and a drilling length adjusting mechanism that faces the side surface of the can body and can adjust a drilling depth by a drill (Patent Document 1). reference).
This perforation length adjustment mechanism is fixed by sandwiching the side surface of the can body between the slider part and perforation length adjustment fixing part (knob). You can face it. And with this guide attachment, after fixing the drilling length adjustment mechanism, drilling work with a hammer drill is started, and drilling progresses and the slider part hits the rear end of the dust collecting movable part to form a hole of the desired depth Can be done.

JP 2008-023622 A

Makita Corporation Diacore Vibrating Drill Model 8406C Instruction Manual

However, in the depth adjustment mechanism as described above, there is no function to guide the movement of the electric drill in the drilling direction during drilling work, and it is difficult to keep the drilling angle with respect to the drilling target constant, There is a problem that the depth of the hole formed varies depending on the drilling angle. Further, since the holder part and the stopper pole protrude from the electric drill side, there is a problem that it becomes an obstacle in handling during drilling work.
In addition, the guide attachment as described above can guide the movement of the hammer drill in the drilling direction, but the fixed state of the drilling length adjusting mechanism is loosened due to vibration during drilling operation, etc. The depth could go crazy. Moreover, since the drilling length adjusting mechanism protrudes from the side surface of the can body in the same manner as described above, it has become an obstacle during the drilling operation.

  It is an object of the present invention to provide a guide attachment for an electric drill that can guide drilling of an object to be drilled, and that does not change the drilling depth adjusted during the drilling operation, and a drilling device including the guide attachment. It is said.

  The guide attachment of the electric drill of the present invention is a guide attachment for an electric drill that is attached to an electric drill equipped with a drill bit and guides drilling of an object to be drilled by the electric drill, and is attached to the electric drill. A guide holder, a nose block that has an insertion opening through which a drill bit is inserted, and a slide guide that extends and retracts in a telescopic manner by connecting the guide holder and the nose block. The guide is slidably connected to a guide tube having one end fixed to the nose block and a guide rod threaded to the guide holder. The guide rod contracts due to contact. The position of the sliding end on the side is regulated, and the adjustment screw mechanism is configured by screwing with the guide holder. And butterflies.

  In this case, it is preferable that the position of the sliding end is regulated by the guide rod hitting the nose block.

According to these configurations, it becomes easy to keep the drilling angle with respect to the drilling target constant by abutting the nose block against the drilling target. Further, the length of the guide rod on the contraction side is adjusted by rotating the guide rod forward and backward with respect to the guide holder, and the distance between the tip of the guide rod and the contact is adjusted. That is, the drilling depth of the hole formed by the electric drill is adjusted by the adjusting screw mechanism. Thereby, the shift | offset | difference of the drilling depth resulting from the change of a drilling angle can be prevented. Further, by using the adjusting screw mechanism, the structure can be simplified and the drilling depth can be adjusted steplessly. In addition, since the slide guide (guide rod) that supports the nose block also has a function of adjusting the drilling depth, there is no protruding portion, and the adjusting screw mechanism does not get in the way during the drilling operation.
Furthermore, the adjustment screw mechanism has a fixed tightening length because the guide rod is directly screwed into the guide holder, and the guide rod receives rotational resistance from the guide cylinder, and therefore is configured to be relatively difficult to loosen. Can do. For this reason, the shift | offset | difference of the sliding end position of the guide rod adjusted by the vibration etc. during a drilling operation | work can be prevented effectively.

  In this case, it is preferable that one end portion of the guide rod penetrates the nose block and is exposed when it comes into contact with the nose block.

  According to this configuration, the operator can recognize that the drilling of a predetermined depth has been completed by recognizing the end portion of the guide rod exposed from the nose block. Thereby, the end of drilling can be confirmed visually without depending on the operator's intuition and experience, and anyone can easily and reliably perform the drilling work.

  In this case, it is preferable that one end portion of the guide rod constituting the adjusting screw mechanism extends through the guide holder.

  According to this configuration, since the guide rod extends to the side of the electric drill that is actually operated by the operator, the operator can easily adjust the drilling depth by the adjusting screw mechanism.

  In this case, it is preferable that a scale for indicating the drilling depth with respect to the drilling object is disposed along the extending portion of the guide rod.

  According to this configuration, it is not necessary for the operator to separately prepare a ruler and measure and set the drilling depth, and the drilling depth can be set quickly and accurately.

  Furthermore, in this case, it is preferable that a lock nut attached to the guide holder is screwed into one end portion of the guide rod constituting the adjustment screw mechanism.

  According to this configuration, the lock nut can more effectively prevent loosening in the adjustment screw mechanism adjusted to a desired drilling depth, and can surely prevent positional deviation of the adjusted guide rod.

  In this case, the guide holder and the nose block are connected to each other, and a second slide guide that is telescopically telescopic is further provided, and the slide guide and the second slide guide are disposed at point-symmetric positions with respect to the drill bit. It is preferable.

  In this case, the second slide guide is formed by slidably connecting a guide cylinder having one end fixed to the guide holder and a guide rod having one end fixed to the nose block. Is preferred.

  According to these configurations, it is possible to more firmly support the nose block that is abutted against the object to be drilled, and to guide the drilling straight without tilting the drill bit during the drilling operation.

  In this case, it is preferable to further include a coil spring that is provided so as to be wound around at least one of the slide guide and the second slide guide, and receives the guide holder to urge the nose block in the forward direction.

  According to this configuration, if the operator removes the force when the drilling operation is completed, the drill bit can be pulled out from the hole in which the drill bit is formed while being guided to each slide guide by the coil spring. Thereby, workability can be improved and the drill bit can be pulled straight out of the hole.

  A drilling device according to the present invention includes the above-described electric drill guide attachment and the electric drill.

  According to this configuration, it is possible to guide the drilling with respect to the drilling target, and it is possible to perform the drilling operation with the electric drill without causing the adjusted drilling depth to be out of order.

It is the external view which showed typically the punching apparatus which concerns on this embodiment. It is sectional drawing which showed the valve closing state (a) and the valve opening state (b) in a coolant supply attachment. It is a three-view figure of an electric drill and a guide attachment. It is the front view and side view of a nose block. It is the front view and side view (a) of the nose block which concern on a modification, and the front view (b) of the nose block which concerns on another modification. It is the perspective view (a) of a dust seal, and sectional drawing (b) of the dust seal at the time of pressing a nose block against a drilling target object. It is the top view which shows the backward end position (a) of a guide attachment, and an advance end position (b), and sectional drawing (c) of a contact member. It is a fragmentary top view of the guide attachment which concerns on a modification (three forms).

  Hereinafter, a perforating apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings. In this drilling device, a guide attachment for guiding drilling is mounted on an electric drill, and drilling work is performed on concrete, tile, stone, or the like.

  As shown in FIG. 1, the drilling device 1 includes a drill bit 2 that performs wet drilling on a drilling target C such as concrete, an electric drill 3 that rotates the drill bit 2, a drill bit 2, and an electric drill 3. The coolant supply attachment 4 interposed therebetween, the guide attachment 5 that is abutted against the drilling object C and guides drilling of the electric drill 3, and the coolant is supplied to the drill bit 2 through the coolant supply attachment 4. And a coolant recovery means 7 for sucking and recovering the coolant supplied to the drill bit 2 through the guide attachment 5.

  The coolant supply means 6 includes a pressure feeding device 6 a that feeds the coolant from the supply tank 6 b storing the coolant to the drill bit 2. The coolant recovery means 7 includes a suction pump 7a for sucking the coolant supplied to the drill bit 2 together with the grinding powder (dust) of the drilling object C, and a recovery tank 7b for discarding and storing the coolant mixed with dust. It is equipped with. In addition, it is preferable to use what mixed alcohol in order to accelerate | stimulate the drying (vaporization) after a work as a coolant.

  A supply tube 6c connected to the coolant supply means 6 is connected to the base side of the coolant supply attachment 4. When drilling by the drill bit 2 is started, the supply tube 6c and the coolant supply attachment are supplied from the coolant supply means 6. 4, the coolant is supplied to the drill bit 2. Further, a recovery tube 7c connected to the coolant recovery means 7 is connected to the distal end side of the guide attachment 5, and the coolant recovery means 7 is subject to drilling of the coolant supplied to the drill bit 2 via the recovery tube 7c. Suction and collected together with grinding powder (dust) of object C.

  In the drilling operation, the operator supports the electric drill 3 by hand so that the tip (cutting edge 11) of the drill bit 2 is applied to the required drilling location of the drilling target C via the guide attachment 5, and the drill body 15 The drill bit 2 is rotated to form a hole with a predetermined depth in the drilling object C. At this time, the coolant pressurized and supplied from the coolant supply means 6 to the coolant supply attachment 4 is linked from the coolant supply attachment 4 to the drill bit 2 in conjunction with the operation of abutting the cutting blade 11 against the drilling object C. And is supplied to the cutting blade 11. In addition, the coolant supplied to the cutting blade 11 is recovered by the coolant recovery means 7 from the tip of the guide attachment 5 in a state of being mixed with the grinding powder of the drilling object C.

  The drill bit 2 is a diamond core bit that grinds the drilling object C into a ring shape so as to leave the core part. The drill bit 2 has a cutting edge 11 (diamond cutting blade) for drilling the drilling object C and a tip at the tip. A shank 12 that holds the blade 11 and is attached to the coolant supply attachment 4 at the base end. In the axial center portion of the drill bit 2, a core piece of the drilled object C is called in and an in-bit channel 13 serving as a coolant channel is formed. The coolant is guided to the tip of the cutting edge 11 through the channel 13 in the bit, while the ground core piece of the drilled object C is relatively guided from the cutting blade 11 to the channel 13 in the bit. . In the following description, the drilling direction for the drilling object C is defined as the front (front side), and the opposite direction is defined as the rear (rear side).

  The cutting blade 11 is formed in a cylindrical shape so as to grind the drilling object C so as to leave the core portion, and is formed to have a somewhat larger diameter than the shank 12. The shank 12 has a cutting edge 11 fixed to a front end portion and a cylindrical joining recess 14 formed at a rear end portion. A female screw is formed on the inner peripheral surface of the joint recess 14 and is screwed into a joint convex portion 47 (see FIG. 2A) of the output shaft 22 which will be described later and has a male screw formed on the outer peripheral surface. As a result, the drill bit 2 is detachably attached to the coolant supply attachment 4. In addition, a seal member (O-ring) (not shown) is attached to a portion corresponding to the bottom surface of the joint recess 14, and when the joint recess 14 is screwed to the joint projection 47, the in-bit channel 13 and a later-described portion are provided. The output shaft flow path 48 of the output shaft 22 is in fluid-tight communication.

  The electric drill 3 includes a drill body 15 in which a motor driven by a common power source and a speed reducer (not shown) that decelerates and outputs the rotation of the motor are housed in a motor housing 16, and a grip portion extending rearward from the drill body 15 17. Further, a guide holder 51 (details will be described later) on which a rear end portion of the guide attachment 5 is fixed is formed to project from the front portion of the drill body 15. Furthermore, a single character grip G for supporting the electric drill 3 by hand is attached to the front portion of the drill body 15. The grip portion 17 is provided with a trigger switch SW that controls the start / stop of driving by the operator. The main shaft 18 extending from the speed reducer is connected to an input shaft 21 of a coolant supply attachment 4 described later at the front end portion of the drill body 15 (see FIG. 2).

  As shown in FIG. 2, the coolant supply attachment 4 has a cylindrical appearance, is attached to a drill body 15 (motor housing 16), and is rotatably supported by the attachment case 20. An input shaft 21 to which the main shaft 18 of the main body 15 is connected, and an output shaft flow channel 48 that is rotatably held integrally with the input shaft 21 and slidable in the axial direction, and communicates with the above-described bit flow channel 13. And an output shaft 22 formed. A pressurization flow path 23 is formed in the gap between the input shaft 21 and the output shaft 22, and the coolant supply attachment 4 is a valve that communicates or shields the pressurization flow path 23 and the output shaft internal flow path 48. A mechanism 24 is further provided.

  The attachment case 20 has a hook-like annular convex portion for mounting on the motor housing 16 at the rear end portion, and has a substantially cylindrical shape as a whole. A coolant introduction port 25 penetrating the attachment case 20 in the radial direction is formed in the front and rear intermediate portion of the attachment case 20, and the supply tube 6 c is connected to the coolant introduction port 25 via a joint (screw connection). ing.

  A front bearing 26 and a rear bearing 27 (both ball bearings) that rotatably support the input shaft 21 are fitted in front of and behind the attachment case 20 in a state of being prevented from coming off. On the rear side of the front bearing 26 and the front side of the rear bearing 27, a seal packing 28 that is in contact with the outer peripheral surface of the input shaft 21 that is pivotally supported is disposed. By the pair of seal packings 28, an annular coolant reservoir 29 is liquid-tightly formed between the inner peripheral surface of the attachment case 20 and the outer peripheral surface of the input shaft 21. A coolant introduction port 25 communicates with the coolant reservoir 29 and is filled with the coolant introduced from the coolant introduction port 25.

  The input shaft 21 is integrally formed by a main shaft connecting portion 31 with a gear connected to the main shaft 18 of the drill main body 15 and an input shaft main body 32 connected to the front of the main shaft connecting portion 31 and formed in a bottomed cylindrical shape. Is formed. The input shaft 21 is rotatably supported by the attachment case 20 by the front bearing 26 and the rear bearing 27 described above. Further, an annular retaining flange portion 33 that functions as a retaining member for the front bearing 26 protrudes from the front side surface of the input shaft main body 32.

  At the front end portion of the outer peripheral surface of the input shaft main body 32, a connection male screw portion 34 is formed in which a connection cap 44 for holding the output shaft 22 so as to be integrally rotatable and slidable in the axial direction is screwed. . The connection male screw portion 34 is formed with a notch 35 that engages with a key 45 fitted to the output shaft 22 described later so as to cut from the front.

  A slide support portion 36 is formed at the shaft center of the input shaft main body 32 to hold the output shaft 22 so as to be integrally rotatable and slidable in the axial direction. The sliding support portion 36 is connected to the first sliding support portion 36a having a small diameter communicating with the coolant introduction port 25 opened in the attachment case 20, and the front of the first sliding support portion 36a, and the front end thereof is opened. A second sliding support portion 36c having a large diameter. The first sliding support part 36a and the second sliding support part 36c are provided on the same axis.

  The first sliding support portion 36a forms a cylindrical space and supports the rear end portion of the output shaft 22 to be slidable. In the rear end portion of the first sliding support portion 36a, an introduction passage 36b communicating with the coolant reservoir 29 is formed penetrating in the radial direction.

  The second sliding support portion 36c as a whole forms a columnar space having a larger diameter than the first sliding support portion 36a, and supports the intermediate portion of the output shaft 22 so as to be slidable. That is, the second sliding support part 36c includes a liquid passage part 36d communicating with the front of the first sliding support part 36a, and a sliding contact part 36e formed with a smaller diameter than the liquid passage part 36d and having the front end opened. And a tapered portion 36f formed between the liquid passage portion 36d and the sliding contact portion 36e.

  The output shaft 22 includes a narrow-diameter portion 41 that is slidably supported by the first sliding support portion 36a, a large-diameter portion 42 that is slidably supported by the second sliding support portion 36c, and a large-diameter portion 42. The bit mounting portion 43 connected to the front end is configured as a stepped shaft coaxially and integrally. The small-diameter portion 41 is inserted into the first sliding support portion 36a, and the large-diameter portion 42 is inserted into the sliding contact portion 36e of the second sliding support portion 36c with slidable dimensional tolerances. As described above, since the sliding of the output shaft 22 in the front-rear direction is guided at the two front and rear positions of the input shaft 21 (the first sliding support portion 36a and the second sliding support portion 36c), the output shaft 22 is , Can be slid with stable straightness.

  The output shaft 22 is locked to the input shaft 21 by the connecting cap 44 at the portion of the large diameter portion 42. The connection cap 44 is screwed into the connection male screw portion 34 of the input shaft main body 32 with the output shaft 22 passing through the bottom. A key groove 45 a into which the key 45 is fitted is formed at the substantially center in the axial direction of the outer peripheral surface of the large-diameter portion 42. The output shaft 22 is attached to the input shaft 21 (input shaft main body 32) so as to be integrally rotatable and slidable in the axial direction by the keyway 45a and the key 45.

  The bit mounting portion 43 is connected to the front side of the large-diameter portion 42, is attached to the output flange portion 46 that restricts the rearward movement of the output shaft 22, and the back surface of the output flange portion 46. It has a buffering O-ring B for reducing the impact, and a joint convex portion 47 connected to the front of the output flange portion 46. A male thread is formed on the outer peripheral surface of the joint convex portion 47, and the shank 12 (joint concave portion 14) of the drill bit 2 is screwed together. In order to fix the drill bit 2 to the output shaft 22, tool hooks (not shown) are formed in the joint recess 14 and the output flange portion 46, respectively.

  As described above, the pressurizing flow path 23 through which the coolant flows is formed in the gap between the input shaft 21 and the output shaft 22. Specifically, the pressurizing flow path 23 includes the first pressurizing flow path 23a surrounded by the first sliding support part 36a and the small diameter part 41, the second sliding support part 36c, the large diameter part 42, and the small diameter. And a second pressurizing flow path 23b having a gap with the portion 41. Although details will be described later, the small-diameter portion 41 is pressurized by the coolant flowing into the first pressurizing channel 23a, and the large-diameter portion 42 and the small-diameter portion 41 by the coolant flowing into the second pressurizing channel 23b. The step between is pressurized.

  At the shaft center of the output shaft 22, an output shaft flow channel 48 that connects the pressurizing flow channel 23 and the bit internal flow channel 13 is formed. Specifically, the output shaft flow path 48 includes a first output shaft flow path 48 a formed in the shaft center of the small diameter portion 41 and a second output shaft flow formed in the shaft center of the large diameter section 42. And a path 48c. The first output shaft channel 48a is opened to communicate with the first pressurizing channel 23a by opening the rear end, and through the first radial channel 48b formed through the front end in the radial direction. It communicates with the pressure channel 23b. On the other hand, the second output shaft flow path 48c communicates with the second pressurizing flow path 23b through a second radial flow path 48d formed in a radial direction at the rear end portion, and is mounted with the front end opened. The drill bit 2 communicates with the in-bit flow path 13.

  That is, the coolant supplied from the coolant supply means 6 via the supply tube 6c is from the upstream side (rear side), the coolant introduction port 25, the coolant reservoir 29, the introduction flow path 36b, and the first pressurization flow path 23a. , The first output shaft channel 48 a, the first radial channel 48 b, the second pressure channel 23 b, the second radial channel 48 d, the second output shaft channel 48 c, and the bit channel 13. Flow is supplied to the cutting edge 11 at the downstream end (front end) (see FIG. 2B).

  The output shaft 22 has a pressure receiving portion 49 that faces the pressurizing flow path 23 and receives pressure in the forward direction by the coolant introduced into the pressurizing flow path 23. Specifically, the pressure receiving portion 49 includes a first pressure receiving portion 49 a configured by an opening edge portion of the first output shaft flow passage 48 a opened at the rear end surface of the small diameter portion 41, a large diameter portion 42, and a small diameter portion 41. And a second pressure receiving portion 49b configured by a step portion therebetween. The first pressure receiving part 49a receives the pressure of the coolant introduced into the first pressurizing flow path 23a, while the second pressure receiving part 49b receives the pressure of the coolant introduced into the second pressurizing flow path 23b. By receiving it, the force which advances to the output shaft 22 is made to act (refer Fig.2 (a)).

  The valve mechanism 24 includes a pair of O-rings 24a (valve bodies) fitted in a pair of annular grooves D formed in the axial direction on the outer peripheral surface of the rear end portion of the large diameter portion 42, and a second sliding support. And a valve seat 24b constituted by a sliding contact portion 36e of the portion 36c (an inner peripheral wall of the downstream end portion of the second pressurizing flow path 23b). Each O-ring 24a is made of an elastic member such as rubber, and the large-diameter portion 42 into which the pair of O-rings 24a is fitted is slidably and liquid-tightly attached to the valve seat 24b (sliding contact portion 36e). ing. As described above, by providing the O-rings 24a twice, it is possible to appropriately prevent the leakage of the coolant from the second pressurizing flow path 23b. In addition, the second radial flow path 48d described above is opened between the pair of O-rings 24a.

  During the drilling operation, when the tip of the drill bit 2 (the cutting edge 11) is pressed against the drilling object C, the output shaft 22 moves backward relative to the input shaft 21. Then, the rear O-ring 24a and the second radial flow path 48d are shifted to positions facing the liquid passage part 36d (or the tapered part 36f), and the second radial flow path 48d and the second pressurization flow path 23b are moved. Communication (opens the valve) (see FIG. 2B). Then, the coolant in the second pressurizing flow path 23 b flows into the second output shaft flow path 48 c through the second radial flow path 48 d and is supplied to the bit internal flow path 13. At this time, since the front O-ring 24a is in close contact with the valve seat 24b (sliding contact portion 36e), the second pressurizing flow path 23b is kept liquid-tight.

  On the other hand, after the drilling operation is completed or before the drilling operation, the pressure by the coolant introduced into the first pressurizing flow path 23a and the second pressurizing flow path 23b acts on the first pressure receiving part 49a and the second pressure receiving part 49b. Thus, the output shaft 22 moves forward relative to the input shaft 21. Then, the rear O-ring 24a and the second radial flow path 48d face a position in close contact with the valve seat 24b, and the second radial flow path 48d and the second pressurization flow path 23b are shielded (valve closed), Supply of the coolant to the in-bit flow path 13 is stopped (see FIG. 2A). At this time, the rear O-ring 24a is guided by the tapered portion 36f and smoothly enters the sliding contact portion 36e, and is brought into an appropriate valve closing state.

The movement of the output shaft 22 in the forward direction is due to the pressure of the coolant acting on the pressure receiving portion 49 (the first pressure receiving portion 49a and the second pressure receiving portion 49b). Compared to energizing, it moves slowly. For this reason, even after the drilling operation is finished and the pressing of the drill bit 2 against the drilling target C is released, the valve is not immediately closed and the supply of the coolant to the drill bit 2 is continued for a short time. . As a result, dust inside the drilled hole can be washed out together with the coolant, and after the drill bit 2 is pulled out, there is no need to separately clean the inside of the hole, and the subsequent process (anchor embedding, etc.) smoothly proceeds. be able to.
In addition, you may arrange | position the spring (illustration omitted) for assisting the movement to the front of the output shaft 22 in the 1st pressurization flow path 23a or (and) the 2nd pressurization flow path 23b. Even in this case, it is the pressure acting on the pressure receiving portion 49 that moves the output shaft 22 forward, and the spring is provided only as an auxiliary. Further, it is preferable that the operator does not pull out the drill bit 2 until the valve mechanism 24 is closed after completion of the drilling operation (stop of driving of the electric drill 3).

  Further, it is preferable that the first output shaft flow path 48 a has a sufficiently small diameter with respect to the diameter of the small diameter portion 41. By doing in this way, since the pressure of the 1st pressurization flow path 23a and the 2nd pressurization flow path 23b increases individually with a time difference, respectively, the output shaft 22 is more slowly with respect to the input shaft 21. Advance. Thereby, the valve closing after canceling the pressing of the drill bit 2 against the drilling object C can be delayed further, and the cleaning of the inside of the hole can be performed more accurately.

  Next, the guide attachment 5 will be described with reference to FIGS. 3 to 8. The guide attachment 5 includes a pair of guide holders 51 projecting from the front end of the drill body 15, a nose block 52 that is abutted against the drilling object C, and a pair that is passed between the guide holder 51 and the nose block 52. The slide guide 53 is provided. The pair of slide guides 53 and the drill bit 2 are located in the middle of the left and right slide guides 53 and extend forward in parallel with each other.

  Each guide holder 51 is a block-like member integrally formed on the upper side of the front end portion of the drill main body 15 in FIG. 3, and is constituted by aluminum die casting. Further, the pair of guide holders 51 are disposed at the left and right ends of the drill body 15 in FIG. Each guide holder 51 is formed with a shaft through hole 54 extending in the front-rear direction. A guide nut 55 is fitted in each shaft through hole 54 and fixed by a retaining screw 56 from the radial direction. The guide nut 55 is supported such that the rear end portion of each slide guide 53 is screwed. In the present embodiment, each guide holder 51 is formed integrally with the drill body 15, but each guide holder 51 may be attached to the drill body 15 as a separate member.

  As shown in FIGS. 3 and 4, the nose block 52 has an abutment guide portion 57 in which an insertion opening 61 through which the distal end portion of the drill bit 2 faces is formed at the center portion, and the front end portions of the pair of slide guides 53. A pair of guide fixing portions 58 to be fixed and a dust seal 59 attached to the insertion opening 61 are configured. The abutting guide portion 57 and the pair of guide fixing portions 58 are integrally formed by aluminum die casting or the like, and the dust seal 59 is formed by an elastic material such as rubber.

  The abutting guide part 57 is integrally formed by a plate part 62 formed in a plate shape that abuts against the perforation object C, and a block part 63 that protrudes rearward from the center of the width of the plate part 62 in a block shape. Yes. The plate portion 62 has a horizontally long rectangular shape (four corners are right-angled) in a plan view, and the surface of the plate portion 62 that comes into contact with the perforation object C (contact surface S) has rubber or the like (fluoro rubber). The contact sheet 64 formed of an elastic material is preferably attached. The abutting surface S and the axial direction of the drill bit 2 are orthogonal to each other. When the abutment guide portion 57 is abutted against the drilling object C, the drill bit 2 faces the drilling object C at a right angle. (See FIG. 1).

  When performing the drilling operation, the operator abuts the nose block 52 against the drilling object C and brings the contact surface S of the abutting guide portion 57 into surface contact with the surface (drilling surface) of the drilling object C. At this time, since the drilling surface and the contact surface S are in surface contact, the orthogonal state between the drilling surface and the drill bit 2 can be stably maintained. In this state, by performing a drilling operation with the electric drill 3, holes can be formed in a direction perpendicular to the drilling surface. Furthermore, since the contact sheet 64 (contact surface S) is made of an elastic material, the piercing object C is not damaged when the nose block 52 is abutted against the piercing object C. In addition, it is preferable that the contact sheet 64 has a non-slip function. Thereby, it is possible to effectively prevent the shaft bit of the drill bit 2 at the start of the drilling operation and the positional deviation during the drilling operation.

  Further, the planar dimension of the plate portion 62 is 90 mm × 40 mm corresponding to the dimension (94 mm × 54 mm) of the “new edge” frequently used as the exterior tile. Further, in FIG. 3, an aiming member 65 for indicating the axial center of the drill bit 2 is provided on the upper side of the abutting guide portion 57 and in the center in the width direction. With these configurations, accurate alignment can be performed with respect to the required drilling location of the drilling target C, and proper drilling can be performed at a desired position. In addition, the planar dimension of the plate part 62 is not limited to the above dimensions, and it is preferable to arbitrarily change the drilling object C or the like according to the use situation.

  In FIG. 3, a discharge port 66 is formed through the lower side of the block portion 63 from the inner peripheral surface of the insertion opening 61 where the tip of the drill bit 2 faces obliquely rearward. One end of a connection member 67 (joint) is screwed and fixed to the discharge port 66, and the recovery tube 7 c is connected to the other end of the connection member 67. Thereby, the coolant recovery means 7 is connected to the insertion opening 61 via the discharge port 66, the connection member 67 and the recovery tube 7 c, and the coolant supplied to the drill bit 2 is sucked by the coolant recovery means 7. It is collected (see FIG. 1).

In the present embodiment, the abutting guide portion 57 is configured to come into surface contact with the drilling target C. However, as shown in FIG. Convex portions 68 may be provided at the four corners of the surface facing C. Even in this case, the orthogonal state between the drilling surface and the drill bit 2 can be stably maintained as described above. In addition, the shape, the number of arrangement | positioning, and the arrangement position of the convex part 68 are arbitrary.
Further, as shown in FIG. 5 (b), the lower corners (two places) of the plate part 62 may be cut out to form a “T” shape in front view, or FIG. 5 (a). Similarly to the one shown in FIG. 3, the convex portions 68 may be provided at three places on the “T” -shaped plate portion 62. In addition, although not shown, a notch or an opening may be formed in a portion excluding the corner of the plate portion 62. That is, the abutting guide part 57 should just be comprised so that the drill bit 2 may oppose at right angle with respect to the drilling target object C. FIG. Thereby, alignment to a perforation required location can be performed easily.

  Each guide fixing portion 58 is a block-like member protruding above the abutting guide portion 57 in FIG. In addition, the pair of guide fixing portions 58 are disposed at the left and right ends of the abutting guide portion 57 in FIG. A fixed female screw hole 69 is formed through each guide fixing portion 58 in the front-rear direction, and a front end portion of each slide guide 53 is screwed into each fixed female screw hole 69. Accordingly, the nose block 52 is supported by a pair of slide guides 53 extending in parallel from the pair of guide holders 51.

  As shown in FIG. 6A, the dust seal 59 has the form of a cylindrical portion 59a inserted and mounted in the insertion opening 61 of the abutting guide portion 57, and an inner and outer double annular seal piece that is in close contact with the drilling object C. The horn part 59b has a seal flange part 59c interposed between the cylindrical part 59a and the horn part 59b. The cylindrical portion 59a is formed in a bottomed cylindrical shape, and an insertion hole (not shown) communicating with the insertion opening 61 described above is formed in the bottom portion. In addition, an oval discharge hole 59d communicating with the discharge port 66 is formed on the inner peripheral surface of the cylindrical portion 59a.

  As shown in FIG. 4, the insertion opening 61 opened in the abutting guide portion 57 is pressed against the small-diameter opening 61 a opened at substantially the same diameter as the cylindrical portion 59 a at the rear and the horn portion 59 b at the front. And a large-diameter opening 61b that is opened with substantially the same diameter as the diameter when expanded. The large-diameter opening 61b has a depth such that the seal flange portion 59c slightly enters the contact surface S when the dust seal 59 is inserted and attached to the insertion opening 61 from the front. That is, in a state where the dust seal 59 is attached to the insertion opening 61, the horn portion 59b slightly protrudes from the contact surface S.

  In a state where the nose block 52 is at the most advanced position, the cutting edge 11 of the drill bit 2 is accommodated in the dust seal 59 with a predetermined gap. When the nose block 52 is pressed against the drilling object C along with the drilling operation, the cutting blade 11 cuts into the drilling object C while projecting relatively from the close dust seal 59. At this time, since the seal flange portion 59c is pressed against the edge of the small diameter opening 61a, the dust seal 59 does not sink into the insertion opening 61 (small diameter opening 61a).

  Further, as shown in FIG. 6 (b), as the dust seal 59 is pressed against the drilling target C, the inner and outer double annular seal pieces of the horn portion 59b bend and expand outward in the radial direction. Adhere to C. At this time, the bent horn portion 59b expands within the large-diameter opening 61b while retreating relatively, so that the horn portion 59b and the contact surface S are flush with each other. Thereby, the contact surface S (contact sheet 64) is also brought into close contact with the piercing object C together with the horn portion 59b. In this way, the perforation edge is double sealed by the dust seal 59 and the contact sheet 64 is in close contact with the dust seal 59 so that the perforated surface and the drill bit 2 are in an orthogonal state. Scattering and leakage of the coolant mixed with dust can be effectively prevented while stably maintaining.

  On the other hand, the dust-mixed coolant flowing out from the perforated hole is sucked and collected by the coolant collecting means 7 through the discharge hole 59d and the discharge port 66 of the dust seal 59. The recovered coolant is preferably filtered and reused.

  As shown in FIGS. 3 and 7, the pair of slide guides 53 guides the sliding of the nose block 52 in the front-rear direction with respect to the electric drill 3 (guide holder 51), and has a function of adjusting the drilling depth. The first slide guide 53a (right side in FIGS. 3 and 7), the second slide guide 53b in which the nose block 52 regulates the forward end position (left side in FIGS. 3 and 7), the first slide guide 53a and the first slide guide 53a. It comprises a pair of coil springs 90 provided so as to be wound around the two slide guides 53b.

  The first slide guide 53a includes a first guide cylinder 70 that supports the above-described nose block 52 at the front end, and a first guide rod 71 that is supported by the above-described guide holder 51 at the rear end. A first guide rod 71 is slidably connected to the one guide cylinder 70 in a nested manner.

  The first guide cylinder 70 is a cylindrical member in which a so-called straight hole is formed so as to penetrate the shaft center. The first guide cylinder 70 is screwed and fixed to the guide fixing portion 58 of the nose block 52 on the outer peripheral surface of the front end portion. A single cylinder male screw portion 72 and a first cylinder flange portion 73 disposed behind the first cylinder male screw portion 72 and having a tool hook portion are integrally formed. The first cylindrical male screw portion 72 is screwed into the fixed female screw hole 69 of the guide fixing portion 58 and fixed. The 1st cylinder flange part 73 contact | abuts to the peripheral part of the fixed internal thread hole 69, and the screwing of the 1st cylinder male thread part 72 is controlled. As a result, the first tube male screw portion 72 does not protrude from the tip of the guide fixing portion 58.

  The first guide rod 71 includes, from the front, a contact portion 74 whose tip penetrates through the guide fixing portion 58 and is exposed, a first sliding contact portion 75 slidably engaged with the first guide cylinder 70, and a guide holder 51 (right side in FIGS. 3 and 7), an adjustment male screw portion 76 screwed into a guide nut 55 fitted and fixed, and an instruction portion 77 serving as a pointer to a scale plate 79 (described later) for indicating a drilling depth. And are integrally formed. The contact portion 74, the first sliding contact portion 75, and the adjusting male screw portion 76 have a cylindrical shape with a circular cross section, while the indicator portion 77 that also serves as a tool hook has a square cross section. It has a square pillar shape.

The contact portion 74 has a smaller diameter than the inner diameter of the first guide tube 70 and a tapered tip, so that it does not slide on the inner peripheral surface of the first guide tube 70 (FIG. 7 ( a)). The first sliding contact portion 75 is in sliding contact with the inner peripheral surface of the first guide cylinder 70 with a slidable dimensional tolerance (see FIG. 7A). In addition, a contact member 71a is screwed into and fixed to the fixed female screw hole 69 of the guide fixing portion 58 from the front when the front end of the first guide rod 71 (first guide cylinder 70) comes in contact (see FIG. FIG. 7 (a)). A stepped hole 71b is formed through the shaft center of the contact member 71a so that the contact portion 74 can be inserted on the front side and the first sliding contact portion 75 can be inserted on the rear side (see FIG. 7 (c)).
In the drilling operation, when the nose block 52 is abutted against the drilling object C and drilling by the electric drill 3 proceeds, the first guide cylinder 70 fixed to the guide fixing portion 58 of the nose block 52 moves backward, and the first guide rod 71 and the electric drill 3 move relatively forward. Then, the contact portion 74 protrudes from the first guide cylinder 70 and the guide fixing portion 58, and the front end surface of the first sliding contact portion 75 (the step portion between the contact portion 74 and the first sliding contact portion 75) is stepped. It contacts (per degree) the step portion of the perforated hole 71b (see FIG. 7B). Thereby, the advance of the first guide rod 71 and the electric drill 3 is restricted. Further, the contact portion 74 protrudes (exposes) forward from the guide fixing portion 58 in a state where the first sliding contact portion 75 contacts the contact member 71a and a hole having a predetermined perforation depth is formed. The protruding contact portion 74 has a gap of about 5 mm in the contacted state, and does not contact the drilling object C. Thereby, the perforation target C is not damaged. Note that the size (distance) of the gap between the tip of the contact portion 74 and the drilling object C is arbitrary. Further, when the operator recognizes the exposed contact portion 74, it can be recognized that drilling of a predetermined depth has been completed. Thereby, the end of drilling can be confirmed visually without depending on the operator's intuition and experience, and anyone can easily and reliably perform the drilling work.

  The adjustment male screw portion 76 extends rearward through the guide holder 51 (guide nut 55), and the extended adjustment male screw portion 76 is a lock that comes into contact with the rear end portion of the guide nut 55 from the rear. A nut 78 (hexagon nut) is screwed. In addition, a scale plate 79 with a scale for indexing the drilling depth is attached to the motor housing 16 (drill body 15) along the extended adjustment male screw portion 76.

As described above, in the adjustment screw mechanism AS composed of the guide nut 55 (guide holder 51) and the adjustment male screw portion 76, the first guide rod 71 is rotated forward and backward to advance and retreat, thereby causing the contact portion 74 to move forward and backward. The separation distance (drilling depth) between the tip and the contact surface S of the nose block 52 is adjusted steplessly. At this time, by adjusting the rear end of the instructing unit 77 while matching the scale plate 79, the desired drilling depth can be set. For this reason, the operator can adjust the drilling depth quickly and accurately without preparing a ruler or the like separately.
Then, after adjusting the perforation depth, the lock nut 78 is brought into contact with the guide holder 51 from the rear side and tightened to be fixed in a loosening-prevented state. As a result, the adjusted position of the first guide rod 71 is not loosened due to vibrations associated with the drilling operation. When the lock nut 78 is tightened, a tool is also applied to the instruction portion 77 to prevent rotation, so that rotation is prevented.

  Such an adjustment screw mechanism AS has a simple structure, and the first slide guide 53a (first guide rod 71) that supports the nose block 52 also functions to adjust the drilling depth. Therefore, there are no protruding parts or the like that interfere with the drilling operation. Furthermore, since the first guide rod 71 is screwed directly into the guide nut 55 (guide holder 51), the adjustment screw mechanism AS has a fixed tightening length, and the first guide rod 71 has the first guide rod 71. Since rotational resistance is received from the cylinder 70, it is possible to achieve a configuration that is relatively difficult to loosen. For this reason, the shift | offset | difference of the sliding end position (drilling depth) of the 1st guide rod 71 adjusted by the vibration etc. during a drilling operation | work can be prevented effectively.

  In the present embodiment, the first sliding contact portion 75 hits the contact member 71a to restrict the forward movement of the first guide rod 71 and the electric drill 3, but it is shown in FIG. In this way, the contact portion 74 may be brought into contact with the closed portion by closing the front end portion of the first guide cylinder 70. Similarly, the front end portion of the guide fixing portion 58 may be closed (FIG. 8B). In addition, the forward movement of the first guide rod 71 and the electric drill 3 may be restricted by the contact portion 74 coming into contact with the drilling target C (see FIG. 8C). Even in these cases, it is possible to perform drilling with a desired drilling depth. When the contact portion 74 is brought into contact with the drilling target C, it is preferable that the tip of the contact portion 74 is covered with an elastic material or the like (or formed with an elastic material) so as not to damage the drilling target C. .

  Subsequently, the second slide guide 53b has a second guide cylinder 80 supported by the guide holder 51 described above at the rear end portion, and a second guide rod 81 supporting the nose block 52 described above at the front end portion. The second guide rod 81 is slidably connected to the second guide cylinder 80 in a nested manner. The second slide guide 53b is arranged point-symmetrically with the first slide guide 53a, but may be arranged symmetrically with the first slide guide 53a.

  The second guide cylinder 80 has, on the outer peripheral surface of the rear end portion thereof, a second cylinder male screw portion 82 that is screwed through a guide nut 55 fitted and fixed to the guide holder 51 (left side in FIGS. 3 and 7). Is formed. The second cylinder male screw portion 82 penetrates the guide holder 51 (guide nut 55) and extends rearward. The U-nut 83 is screwed into the extended second cylinder male screw portion 82. . The second guide cylinder 80 is fixed to the guide holder 51 in a loosening-prevented state by tightening the U-nut 83 with the rear end of the guide nut 55 from behind.

  In addition, a so-called straight hole is formed in the axial center of the second guide cylinder 80, but only the front end portion is formed with a somewhat small diameter with an annular stepped portion, and the second guide rod 81 is formed in this portion. A retaining portion 84 that functions as a retaining member is formed.

  The second guide rod 81 is disposed on the outer peripheral surface of the front end portion and is disposed behind the second rod male screw portion 85 that is screwed into the fixed female screw hole 69 of the guide fixing portion 58 described above, and the second rod male screw portion 85. A second rod flange portion 86 having a hook portion, a rod main body 87 connected to the second rod flange portion 86, and a second sliding contact portion 88 formed at the rear end portion of the rod main body 87 are integrally formed. Yes.

  The second rod male screw portion 85 is screwed into the fixed female screw hole 69, whereby the second guide rod 81 is fixed to the guide fixing portion 58 of the nose block 52. The second rod flange portion 86 abuts on the peripheral edge portion of the fixed female screw hole 69 and the screwing of the second rod male screw portion 85 is restricted. As a result, the second rod male screw portion 85 does not protrude from the tip of the guide fixing portion 58.

  The second sliding contact portion 88 has a larger diameter than the rod main body 87 and engages with the second guide cylinder 80 in a retaining state. That is, the position of the most advanced end position of the second slide guide 53b (nose block 52) is regulated by the second sliding contact portion 88 abutting against the retaining portion 84 described above (see FIG. 7A). Similarly, when the nose block 52 abuts against the tip of the second guide cylinder 80, the position of the last retracted position of the second slide guide 53b (nose block 52) is regulated. The rod body 87 is in sliding contact with the inner peripheral surface of the retaining portion 84 of the second guide cylinder 80, and the second sliding contact portion 88 is in sliding contact with the inner peripheral surface of the straight hole. As a result, the second guide rod 81 is always in sliding contact with the second guide cylinder 80 at two locations, and smoothly slides while maintaining straight advanceability.

  Each coil spring 90 abuts the guide nut 55 at the rear end and abuts the front end against the first cylinder flange portion 73 or the second rod flange portion 86 to function as a compression spring. That is, each coil spring 90 receives the guide nut 55 (guide holder 51) and urges the nose block 52 forward. The coil spring 90 may be provided only on either the first slide guide 53a or the second slide guide 53b.

  The drilling operation is performed with the operator holding the electric drill 3 by hand, and when the drill bit 2 gradually moves forward with the drilling, the pair of slide guides 53 resists the pair of coil springs 90. At that time, the nose block 52 urged by the pair of coil springs 90 always maintains a state of being abutted against the drilling object C. When the drilling reaches the adjusted drilling depth, the tip of the first guide rod 71 comes into contact with the member 71a and the drilling is restricted (see FIG. 7B). When the drilling operation is completed in this way, the operator removes the force. Then, the spring force of the pair of coil springs 90 acts, and the drill bit 2 is pulled straight out of the hole while being guided by the pair of slide guides 53.

According to the above configuration, since the dust inside the hole that has been drilled can be washed away without taking time and effort, the drilling operation can be performed efficiently.
Further, anyone can easily perform the drilling operation in the direction perpendicular to the drilling surface by the electric drill 3 without depending on experience or intuition.
Further, it is possible to guide the drilling with respect to the drilling object C, and it is possible to perform the drilling operation with the electric drill 3 without the adjusted drilling depth being out of order.

  1: drilling device, 2: drill bit, 3: electric drill, 4: coolant supply attachment, 5: guide attachment, 13: flow path in bit, 20: attachment case, 21: input shaft, 22: output shaft, 23 : Pressurizing channel, 23a: First pressurizing channel, 23b: Second pressurizing channel, 24: Valve mechanism, 24a: O-ring, 24b: Valve seat, 25: Coolant inlet, 36a: First sliding support Part, 36c: second sliding support part, 41: small diameter part, 42: large diameter part, 48: output shaft flow path, 48b: first radial flow path, 48d: second radial flow path, 49 : Pressure receiving portion, 49a: first pressure receiving portion, 49b: second pressure receiving portion, 51: guide holder, 52: nose block, 53: slide guide, 53a: first slide guide, 53b: second slide guide, 57: protrusion Contact guide part 59: Dust seal 61: insertion opening, 64: contact sheet, 70: first guide cylinder, 71: first guide rod, 78: lock nut, 79: scale plate, 80: second guide cylinder, 81: second guide rod, 90 : Coil spring, C: Drilling object, AS: Adjustment screw mechanism, S: Contact surface

Claims (10)

An electric drill guide attachment that is attached to an electric drill equipped with a drill bit and guides drilling of an object to be drilled by the electric drill,
A guide holder attached to the electric drill;
A nose block having an insertion opening through which the drill bit is inserted and abutted against the drilling object;
The guide holder and the nose block are connected, and a slide guide that telescopically extends and retracts,
The slide guide is slidably connected to a guide tube having one end fixed to the nose block and a guide rod screwed to the guide holder at one end.
A guide attachment for an electric drill characterized in that the position of the sliding end on the contraction side of the guide rod is regulated by contact and an adjustment screw mechanism is configured by screwing with the guide holder.   The guide attachment of the electric drill according to claim 1, wherein the position of the sliding end of the guide rod is regulated when the guide rod comes into contact with the nose block.   The guide attachment of the electric drill according to claim 2, wherein one end of the guide rod penetrates the nose block and is exposed when the end of the guide rod comes into contact with the nose block.   The guide attachment of the electric drill according to any one of claims 1 to 3, wherein one end portion of the guide rod constituting the adjustment screw mechanism extends through the guide holder. .   5. The electric drill guide attachment according to claim 4, wherein a scale that indicates a drilling depth with respect to the drilling object is disposed along the extending portion of the guide rod.   The electric drill according to any one of claims 1 to 5, wherein a lock nut that comes into contact with the guide holder is screwed into one end of the guide rod constituting the adjustment screw mechanism. Guide attachment. A second slide guide that connects the guide holder and the nose block and extends and retracts;
The guide attachment of the electric drill according to any one of claims 1 to 6, wherein the slide guide and the second slide guide are disposed at point-symmetrical positions with respect to the drill bit. The second slide guide is
8. A guide cylinder having one end fixed to the guide holder and a guide rod having one end fixed to the nose block are slidably connected to each other. Electric drill guide attachment.   A coil spring provided to wind around at least one of the slide guide and the second slide guide, and receiving the guide holder to urge the nose block in a forward direction; The guide attachment of the electric drill according to claim 7 or 8. A guide attachment of the electric drill according to any one of claims 1 to 9,
A drilling device comprising the electric drill.

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