JP7098432B2 - Dust collection system for dust collection bit and hammer drill - Google Patents

Description

The present invention is a dust collecting system for a dust collecting bit used for collecting dust from a dust collecting bit used when drilling with an electric tool, and a hammer using the dust collecting system for the dust collecting bit. Regarding the drill.

When drilling a hole in concrete or stone using an electric tool, a drill bit is attached to an electric drill or the like and the drill bit is rotated to perform drilling work. At this time, in order to prevent the generated dust from scattering, in Patent Document 1, a dust suction path is provided in the bit body, one end of the dust suction path is opened at the tip of the bit body, and the other end is opened at the side surface of the bit body. While using a dust suction bit, the device body is attached to an electric tool by using a dust collector equipped with a suction head that is externally attached to the dust suction bit bit body on the device body that houses the fan and filter, and the tip of the bit body is used. Disclosed is an invention of a dust collector for an electric tool capable of collecting dust sucked from a suction head from a suction head to a device main body.

European Patent Application Publication No. 2946860

In the above-mentioned conventional dust collector for electric tools, the bit body rotates with respect to the suction head provided in the device body and whose rotation is restricted. However, if dust enters between the suction head and the bit body, both of them. The slidability between them deteriorated, and there was a risk that the suction head would be damaged due to the application of a large rotational urging force.

Therefore, the present invention provides a dust collection system for a dust suction bit, which can prevent damage to the suction head and improve durability even if the slidability between the bit body of the dust suction bit and the suction head deteriorates. It is intended to provide a hammer drill.

In order to achieve the above object, the invention according to claim 1 is a dust collecting system for a dust collecting bit, in which a suction head for dust collecting is externally attached to a bit body, and a dust collecting head mounted on an electric tool having a motor is attached. With a bit
A dust collector equipped with an introduction port that is attached to an electric tool to generate suction force and a dust collection unit that stores dust sucked from the introduction port.
Includes a flexible hose, which is connected between the suction head and the inlet ,
The dust collector is equipped with a dust collecting motor and a dust collecting fan for generating suction force, and the dust collecting motor is in front of the motor of the electric tool with the dust collecting device attached to the electric tool. It is characterized by being placed in .
The invention according to claim 2 is characterized in that, in the configuration of claim 1 , the introduction port is provided on the front surface of the dust collector.
According to the third aspect of the present invention, in the configuration of the second aspect, a chuck member for attaching / detaching a dust collecting bit by operating the operating member is provided on the front portion of the power tool, and the front surface of the dust collecting device is electrically driven. It is characterized in that it is located behind the chuck member in the state of being mounted on the tool.
According to a fourth aspect of the present invention, in the configuration according to any one of claims 1 to 3 , the power tool is connected to a housing accommodating an output unit so as to be relatively movablely connected to the housing via an anti-vibration unit. It has a housing and is characterized in that the dust collector is mounted on a vibration-proof housing.
The invention according to claim 5 is the configuration according to any one of claims 1 to 4, wherein the dust collector supplies the exhaust gas generated by the dust collecting fan to the output unit of the electric tool in a state of being attached to the electric tool. It is characterized by having a possible exhaust flow path.
In order to achieve the above object, the invention according to claim 6 is a hammer drill, characterized in that it includes the dust collecting system for a dust collecting bit according to any one of claims 1 to 5 .

According to the inventions of claims 1 and 6 , a dust suction bit which is attached to an electric tool by externally attaching a dust suction head to the bit body, and an introduction port which is attached to the electric tool to generate suction force. By including a dust collector equipped with a dust collector for storing dust sucked from the introduction port and a flexible hose connected between the suction head and the introduction port, the bit body of the dust suction bit and the suction port are included. Even if the slidability between the head and the head deteriorates, it is possible to prevent damage to the suction head and improve durability.
In particular , since the dust collector includes a dust collecting motor and a dust collecting fan for generating a suction force, the dust collector can generate the suction force by itself, and the usability is improved.
According to the second aspect of the present invention, in addition to the effect of the first aspect, since the introduction port is provided on the front surface of the dust collector, the flexible hose can be easily connected and the length of the flexible hose is long. It will also be shorter and less likely to get in the way of your work.
According to the third aspect of the present invention, in addition to the effect of the second aspect, a chuck member for attaching / detaching the dust absorbing bit by operating the operating member is provided on the front portion of the power tool, and the dust collector is provided. Since the front surface is located behind the chuck member when it is attached to the power tool, even if the dust collector is attached, it does not interfere with the operation of attaching / detaching the dust absorbing bit by the operating member.
According to the invention of claim 4 , in addition to the effect of any one of claims 1 to 3 , the power tool is movably connected to the housing accommodating the output unit via the vibration isolator. Since the dust collector is mounted on the vibration-proof housing, a higher vibration-proof effect can be obtained.
According to the invention according to claim 5 , in addition to the effect of any one of claims 1 to 4 , the dust collector uses the exhaust gas generated by the dust collecting fan in a state of being mounted on the electric tool. Since it has an exhaust flow path that can be supplied to the output unit, the dust collecting air can be effectively used for cooling the output unit.

FIG. 3 is a central vertical sectional view of a dust collecting system for a dust collecting bit and a hammer drill according to the first aspect. FIG. 3 is a sectional view taken along line AA of FIG. It is a central vertical sectional view which shows the operating state of the anti-vibration housing in the hammer drill of Embodiment 1. FIG. FIG. 3 is a central vertical sectional view of a dust collecting system for a dust collecting bit and a hammer drill of the second aspect. (A) is a sectional view taken along line BB of FIG. 4, and (B) is a sectional view taken along line CC.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Form 1]
FIG. 1 is a central vertical sectional view showing an example in which a dust collecting device 40 and a dust collecting bit 70 are attached to a hammer drill 1 to form a dust collecting system S for a dust collecting bit.
First, the hammer drill 1 is coupled to the inner housing 2 that houses the output unit 3, the motor housing 4 that is coupled below the inner housing 2 and houses the motor 5 with the output shaft 6 facing upward, and the outside of the inner housing 2. It has an outer housing 7 that covers the outer housing 7, and a handle housing 8 that is provided from the rear of the outer housing 7 to the lower part of the motor housing 4.
The handle housing 8 includes a switch 10 and a switch lever 11, a handle portion 9 extending in the vertical direction behind the outer housing 7, and two front and rear battery packs that wrap around to the lower side of the motor housing 4 and serve as a power source at the lower part. It is provided with a battery mounting portion 12 for mounting 13 and 13. A controller 14 having a control circuit board is housed in the battery mounting portion 12 on the upper side of the battery pack 13 in the front-rear direction.

Here, the outer housing 7 is provided so as to be relatively movable back and forth with respect to the inner housing 2 and the motor housing 4, and the upper end of the handle portion 9 of the handle housing 8 is coupled to the upper rear surface of the outer housing 7 to form a battery. The mounting portion 12 is engaged with the lower portion of the motor housing 4 so as to be relatively movable back and forth.
Anti-vibration portions 15A and 15B are provided between the inner housing 2 and the outer housing 7 and between the motor housing 4 and the handle housing 8. The anti-vibration portion 15A straddles the front and rear bosses 16 and 16 and both bosses 16 and 16 provided so as to face each other between the rear surface of the inner housing 2 and the rear inner surface of the outer housing 7 in the outer housing 7. It is formed from a coil spring 17A to be exteriorized. The anti-vibration portion 15B is erected in the battery mounting portion 12 of the handle housing 8, a protruding piece 18 protruding downward into the battery mounting portion 12 on the lower surface of the motor housing 4, and behind the projecting piece 18 in the battery mounting portion 12. It is formed from a coil spring 17B provided in the front-rear direction between the receiving rib 19 and the housing rib 19.

Therefore, the outer housing 7 and the handle housing 8 are normally elastically attached to the retracted position of FIG. 1 in which the upper end of the front portion of the battery mounting portion 12 abuts on the base end of the protruding piece 18 due to the urging of the coil springs 17A and 17B. It is a vibration-proof housing that can move back and forth relative to the inner housing 2 and the motor housing 4 against the urgency of the coil springs 17A and 17B.
As shown in FIG. 2, vertical guide grooves 20 and 20 are recessed on the left and right side surfaces of the front portion of the battery mounting portion 12, respectively. A recessed portion 21 having a locking hole 22 formed on the upper surface thereof is formed.

On the other hand, the output unit 3 has a cylindrical tool holder 23 that is held by the cylindrical barrel portion 2a on the front side of the inner housing 2 and extends in the front-rear direction. Below the tool holder 23, the output shaft 6 of the motor 5 projects into the inner housing 2, and the intermediate shaft 24 is supported on the front side of the output shaft 6 and the crank shaft 25 is supported on the rear side in the vertical direction. Gears 26, 26 provided on each shaft mesh with a pinion provided on the upper end of the output shaft 6. The bevel gear provided at the upper end of the intermediate shaft 24 meshes with the bevel gear 27 rotatably mounted on the tool holder 23. The bevel gear 27 transmits the rotation of the intermediate shaft 24 to the tool holder 23 by retracting and engaging the switching sleeve 28 splined to the outer periphery of the tool holder 23, and the front-rear position of the switching sleeve 28. Can be switched by the switching knob 29 provided on the upper surface of the outer housing 7.

Further, in the rear part of the tool holder 23, the cylinder 30 is held and the piston 31 is accommodated so as to be movable back and forth, and the piston 31 and the eccentric pin 32 provided on the crank shaft 25 behind the piston 31 are connected via the connecting rod 33. It is connected. A striker 35 is housed in the cylinder 30 in front of the piston 31 so as to be movable back and forth via an air chamber 34, and an impact bolt 36 with which the inserted bit abuts is housed in the tool holder 23 in front of the striker 35. It is provided. An operation sleeve 37 as an operation member for attaching / detaching the bit is provided at the front end of the tool holder 23. Inside the front end of the operation sleeve 37, chuck members 37a and 37a that engage with the retaining recess 74 provided in the bit via the tool holder 23 are provided, and the operation sleeve 37 can be slid back and forth. As a result, the movement of the chuck member 37a in the radial direction is locked / unlocked so that the bit can be attached and detached.
In this hammer drill 1, when the output shaft 6 rotates, the crank shaft 25 constantly rotates to move the piston 31 back and forth, so that the interlocking striker 35 hits the impact bolt 36. Therefore, when the switching sleeve 28 is switched to the retracted position by operating the switching knob 29, the tool holder 23 is rotated via the bevel gear 27, and the hammer drill mode is set. When the switching sleeve 28 is switched to the forward position, the tool holder 23 is rotated. It becomes a hammer mode that only hits without hitting.

The dust collector 40 has a box-shaped casing 41, and the casing 41 is mounted on the battery mounting portion 12 on the front side of the motor housing 4 and the handle housing 8 of the hammer drill 1. A dust box 43 as a dust collecting portion is detachably attached to a connecting portion 42 provided on the lower side of the casing 41.
A rear wall portion 44 extending downward along the front surface of the battery mounting portion 12 is formed in the rear portion of the casing 41, and a recessed portion 21 of the battery mounting portion 12 is formed in the center in the left-right direction at the lower end of the rear wall portion 44. A convex portion 45 that fits into the protrusion 45 is projected backward. A hook plate 46 having a forward-facing hook 47 projecting from the upper end thereof is supported on the rear surface of the convex portion 45 so as to be swingable back and forth by a pin 48 in the left-right direction. A coil spring 49 for pressing the lower end of the hook plate 46 backward is provided in the convex portion 45, and the hook plate 46 is urged to a front swing position where the upper end abuts on the back surface of the convex portion 45. ..

Further, as shown in FIG. 2, the pair of side plates 50, 50 provided on the left and right sides of the rear wall portion 44 project rearward from the rear wall portion 44 and cover both side surfaces of the battery mounting portion 12. At the rear end of each side plate 50, engaging pieces 51, 51 that engage with the guide grooves 20, 20 provided on the left and right sides of the battery mounting portion 12 are formed.
Here, when the engaging pieces 51 and 51 are aligned with the guide grooves 20 and 20 and the casing 41 is slid from below, the convex portion 45 is fitted into the recessed portion 21 from below and the hook 47 of the hook plate 46 is a locking hole. It can be locked to 22.

Further, a dust collecting motor 52 is housed in the casing 41 with the output shaft 53 facing forward, and a dust collecting fan 54 is provided at the front end of the output shaft 53. A fan accommodating chamber 55 for accommodating the dust collecting fan 54 is formed in the casing 41, and device-side exhaust ports 56, 56 ... Communicating with the fan accommodating chamber 55 are formed on the side surface of the casing 41. ing.
The lower plate 57 of the casing 41 is formed with a communication port 58 communicating with the suction side of the fan accommodating chamber 55, and the upper plate 59 has a tubular exhaust flow path 60 communicating with the outlet side of the fan accommodating chamber 55. It is formed so as to project upward.
An exhaust introduction port 7a into which the exhaust flow path 60 is inserted is formed below the barrel portion 2a in the outer housing 7 of the hammer drill 1 with the dust collector 40 attached, and the outer housing 7 is formed in front of the exhaust introduction port 7a. An exhaust port 7b on the machine side is formed on the lower surface of the machine so that the air blown from the exhaust flow path 60 can pass through the tubular flow path 38 between the barrel portion 2a and the outer housing 7.

Further, a light 61 using an LED is provided at the upper front end in the casing 41 so that the front of the bit mounted on the tool holder 23 can be irradiated while the light 61 is mounted on the hammer drill 1.
A terminal (not shown) that is electrically connected to each other in the mounted state of the casing 41 is provided between the rear wall portion 44 of the casing 41 and the battery mounting portion 12 of the handle housing 8, and the terminals are electrically connected to each other. By connection, the power supply of the dust collecting motor 52 and the light 61 can be obtained from the battery pack 13 via the controller 14. Here, the dust collecting motor 52 is driven by the ON operation of the switch 10, and the light 61 is turned on.

The dust box 43 is a box-shaped body attached to the joint portion 42 from the front, and the locking shaft 62 provided at the lower end of the rear portion is engaged with the receiving recess 63 provided at the lower end of the front surface of the rear wall portion 44 to engage the inner surface of the upper end. By engaging the locking portion (not shown) provided on the lower surface of the casing 41, the locking portion is detachably attached to the coupling portion 42. Inside the dust box 43, a filter accommodating portion 64 located below the communication port 58 in the mounted state is provided, and the filter accommodating portion 64 is provided with a paper filter 65 folded in the left-right direction with the front-back direction as a crease. The communication port 58 and the inside of the dust box 43 are separated from each other. A cylindrical introduction port 66 is projected forward on the upper front surface of the dust box 43.
In this way, the air sucked from the introduction port 66 enters the dust box 43 in the dust collector 40, passes through the filter 65, and forms a dust collection path R from the communication port 58 to the fan accommodating chamber 55.

The dust suction bit 70 mounted on the hammer drill 1 includes a metal bit body 71 having a cutting edge at the front end, and a resin hose attachment portion 72 as a suction head mounted on the bit body 71. Become. At the rear end of the shank portion 73 formed at the rear end of the bit body 71, a pair of retaining recesses 74 and 74 for inserting and mounting the tool holder 23 of the hammer drill 1 and a pair of detents having different phases are provided. The grooves 75 and 75 are formed in the axial direction, respectively.
A dust suction path 76 is formed at the axis of the bit body 71. The front end of the dust suction path 76 is bifurcated to open a pair of suction ports 77, 77 on the front end surface of the bit body 71. The rear end of the dust suction path 76 is bent in the radial direction at the mounting position of the hose mounting portion 72 to open the outlet 78 on the peripheral surface of the bit main body 71.

The hose attachment portion 72 is a tubular portion 79 that is rotatably exteriord to the bit body 71, and a tubular portion that is connected to the exterior portion 79 and protrudes outward in the radial direction of the bit body 71, and the tip opens. It consists of 80. The exterior portion 79 communicates with the tubular portion 80 to open the outlet 78 into the tubular portion 80.
A flexible hose 81 is inserted and connected between the tubular portion 80 and the introduction port 66 of the dust collector 40 so that the suction force at the introduction port 66 can be generated by the tubular portion 80. The flexible hose 81 has a dimension longer than the linear distance between the tubular portion 80 and the introduction port 66, and has a slight deflection downward.

In the dust collecting system S for dust collecting bits configured as described above, when the dust collecting device 40 is mounted on the hammer drill 1, the side plate is in a state where the casing 41 is located in front of the battery mounting portion 12 of the hammer drill 1. Slide one of the engaging pieces 51, 51 of 50, 50 in the vertical direction so as to engage the guide grooves 20, 20 of the battery mounting portion 12 from below. Then, the battery mounting portion 12 is fitted and connected between the side plates 50 and 50, and the hook 47 of the hook plate 46 is locked in the locking hole 22 to complete the mounting. At this time, the exhaust flow path 60 of the casing 41 is inserted into the exhaust introduction port 7a of the outer housing 7 to allow the fan accommodating chamber 55 to communicate with the tubular flow path 38. Further, in the mounted state, the front surface of the casing 41 is located behind the chuck member 37a provided inside the operation sleeve 37.

Then, when the switch lever 11 of the hammer drill 1 is pushed in with the tip of the bit body 71 of the dust absorbing bit 70 attached to the tool holder 23 pressed against the surface to be machined, the switch 10 is turned on. The motor 5 is driven to rotate the output shaft 6, and the intermediate shaft 24 and the crank shaft 25 are rotated. Here, as described above, since the piston 31 always reciprocates regardless of whether the hammer drill mode or the hammer mode is selected, the bit body 71 is hit by the interlocking striker 35 via the impact bolt 36.

Further, the dust collecting motor 52 in the casing 41 is also driven by the power supply from the controller 14 to rotate the dust collecting fan 54, so that the dust collecting path R becomes a negative pressure and a suction force is generated in the flexible hose 81. do. Therefore, in the dust suction bit 70, the outside air is sucked from the suction port 77 through the hose attachment portion 72 and the dust suction path 76. The sucked outside air passes through the dust suction path 76 and the hose attachment portion 72, and enters the dust box 43 from the introduction port 66 via the flexible hose 81. Then, it passes through the filter 65 and reaches the fan accommodating chamber 55 from the communication port 58, and a part of the communication port 56 is discharged to the outside from the device side exhaust port 56. Therefore, the dust generated from the work material is sucked into the suction port 77, enters the dust box 43 through the hose attachment portion 72 and the flexible hose 81, is captured by the filter 65, and is stored in the dust box 43.

On the other hand, the other portion of the outside air that has entered the fan accommodating chamber 55 reaches the tubular flow path 38 from the exhaust flow path 60 through the exhaust introduction port 7a of the outer housing 7, and is between the barrel portion 2a and the outer housing 7. Is discharged from the exhaust port 7b on the machine side. The barrel portion 2a is cooled by this air flow.
Further, a motor cooling fan 82 is provided on the output shaft 6 of the motor 5, an intake port 83 is provided on the left and right outer side surfaces of the controller 14 in the battery mounting portion 12, and a battery is provided on the bottom surface of the motor housing 4. Each of the openings 84 communicating with the inside of the mounting portion 12 is formed. Therefore, the rotation of the motor cooling fan 82 accompanying the rotation of the output shaft 6 sucks outside air from the intake port 83 to cool the controller 14, and then enters the motor housing 4 through the opening 84 to cool the motor 5. It is discharged from an exhaust port (not shown) provided in the outer housing 7. A part of this cooling air joins the tubular flow path 38 to cool the barrel portion 2a, and then is discharged from the machine-side exhaust port 7b.

Then, as the bit body 71 rotates, the frictional force generated between the hose mounting portion 72 and the exterior portion 79 exerts a rotational urging force on the hose mounting portion 72 in the rotational direction of the bit main body 71. Since the flexible hose 81 is connected between the shape portion 80 and the introduction port 66, the rotation of the hose attachment portion 72 is suppressed. Even if dust or the like enters the sliding portion of the exterior portion 79 and the slidability deteriorates, the flexible hose 81 can obtain the effect of suppressing rotation.
Further, the inner housing 2 and the motor housing 4 move back and forth due to the vibration generated during the drilling operation. However, since the outer housing 7 and the handle housing 8 are relatively moved back and forth by the vibration-proof portions 15A and 15B as shown by the two-dot chain line in FIG. 3, the vibration transmitted to the operator's hand is suppressed. Be done. At this time, since the dust collector 40 is also mounted on the battery mounting portion 12 of the handle housing 8 to be vibration-proof, the total weight of the handle housing 8 becomes large and vibration is less likely to occur.

On the other hand, the dust collector 40 is removed by pushing the lower end of the hook plate 46 forward to release the lock of the hook 47 to the locking hole 22, and then conversely with the mounting, the hammer drill 1 and the dust collector 40 are removed. When any one of the above is slid in the direction away from the other, the engaging pieces 51 and 51 of the side plates 50 and 50 are disengaged from the guide grooves 20 and 20 of the battery mounting portion 12, and the removal is completed.
Further, when disposing of the dust stored in the dust box 43, the upper part of the dust box 43 may be pulled forward to release the locking with the casing 41, and the dust may be tilted forward around the locking shaft 62 as it is. , The dust box 43 can be removed from the coupling portion 42, and the dust stored inside can be discarded.

As described above, according to the dust collecting system S for the dust collecting bit and the hammer drill 1 of the first embodiment, the dust sucking head (hose mounting portion 72) for sucking dust is externally attached to the bit main body 71, and the dust sucking head is attached to the hammer drill 1. A dust collector 40 equipped with a bit 70, an introduction port 66 attached to a hammer drill 1 to generate suction force, and a dust collecting unit (dust box 43) for storing dust sucked from the introduction port 66, and a hose attachment. By including the flexible hose 81 connected between the portion 72 and the introduction port 66, even if the slidability between the bit main body 71 and the hose mounting portion 72 deteriorates, the hose mounting portion 72 It is possible to prevent damage and improve durability.

In particular, here, since the dust collector 40 includes a dust collecting motor 52 and a dust collecting fan 54 for generating suction power, the dust collecting device 40 alone can generate suction power, which is convenient. Is improved.
Further, since the introduction port 66 is provided on the front surface of the dust collector 40, the flexible hose 81 can be easily connected, and the length of the flexible hose 81 is shortened so that it does not interfere with the work.
Further, since the front surface of the dust collector 40 is located behind the chuck member 37a in the state of being attached to the hammer drill 1, even if the dust collector 40 is attached, the dust suction bit 70 can be attached / detached by the operation sleeve 37. Does not get in the way.

On the other hand, the hammer drill 1 has a housing (inner housing 2) for accommodating the output unit 3 and a vibration-proof housing (outer housing 7 and handle) connected to the inner housing 2 via vibration-proof portions 15A and 15B so as to be relatively movable. Since the dust collector 40 has a housing 8) and is mounted on the handle housing 8 on the vibration-proof side, a higher vibration-proof effect can be obtained.
Further, the dust collector 40 has an exhaust flow path 60 capable of supplying the exhaust generated by the dust collection fan 54 to the output unit 3 of the hammer drill 1 in a state of being mounted on the hammer drill 1, for dust collection. The air can be effectively used for cooling the output unit 3, which leads to a longer life of the hammer drill 1.

In Form 1, the introduction port of the dust collector is not limited to the front surface of the dust box, but may be provided on the front surface of the casing. Further, it can be provided on the side surface or the upper surface instead of the front surface of the dust collector.
Further, the dust collecting motor and the fan are not limited to the above-mentioned arrangement, and may be provided under the casing or changed in direction. The power source is not limited to the case where it is obtained from a hammer drill, and a battery may be mounted on the casing.
As for the mounting structure to the hammer drill, the casing may be slid and mounted in the front-rear direction instead of the vertical direction, or may be mounted on the lower part of the hammer drill.

Next, another embodiment of the present invention will be described. However, the same components as those in the first embodiment are designated by the same reference numerals, and duplicate description will be omitted.
[Form 2]
In FIG. 4, in the hammer drill 1A, a motor housing 4 for accommodating a motor 5 is arranged behind a front housing 90 accommodating an output unit 3 with the output shaft 6 facing forward, and the front housing 90 and the motor housing 4 are arranged. An intermediate housing 91 is interposed between the and. A handle housing 8 having a switch 10 (omitted in FIG. 4) and a switch lever 11 is connected downward to the rear end of the motor housing 4, and a power cord 92 is connected to the lower end of the handle housing 8.

An extension shaft 93 that penetrates the intermediate housing 91 and projects into the front housing 90 is coaxially coupled to the front end of the output shaft 6. A motor cooling fan 82 located in the motor housing 4 is integrally coupled to the output shaft 6, and a dust collecting fan 94 located in the intermediate housing 91 is integrally coupled to the extension shaft 93. An intake port (not shown) for sucking cooling air of the motor 5 is formed on the rear side surface of the motor housing 4, and an exhaust port 95 is formed on the lower surface of the motor housing 4. A connection port 96 connected to a suction path described later of the dust collector 40A is formed on the lower surface of the intermediate housing 91, and a baffle plate that covers the outer peripheral side of the dust collection fan 94 from the rear on the front side of the connection port 96. 97 is provided.
Therefore, in the intermediate housing 91, an intake chamber 98 is formed in which the outside air is sucked from the connection port 96 by the rotation of the dust collecting fan 94 and discharged from the exhaust port (not shown) provided on the side surface of the intermediate housing 91.

In the output unit 3, an intermediate shaft 100 whose torque is transmitted in the front-rear direction via a gear 99 that meshes with a pinion provided at the front end of the extension shaft 93 is supported in the front housing 90 in the front-rear direction, and is forward to the intermediate shaft 100. First gear 101, clutches 102, 102, and boss sleeve 103 are provided. A tool holder 23 is pivotally supported above the intermediate shaft 100 in parallel with the intermediate shaft 100, and a piston cylinder 104 is loosely inserted behind the intermediate shaft 100. An arm 106 is attached to the boss sleeve 103 via a swash bearing 105 whose axis is tilted, and the upper end of the arm 106 is connected to the rear end of the piston cylinder 104. Inside the piston cylinder 104, a striker 35 is accommodated so as to be movable back and forth via an air chamber 34, and an impact bolt 36 provided in front of the striker 35 can be hit. The first gear 101 meshes with the second gear 107 mounted on the tool holder 23.
On the other hand, as shown in FIG. 5A, a pair of guide grooves 108, 108 are formed in the front-rear direction on both the left and right sides of the lower portion of the front housing 90, and are located behind the guide grooves 108, 108 in the center in the left-right direction. The locking recess 109 is formed by two protrusions having an inclined surface on the front and rear surfaces.

The dust collector 40A here has a box-shaped casing 41 in which the left and right half-split casings are assembled and extends in the front-rear direction, and the dust box 43 is detachably attached to a joint portion 42 provided under the casing 41. Has been done. A pair of left and right guide rails 110, 110 that can be engaged with the guide grooves 108, 108 of the hammer drill 1A from the rear outside are formed on the upper plate 59 of the casing 41. Behind the guide rails 110 and 110, as shown in FIG. 5B, a hook 111 whose base end is rotatably connected in the casing 41 and whose tip is engaged with the locking recess 109 is a coil spring 112. It is urged and provided at a position protruding from the upper surface of the upper plate 59. The left side surface of the casing 41 is provided with an operation button 113 that is slidable in the left-right direction and is urged to a position protruding toward the left side surface by the coil spring 114, and the right end portion is inclined to the left side surface of the hook 111. The surfaces are in contact with each other. Therefore, when the operation button 113 is pushed against the urging of the coil spring 114, the hook 111 can be rotated downward against the urging of the coil spring 112 and the tip can be retracted from the upper surface of the upper plate 59.

The introduction port 66 is projected forward at the upper part of the front surface of the casing 41, and an L-shaped cylinder elbow 115 is connected between the introduction port 66 and the lower plate 57 of the casing 41 in the casing 41. The lower end of the elbow 115 projects into the casing 42.
Further, behind the elbow 115, inside the casing 41, there is a lower cylinder 116 whose lower end protrudes into the joint portion 42 through the lower plate 57 and an upper cylinder 117 whose upper end protrudes through the upper plate 59. Are coupled so that they are coaxial with each other. Further, the lower cylinder 116 and the upper cylinder 117 are connected by a flexible connecting duct 118, and the suction path 119 penetrating the casing 41 in the vertical direction by the lower cylinder 116 and the upper cylinder 117 and the connecting duct 118. Is forming.

A front wall portion 120 forming the front side of the joint portion 42 is projected downward from the front portion of the casing 41, and the lower end portion of the front wall portion 120 can be locked to an operation piece 128 described later of the dust box 43. The locking protrusion 121 is projected rearward.
Further, a rear plate 122 that protrudes downward from the rear end of the lower plate 57 and is shorter than the front wall portion 120 is formed in the rear portion of the casing 41, and a receiving shaft 123 in the left-right direction is formed on the lower front side of the rear plate 122. Is formed.

The dust box 43 includes a deep-bottomed box-shaped box body 124 having an open upper surface, and a vertically long square-shaped lid 126 rotatably connected by a hinge shaft 125 on the opening side and the rear side of the box body 124. It becomes. On the rear surface of the box body 124, below the hinge shaft 125, a groove 127 into which the receiving shaft 123 of the rear plate 122 can be fitted is recessed in the left-right direction, and on the front surface of the box body 124, in front of the casing 41. An operation piece 128 that is elastically locked is connected to the locking protrusion 121 of the wall portion 120.
Is formed.
A lid locking piece 129 that engages with the front surface of the box body 124 to maintain the closed state is provided at the front end of the lid 126 in a closed state of the opening of the box body 124, and is coupled behind the lid locking piece 129. A cylindrical inlet 130 into which the lower end of the elbow 115 is inserted in a state of being coupled to the portion 42 is provided. On the other hand, an outlet 131 that communicates with the lower cylinder 116 is formed at the rear side of the lid 126 in a state of being coupled to the coupling portion 42, and a filter 65 is attached to the lower surface of the lid 126 so as to cover the outlet 131 from below. A filter accommodating portion 64 for holding is attached.

When the dust box 43 formed in this way is attached to the joint portion 42, the lid locking piece 129 is locked to the box body 124 to close the lid 126, and the lid locking piece 129 is in front of the lid 126. The groove 127 is fitted to the receiving shaft 123 of the coupling portion 42 from the lower front side with the groove facing up. When the dust box 43 is pushed upward into the coupling portion 42 from this oblique posture, the operation piece 128 is locked to the locking protrusion 121 and attached to the coupling portion 42. In this mounted state, the inlet 130 is fitted to the lower end of the elbow 115 to connect the two, and the outlet 131 abuts on the lower end of the lower cylinder 116 and communicates with the suction path 119. In this way, a dust collecting path R is formed in the dust collecting device 40A from the introduction port 66 through the elbow 115 to the dust box 43, passing through the filter 65 and reaching the suction path 119.

In the dust collecting system S for dust collecting bits configured as described above, when the dust collecting device 40A is attached to the hammer drill 1A, the guide rails 110 and 110 of the casing 41 are in front of the guide grooves 108 and 108 of the hammer drill 1A. Is positioned, one of the guide grooves 108 and 108 is slid in the front-rear direction so as to fit between the guide rails 110 and 110. Then, the guide rails 110 and 110 are fitted and coupled to the guide grooves 108 and 108, and the tip of the hook 111 is locked in the locking recess 109 to complete the mounting. At this time, the upper cylinder 117 of the casing 41 is in close contact with the connection port 96 of the intermediate housing 91, and the suction path 119 is communicated with the intake chamber 98. Further, in this mounted state, the front surface of the casing 41 is located behind the chuck member 37a provided inside the operation sleeve 37.

Then, with the tip of the bit body 71 of the dust absorbing bit 70 attached to the tool holder 23 pressed against the surface to be machined, the switch lever 11 of the hammer drill 1A is pushed in to turn on the switch 10. The motor 5 is driven to rotate the output shaft 6 and rotate the intermediate shaft 100. At this time, by operating the switching knob 29 (omitted in FIG. 4) provided on the side surface of the front housing 90, the clutches 102 and 102 are slid, and only the switching position, the boss sleeve 103, which engages only with the first gear 101. By selecting either the switching position that engages with the first gear 101 or the switching position that engages at the same time as the first gear 101 and the boss sleeve 103, the tool holder 23 rotates via the second gear 107 and the bit body 71 rotates. Drill mode to reciprocate the piston cylinder 104 by swinging the arm 106, and hammer mode to hit the bit body 71 through the impact bolt 36 by the interlocking striker 35, rotation of the tool holder 23 and hitting of the impact bolt 36. It is possible to select the hammer drill mode in which the above is performed at the same time.

Further, since the dust collecting fan 94 rotates together with the motor cooling fan 82 due to the rotation of the output shaft 6, the dust collecting path R communicating with the intake chamber 98 becomes a negative pressure and suction force is generated in the flexible hose 81. .. Therefore, the outside air is sucked from the suction port 77 through the hose attachment portion 72 and the dust suction path 76. The sucked outside air passes through the dust suction path 76 and the hose attachment portion 72, enters the casing 41 from the introduction port 66 via the flexible hose 81, and enters the dust box 43 from the inlet 130 through the elbow 115. After that, it passes through the filter 65, reaches the intake chamber 98 from the outlet 131 via the suction passage 119, and is discharged to the outside from the exhaust port. Therefore, the dust generated from the work material is sucked into the suction port 77, enters the dust box 43 through the hose attachment portion 72, the flexible hose 81, and the elbow 115, and is captured by the filter 65 when passing through the filter 65. It is stored in the box body 124.

Then, as the bit body 71 rotates, the frictional force generated between the hose mounting portion 72 and the exterior portion 79 exerts a rotational urging force on the hose mounting portion 72 in the rotational direction of the bit main body 71. Since the flexible hose 81 is connected between the shape portion 80 and the introduction port 66, the rotation of the hose attachment portion 72 is suppressed. Even if dust or the like enters the sliding portion of the exterior portion 79 and the slidability deteriorates, the flexible hose 81 can obtain the effect of suppressing rotation.

On the other hand, when removing the dust collector 40A, either the hammer drill 1A or the dust collector 40A is removed in the state where the operation button 113 is pushed to release the hook 111 from the locking recess 109 and the hook 111 is released. When one is slid in the direction away from the other, the guide rails 110 and 110 are disengaged from the guide grooves 108 and 108, and the removal is completed.
Further, when disposing of the dust stored in the dust box 43, the operation piece 128 is pushed to the rear side to release the lock with the locking protrusion 121, and the front side is pulled downward with the receiving shaft 123 as the center. Then, the dust box 43 can be removed from the joint portion 42.
Next, if the lid locking piece 129 of the lid 126 is removed from the box body 124 and the lid 126 is opened, dust can be discarded from the opening of the box body 124.

As described above, also in the dust collecting system S for dust collecting bit and the hammer drill 1A of the second embodiment, the dust sucking bit is mounted on the hammer drill 1A by externally mounting the suction head (hose mounting portion 72) for dust collecting on the bit main body 71. A dust collector 40A equipped with a 70, an introduction port 66 mounted on a hammer drill 1A to generate suction force, and a dust collector (dust box 43) for storing dust sucked from the introduction port 66, and a hose attachment portion. By including the flexible hose 81 connected between the 72 and the introduction port 66, the hose mounting portion 72 is damaged even if the slidability between the bit main body 71 and the hose mounting portion 72 deteriorates. Can be prevented and durability can be improved.

In particular, here, the dust collecting device 40A has a suction path 119 that communicates with the intake chamber 98 provided in the hammer drill 1A in a state of being attached to the hammer drill 1A, and the suction force is obtained from the hammer drill 1A. Therefore, the configuration of the dust collecting device 40A is simplified and the cost increase can be suppressed. It also leads to weight reduction of the system.
Further, since the introduction port 66 is provided on the front surface of the dust collector 40A, the flexible hose 81 can be easily connected, and the length of the flexible hose 81 is shortened so that it does not interfere with the work.
Further, since the front surface of the dust collector 40A is located behind the chuck member 37a in the state of being attached to the hammer drill 1A, even if the dust collector 40A is attached, the dust suction bit 70 can be attached / detached by the operation sleeve 37. Does not get in the way.

Also in the second form, the introduction port of the dust collector is not limited to the upper side of the front surface of the casing, but may be provided on the lower side of the front surface of the casing. Further, it may be provided on the side surface or the upper surface instead of the front surface of the casing. The mounting structure for the hammer drill can be changed as appropriate.
Further, in common with each form, the present invention can be applied to the structure of the dust absorbing bit even if the bit body is short or the position and shape of the hose mounting portion are different.

1,1A ... Hammer drill, 2 ... Inner housing, 2a ... Barrel part, 3 ... Output part, 4 ... Motor housing, 5 ... Motor, 6 ... Output shaft, 7 ... Outer housing, 7a・ ・ Exhaust inlet, 7b ・ ・ Exhaust port on the machine side, 8 ・ ・ Handle housing, 12 ・ ・ Battery mounting part, 14 ・ ・ Controller, 15A, 15B ・ ・ Anti-vibration part, 23 ・ ・ Tool holder, 35 ・・ Striker, 36 ・ ・ Impact bolt, 37 ・ ・ Operation sleeve, 37a ・ ・ Chuck member, 40, 40A ・ ・ Dust collector, 41 ・ ・ Casing, 42 ・ ・ Joint part, 43 ・ ・ Dust box, 52 ・ ・ Collection Dust motor, 54, 94 ... Dust collection fan, 60 ... Exhaust flow path, 65 · Filter, 66 ... Introduction port, 70 ... Dust suction bit, 71 · Bit body, 72 · Hose mounting part, 76 ·・ Dust suction path, 77 ・ ・ Suction port, 80 ・ ・ Cylindrical part, 81 ・ ・ Flexible hose, 90 ・ ・ Front housing, R ・ ・ Dust collection path, S ・ ・ Dust collection system for dust collection bit.

Claims (6)

A dust suction bit that is attached to a power tool having a motor by attaching a dust suction head to the bit body,
A dust collector equipped with an introduction port attached to the electric tool to generate suction force and a dust collecting unit for storing dust sucked from the introduction port.
A flexible hose connected between the suction head and the introduction port,
Containing ,
The dust collector includes a dust collection motor and a dust collection fan for generating suction force, and the dust collection motor is the electric motor with the dust collector attached to the electric tool. A dust collecting system for a dust collecting bit, characterized in that it is arranged in front of the motor of the tool . The dust collecting system for a dust collecting bit according to claim 1 , wherein the introduction port is provided on the front surface of the dust collecting device. A chuck member for attaching / detaching the dust collecting bit by operating the operation member is provided on the front portion of the power tool, and the front surface of the dust collector is rearward of the chuck member in a state of being attached to the power tool. The dust collecting system for a dust collecting bit according to claim 2 , wherein the dust collecting system is located in. The power tool has a housing for accommodating an output unit and a vibration-proof housing that is relatively movablely connected to the housing via a vibration-proof portion, and the dust collector is mounted on the vibration-proof housing. The dust collecting system for a dust collecting bit according to any one of claims 1 to 3 , wherein the dust collecting system is characterized by the above. The dust collecting device is characterized by having an exhaust flow path capable of supplying the exhaust generated by the dust collecting fan to the output unit of the electric tool in a state of being mounted on the electric tool. The dust collection system for the dust suction bit described in any of the above. A hammer drill comprising the dust collecting system for a dust collecting bit according to any one of claims 1 to 5 .

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