DE3634593A1 - Hammer drill with an air-cushion percussive mechanism - Google Patents

Abstract

A hammer drill with an air-cushion percussive mechanism, comprising a guiding tube (18) for the piston (22) and the percussive element (21), which guiding tube rotates with the spindle (14) for the tool-holding fixture (5), has a crank drive (26, 27, 28) which drives the piston (22), is secured to the guiding tube (18) and rotates therewith. <IMAGE>

Description

The invention relates to a rotary hammer with a Air cushion hammer mechanism with a spindle for the tool holder rotating guide tube for the piston and the impact body and with a drive in the form of a Crank drive.

In a known hammer drill of this type (US-PS 38 28 863) the crank mechanism in the housing is at a distance behind the rear end of the guide tube for the from a hollow piston existing, the impact body slidably receiving Piston arranged. The one with the eccentric pin of the crank drive connected piston rod extends from the Exzen Terzapfen in the guide tube for swivel connection with the rear end of the piston.

This known rotary hammer does not only result in one relatively large overall length, but beyond the piston is not twisted during operation of the air cushion hammer mechanism held while the guide tube receiving him around its longitudinal axis rotates. This twisting of pistons and Guide tube relative to each other, which is the axial back and forth Movement of the piston superimposed in the guide tube, causes additional frictional forces and thus an additional one Load on the surfaces in contact with each other piston and guide tube.

It is an object of the invention to provide a short hammer drill mer to create, where the piston of the air cushion blow works no relative rotational movement with regard to the rotating guide tube.

To solve this problem, a hammer drill is the beginning mentioned type designed according to the invention such that the Crank mechanism is held on the guide tube and with this turns.

This apprenticeship does not just make it short Structure of the entire hammer drill reached and storage significantly simplified for the crank drive in the hammer drill, but also the crank mechanism rotates and with it also the piston he reciprocated with the Guide tube, so that between these two elements in Operation no relative rotation takes place.

In one embodiment of the hammer drill according to the invention the crank mechanism can not twist on its shaft journal wear a bar-mounted gear that meshes with a gear arranged in the housing of the hammer drill stands.

With this construction, the drive motor runs generated rotation of the guide tube and the resulting thereby gentle rotation of the crank mechanism on the crank pin fen fixed gear on the in the housing of the hammer drill arranged, rotatably held gear and is thereby rotated. This rotation of the crankshaft attached gear leads to the rotation of the crank pin and thus for the movement of the eccentric pin of the crank mechanism bes, whereby the piston reciprocates in the guide tube becomes.  

In order to distinguish between combined drilling and and blow mode and pure drilling mode to switch can, a switching device can be provided in an end position the gear arranged in the housing keeps non-rotatable and so when turning the guide tube and Crank drive drives the piston and the in another end position that arranged in the housing Releases gear so that it is freely rotatable, whereby this gear together with the gear of the crank drive can rotate, so no rotation of the crankshaft le of the crank mechanism and therefore no drive for the piston he follows. Here is the gear arranged in the housing preferably rotatably mounted on the guide tube In one embodiment, the switching device can be a have externally displaceable eccentric pin with one end of a coil spring is connected, the the other end is attached to the housing and with her coiled section an outer cylindrical surface on the body surrounds the gear arranged in the housing.

This coil spring is in an end position of the eccentric terzapfens in blocking engagement with the in the housing arranged gear so that it can not rotate and thereby the crank mechanism drives the piston while the coil spring in the other end position of the eccentric terzapfens the gear arranged in the housing completely releases so that the piston is not driven.

An advantage of this switching device is that in particular, the cranking mechanism gradually starts up occurs when the coiled section of the coil spring gradually engages with that located in the housing Gear is brought so that this gear that is first rotates slowly with the crank drive  is braked. As a result, the crankshaft of the crank runs slowly drove so that the transition from pure Drilling operations for combined drilling and impact operations are not takes place suddenly.

The switching device can, however, also be at least one having a locking projection, from the outside between two Have end positions pivotable engagement element, which consists for example of a spring arm, and in Body of the gear arranged in the housing can min least a locking recess for receiving the locking projection be provided.

By means of such a switching device, the Gear by engagement of the locking projection of the engagement element with the locking recess arranged in the housing Block the gear against rotation so that the gear of the Crank drive runs on this gear and the crank drove the piston back and forth while releasing leads to the locking recess through the engagement element, that the gear arranged in the housing with the Crank drive turns, so it is not driven.

In another embodiment of the drill according to the invention hammers with switching device can the guide tube from a Position in which the bearing on the guide tube Gear rotates with this, can be moved into one position be in which the gear mounted on the guide tube in blocking engagement with a braking surface.  

In this arrangement, it is in engagement with the gear attached to the shaft journal of the crank mechanism standing gear rotatably mounted on the guide tube so that there is no drive when rotating together with the guide tube Causes crank drive while it is in a versus Rotary movement of the guide tube blocked position in the The way described above works, that is, on waves pin the crank drive non-rotatably fastened gear can run so that the crank drive the piston back and forth moved here.

In order to switch between combined drilling and Achieving hammer operation and pure drilling operation can Braking surface a cone lying coaxial to the guide tube axis be in the form of a blunt inner surface which extends in the direction of Shifting movement of the guide tube to the blocking on handle of the gear tapered, and the body of the on the Guide tube-mounted gear can be one according to the Inner surface shaped, frustoconical outer surface for have the blocking engagement with the inner surface.

The invention is based on the schematic and Fig. shows partially simplified embodiments ren explained in more detail.

Fig. 1 shows a side view of a hammer drill.

Fig. 2 shows the hammer drill from Fig. 1 from the front.

Fig. 3 shows the hammer drill from Fig. 1 partly broken up and partly in section.

FIG. 4 schematically shows a section along the line IV-IV from FIG. 3.

FIG. 5 schematically shows a section along the line VV from FIG. 3.

Fig. 6 shows the hammer drill 1 shown in FIGS. To 5, partly in section and partly broken away from above.

FIG. 7 shows the detail from the circle X in FIG. 3 on an enlarged scale .

FIGS. 8 and 9 3 increases the detail in the circle Y in Fig. In two operating conditions.

FIG. 10 shows a different switching device in a representation similar to FIG. 4.

Fig. 11 shows partly as a view and partly broken up and in section another hammer drill.

Fig. 12 shows in an enlarged partial sectional view of FIG. 11, the essential parts of the switching device, the striking mechanism being in the activated state.

FIG. 13 shows the striking mechanism in the non-activated state in a representation corresponding to FIG. 12.

The hammer drill shown has a housing 1 with a handle opening 2 forming a spade handle, into which the pusher 3 of the actuation switch projects. At the front end projects beyond the housing 1 in front of a tool holder 5, a drill can be used 6 in which in a known manner, which is shown only in some of the figures and its support is known in the tool holder 5 and will therefore not be explained in more detail.

An electric motor (not shown ) is mounted in the housing 1 , on the armature shaft 10 ( FIG. 3) of which a fan wheel 11 is fastened in the usual way. The outer end of the armature shaft 10 carries a gear 12 with which an endless toothed belt 13 is engaged, which runs over a gear 20 which is formed on the front portion 19 of a guide tube 18 to be described yet. This guide tube 18 is rotatably and only axially immovably mounted in the housing 1 in a partially shown manner and is non-rotatably coupled to the spindle 14 of the rotary hammer at its front end via a spline 15 . In the spindle 14 , a striker 16 is also axially slidably provided in a known manner, which in the shock transmission comes into engagement with the rear end of the drill 6 located in the tool holder 5 and transmits the strikes to be described, which are described .

In the guide tube 18 , which can be composed of several parts to simplify assembly in a manner not shown, there is an axially displaceable impact body 21 , which is shown in Fig. 3 in the view below the center line of the guide tube 18 in shock-transmitting gender contact with the Döpper 16 stands and is in the position shown above the center line of the guide tube 18 in Fig. 3 in the idle position, in which it is moved for example due to the lack of a drill in the tool holder 5 towards the tool holder 25 .

Behind the striking body 21 there is a piston 22 in the guide tube 18 , which in a known manner builds up excess pressure between the striking body 21 and the striking body 21 during operation of the hammer drill in order to fling the striking body 21 forward against the striker 16 and then the striking body 21 by construction of a negative pressure to move backwards. At idle, the piston 22 performs a back and forth movement in a known manner, but neither an overpressure nor a negative pressure is built up in the region between the piston 22 and the impact body 21 in idle fashion, since this space is then continuously connected with the indicated cross pipes Ambient air is connected. The refilling of air into the space between the piston 22 and the striking body 21 in the striking operation of the rotary hammer and the ventilation of this space when idling is known, for example, from EP-PS 00 14 760 and therefore need not be described.

As shown, the piston 22 has a spherical shape and carries a sealing ring 23 in a circumferential groove, which, as can be seen in FIGS . 3, 6 and 7, bears sealingly against the inner surface of the guide tube 18 in each operating position of the piston 22 . On the piston 22 , a piston rod 24 is rigidly attached, which is pivotally connected to this crank arm 26 via an eccentric pin 27 , which is located in the crank arm 26 of a crank mechanism, the end of the crank rod 25 connected to the eccentric pin 27 between the two parts of the crank arm 26 sits. The two parts of the carrier body 26 receive the two sections of the shaft journal 28 , which do not extend into the area between the two parts of the crank web 26 , but are rotatably held in slide bearings 30 held in the guide tube 18 . Upon rotation of the shaft pin 28 , the crank arm 26 is thus rotated about the central axis of the shaft pin 28 and the eccentric pin 27 performs a circular movement around the shaft pin 28 in a conventional manner, so that the articulated end of the piston rod 24 also moves on a circular path, wherein a section 29 ( FIG. 6) of the crank arm 26 designed as a counterweight lies opposite the eccentric pin 27 .

On the upper end of the upper portion of the shaft journal 28 in FIG. 3, a gear 31 is non-rotatably fastened, which meshes with a gear 34 which is rotatably mounted on the guide tube 18 concentrically to the central axis of the guide tube 18 in a manner not shown.

The rear end of the guide tube 18 carries an axle stub 32 and is mounted with this in a bearing 33 held in the housing 1 of the rotary hammer ( FIG. 3).

A switching device contains a helical spring 36 which surrounds the body of the gear 34 and is between its cylindrical outer surface and a thimble surface 37 formed by the housing 1 , so that an annular gap is formed between these two surfaces, the radial dimension of which is greater than the diameter of the Coil spring 36 wire. One end of the coil spring 36 is fastened to the housing 1 by means of a screw 35 , while the other end is attached to an eccentric pin 4 '( FIG. 4) which is inserted into a switch lever 4 rotatably mounted on the housing 1 .

By rotating the switch lever 4 in the striking position, the eccentric pin 4 'is displaced so that the end of the coil spring 36 attached to it is moved downward in Fig. 4, so that the helical portion of the coil spring 36 surrounding the gear 34 is in clamping engagement comes with the gear 34 ( Fig. 8). When moving the eccentric pin 4 'in the other end position, the coil spring 36 expands, and it lies with its helical section on the boundary surface 37 formed by the housing ( Fig. 9), so it is no longer in engagement with the gear 34th

Assuming that the switching device is in the position shown in FIG. 8, the helical section from the coil spring 36 thus in a blocking grip with the gear 34 , and the drive motor of the rotary hammer is turned on by actuating the pusher element 3 , so the armature shaft 10 rotates and drives the toothed belt 13 via the toothed wheel 12 . This rotation of the toothed belt 13 leads to a rotation of the guide tube 18 and, because of the coupling via the serration 15, also to the rotation of the spindle 14 and thus of the drill 6 inserted into the tool holder 5 . When the guide tube 18 rotates, the shaft journal 28 and thus the entire crank mechanism including piston rod 24 and piston 22 also rotates together with the guide tube 18 . Since the gear 34 is held by the helical spring 36 of the switching device stationary bezüg Lich the guide tube 18 , the non-rotatably bar fixed on the shaft journal 28 gear 31 rolls on rotation of the guide tube 18 on the gear 34 and thus causes a rotation of the shaft journal 28 around it Longitudinal axis. This rotation of the shaft journal 28 leads to the reciprocating movement of the piston 22 described above, the piston executing a tilting movement as a result of the rotational movement of the eccentric journal 27 around the shaft journal 28 , as is indicated in FIG. 6.

In the above the center line of the Führroh res in Fig. 6 shown 18 representation of the Exzenterzap is fen 27 so that the piston rod 24 extends on the central axis of the guide tube 18 in the direction of said axis and the piston 22 of the normals to the plane the sealing ring 23 receiving annular groove lies in the axis of the guide tube 18 . The resulting position is shown enlarged in Fig. 7, and it can be seen that the sealing ring 23 is in sealing contact with the inner surface of the guide tube 18 with its central region. When the eccentric pin displaced 27 due to its orbiting motion about the shaft pin 28 laterally with respect to the longitudinal axis of the guide tube 18, so the rear end of the crank rod 24 is displaced accordingly, and thereby brought into an inclined position, the connecting rod 24 as the maximum lateral deflection in the case of the eccentric 27 in the line shown in Fig. 6 below the center line of the guide tube 18 can be seen. Also in this pivoted position of the piston 22 due to pivoting of the crank rod 24 , the ent speaking edge regions of the sealing ring 23 are in tight engagement with the inner surface of the guide tube 18 , so that an overpressure or underpressure is formed in the latter between the piston 22 and the impact body 21 can be.

The switching device is in a position in which the coil-shaped portion of the coil spring is disengaged from the gear 34 36 (Fig. 9), the rotatably mounted on the supply pipe 18 gear 34 upon rotation of the guide tube 18 due to engagement with the tooth wheel 31 rotated together with the guide tube 18 and the crank mechanism, so that there is no rotational movement of the shaft journal 28 and thus also no reciprocating movement of the piston 22 . In this operating state, therefore, as a result of the drive via the toothed belt 13, there is a pure drilling operation, ie a rotation of the spindle 14 and thus of the drill 6 , while the rotation of the guide tube 18 , which also takes place, does not cause any striking movement.

If the helical portion of the coil spring 36 of the switching device by slow rotation of the switching lever 4 and thus corresponding displacement of the eccentric pin 4 'is gradually brought from the position shown in FIG. 9 into engagement with the outer circumferential surface of the gear 34 , this results initially as a result low friction, a braking movement of the gear 34 , by means of which the gear 31 rotates slowly and thus the impact operation begins slowly. This impact operation is accelerated with increasing engagement of the wendelför shaped portion of the coil spring 36 with the gear 34 more and more until the gear 34 is fully held by the coil spring 36 and the full impact operating state is reached. This slow start of the striking operation is particularly advantageous because it avoids extreme shock loads on the overall mechanism.

Instead of a switching device with a helical spring described above, a switching device can also be used, for example, as is shown schematically in FIG. 10. This switching device has a switching used with hook members into the housing 1 lever 54 which is rotatable and an eccentric pin 54 'carries. A spring element 56 is fastened with one leg in the housing 1 , while the other leg has a latching projection 57 and with its free end on the eccentric pin 54 '.

The rotatably mounted on the guide tube, not shown, gear 44 corresponds to the gear 34 of FIGS . 1 to 9, but has on its circumference distributed Rastvertiefun conditions 45 , the shape of which is adapted to the shape of the locking projection 57 of the spring element 56 .

In the position shown in solid line in Fig. 10, the eccentric pin 54 'holds the spring element 56 in a position in which the locking projection 57 is out of engagement with the locking recesses 45 , so that the gear 44 rotate in the manner described above with the crank mechanism can, so the piston 22 is not moved back and forth.

If the spring element 56 is rotated by rotation of the eccentric pin 54 'due to its inherent elasticity in the position shown in dashed lines, the locking projection 57 comes into engagement with a locking recess 45 and blocks the gear 44 against rotation. In this position, the gear 31 of the crank mechanism runs on the gear 44 , and the piston 22 is reciprocated in the manner described.

Another drill hammer is shown in FIGS. 11 to 13, the same or corresponding parts from the hammer drill according to FIGS. 1 to 9 being designated by reference numerals increased by 100.

The hammer drill according to Fig. 1 to 13 includes an electric motor 90, the armature shaft is supported at one end in a bearing 91 110, while the storage of the other end of the armature shaft 110 is not shown. A fan wheel 111 sits on the armature shaft. A gear 112 is arranged coaxially to the armature shaft 110 and is fixedly connected to the latter. The gearwheel 112 is coupled to the gearwheel 120 via a gearwheel 113 seated on an axis 92 , which gearwheel is formed on the section 119 of the guide tube 118 . In this case, the guide tube 118 and the spindle accommodating the anvil 116 are formed in one piece, that is to say the section 119 of the guide tube 118 carrying the gearwheel 120 continues forward into the spindle. The guide tube 118 is rotatably supported in the housing 1 at the rear end via a pin 132 and a bearing 133 in a manner to be described, while the front part of the mounting of the guide tube 118 is not shown.

In the guide tube 118 , which can be composed of several parts in a manner not shown to simplify the assembly, there is a hollow piston 122 in which the striking element 121 is displaceably arranged. At the rear end of the hollow piston 122 there is a pin 93 on which one end of a piston rod 124 is pivotably attached, the other end of which is connected to a crank mechanism to be described, so that the hollow piston 122 can be moved back and forth in the guide tube 118 and the Impact body 121 strikes on the striker 116 , as described in EP-PS 00 14 760.

According to the crank mechanism from the exemplary embodiment according to FIGS. 1 to 9, the crank mechanism has a two-section shaft journal 128 which is rotatably fastened in bearings 130 in the rear end region of the guide tube 118 . At the inner ends of the sections of the shaft pin 128 , the crank arm 126 is fixed non-rotatably, through which the eccentric pin 127 extends, to which the outer end of the piston rod 124 is articulated.

At the outer end of the upper portion of the shaft pin 128 a gear 131 is fixed non-rotatably, which meshes with a gear 134 .

The gear 134 is rotatably supported on the rear end of the guide tube 118 by means of bearings 99 and has a tapered, frustoconical outer surface 97 which is adjacent to an inner surface 96 of a housing part with the same inclination and formed ( FIG. 13).

As already mentioned, extends into the rear end of the guide tube 118 is a bearing pin 132 which is held in a bearing 133 coaxially with the longitudinal axis of the guide tube 118th A coil spring 98 is supported on the one hand on the guide tube 118 and on the other hand on an annular shoulder of the bearing pin 132 , and the bearing pin 123 is pressed backwards against a bearing ball 95 , which is supported on a cross pin 94 which in a manner not shown by one switch lever accessible from the outside can be rotated about its longitudinal axis.

The guide tube 118 can be displaced axially against the pressure of the spring 98 in a manner not shown due to the pressure exerted when the bore 6 engages the workpiece.

If the cross pin 94 is in the position according to FIG. 12, the bearing ball 95 rests in the relatively large depression formed in the cross pin 94 , which leads to an axial displacement of the bearing pin 132 to the right. When the bore 6 is pressed against the workpiece, the guide tube 118 is therefore shifted to the right into the position according to FIG. 12. In this position, the outer surface 97 of the gear 134 is in locking engagement with the inner surface 96 so that the gear 134 cannot rotate together with the guide tube 118 when it is rotated by the motor 90 via the gears 112 , 113 and 120 . Therefore, the gear 131 then runs on the gear 134 in the manner already described in connection with FIGS. 1 to 9, and the crank mechanism moves the hollow piston 122 back and forth in the guide tube 118 rotating together with the crank mechanism.

If the cross pin 94 is rotated into the position according to FIG. 13, the bearing ball 95 is in engagement with a very flat recess in the cross pin 94 , ie the ball 95 has been moved forward (to the left in FIGS . 11 and 13), whereby the guide tube 118 can only be moved to the position shown in FIG. 13 when the drill 6 is in contact with the workpiece, because the then completely compressed coil spring 98 prevents further displacement to the rear (in FIG. 13 to the right). In this position, the outer surface 97 of the gear 134 is disengaged from the inner surface 96 , so that the gear 134 can rotate together with the crank mechanism when the guide tube 118 rotates, ie the gear 113 of the crank mechanism does not run on the gear 134 , and the crank mechanism is therefore at a standstill, so that the hollow piston 122 is not moved back and forth.

Claims (10)

1. hammer drill with an air cushion hammer mechanism with a rotating with the spindle ( 14 ; 118 ) for the tool holder ( 5 ) guide tube ( 18 ; 118 ) for the piston ( 22 ; 122 ) and the impact body ( 21 ; 121 ) and with a Drive for the piston ( 22 , 122 ) in the form of a crank mechanism ( 26 , 27 , 28 ; 126 , 127 , 128 ), characterized in that the crank mechanism ( 26 , 27 , 28 ; 126 , 127 , 128 ) on the guide tube ( 18th ; 118 ) is supported and rotates with it. 2. Hammer drill according to claim 1, characterized in that the crank mechanism ( 6 , 27 , 28 ) carries on its shaft journal ( 28 ) non-rotatably fixed gear ( 31 ) which meshes with a gear arranged in the housing ( 1 ) of the hammer drill ( 34 ) stands. 3. hammer drill according to claim 2, characterized by a switching device (eg 4, 35, 36 ) which in one position holds the gear ( 34 ) arranged in the housing non-rotatably and which in another position releases the gear ( 34 ) arranged in the housing, so that it can be freely rotated. 4. hammer drill according to claim 3, characterized in that arranged in the housing gear (eg 34 ) is rotatably mounted on the guide tube ( 18 ). 5. Hammer drill according to claim 3 or 4, characterized in that the switching device ( 4 , 35 , 36 ) has an externally displaceable eccentric pin ( 4 ') which is connected to one end of a helical spring ( 36 ), the other end of which Housing ( 1 ) is fixed and which surrounds with its coiled portion an outer cylindrical surface on the body of the gear ( 34 ) arranged in the housing. 6. hammer drill according to claim 3 or 4, characterized in that the switching device ( 54 , 56 , 57 ) has at least one locking projection ( 57 ), by external engagement between two end positions pivotable engagement element ( 56 ) and that in the body of At least one locking recess ( 45 ) for receiving the locking projection ( 57 ) is provided in the gear ( 44 ). 7. Hammer drill according to claim 6, characterized in that the engaging element ( 56 ) consists of a spring arm. 8. hammer drill according to claim 4, characterized in that the guide tube ( 118 ) from a position in which the on the guide tube ( 118 ) mounted gear ( 134 ) rotates with this, in a position in which on the Guide tube ( 118 ) mounted gear ( 134 ) is in blocking engagement with a braking surface ( 96 ). 9. hammer drill according to claim 7, characterized in that the braking surface is a coaxial to the guide tube axis, frustoconical inner surface ( 96 ) which tapers in the direction of the displacement movement of the guide tube ( 118 ) for blocking engagement of the gear ( 134 ), and that the body of the gear ( 134 ) mounted on the guide tube ( 118 ) has an accordingly the inner surface ( 96 ) shaped, truncated cone-shaped outer surface ( 97 ) for blocking A handle with the inner surface ( 96 ). 10. Hammer drill according to claim 7 or 8, characterized in that the guide tube ( 118 ) by the pressure of the drill bit ( 5 ) located drill against a workpiece in the gear ( 134 ) blocking position is movable.