EP0816516A1 - Tap hole drilling machine - Google Patents

Abstract

The tap hole drilling machine incorporates a column (18), an arm (20) which is pivotable about an axis (22), and a drill carriage (26) which is attached to the arm and is pivotable relative to the arm about an axis (28). It further includes link bars (34', 34") connected by means of hinges (36', 36") and (40', 40") respectively to the column (18) and to the drill carriage (26), to create a transmission unit in which a pivot motion of the arm (20) about the axis (22) produces a pivot motion of the drill carriage about the axis (28). The machine has a switching mechanism (44', 44") which transfers the link bars (34', 34") from a first position into a second position in the transmission unit.

Description

The present invention relates to a tap hole drilling machine, in particular a tap hole drilling machine for operating two tap holes a shaft furnace, for example on a blast furnace.

Modern blast furnaces usually have several tap holes. Any of these Tap holes are operated by our own tap hole drilling machine. There one powerful tap hole drilling machine is relatively expensive, it would be for cost reasons of course interesting to develop one machine that has two at the same time can operate adjacent stitch holes.

Such a tap hole drilling machine was already described in DE-A-19 62 953 in 1967 described. This machine includes a fixed console and a boom that is pivotable with its first end about a first axis is stored in the fixed console. The cantilever, which by a Drive from a first working position in front of the first tap hole into a second Working position before the second tap hole is pivotable, carries on his free end of a vertical trunnion on which a drill carriage by one second axis is pivotally mounted. A handlebar is by means of swivel joints each with a fixed lever arm on the console and one fixed connected crank on the pivot. This will be a four-link swivel gear, in which a pivoting movement of the boom around the first axis a pivoting movement of the carriage around second axis generated. This gearbox supposedly enables the carriage only and just by the swinging movement of the boom, in the first Working position automatically in the axial extension of the first tap hole and in the second working position automatically in the axial extension of the second Align the stitch hole. So with a precisely aligned gun carriage in the first Working position, an acceptable alignment of the carriage in the second Working position is achieved, however, the pivoting movement of the boom before reaching a working position symmetrical to the first working position before the second tap hole. As from Figure 2 of DE-A-19 62 953 can be clearly seen, this shows the carriage in the working position the second tap hole a much greater distance from the tap hole as in Working position before the first tap hole. Should further the distance to Taphole in one of the two working positions does not become unacceptably large, the well-known tap hole drilling machine may only have a short boom and the fixed bracket must be relatively close to the furnace armor to be ordered. However, such a tap hole drilling machine can only two stitch holes serve that are relatively close together.

The present invention has for its object a tap hole drilling machine to create, which allows to solve the aforementioned problems master.

This object is achieved by a tap hole drilling machine solved according to claim 1.

A tap hole drilling machine according to the invention for operating two Tap holes on a shaft furnace are identified by the tap hole drilling machine DE-A-19 62 953, a support structure in which a boom with a first End is pivotally mounted about a first axis. A drive generates one Swiveling movement of the boom, for example from a rest position into one first working position in front of a first tap hole, or in a second working position in front of a second tap hole, and back to the rest position. A drill carriage is pivotable about a second axis with the second end connected to the boom. At least one handlebar is over a first one Joint with the support structure and via a second joint with the swivel Mounted carriage, so that a gear is formed in which one Swiveling movement of the boom around the first axis is a swiveling movement the carriage around the second axis. A tap hole drilling machine according to the invention differs from the tap hole drilling machine from DE-A-19 62 953 essentially in that the transmission switching means for Switching the active handlebar (i.e. the handlebar which the Pivoting movement of the carriage in the gearbox) from a first position has in a second position in the transmission. By switching the Handlebar from a first position to a second position in the transmission, For example, a first transmission function of the transmission for the Swinging the boom into the first working position and a second Transmission function of the gearbox for swinging the boom in determine the second working position independently, with "Transmission function of the transmission" is the function that the Swivel angle of the carriage depending on the swivel angle of the boom specifies. In other words, by changing the position of the handlebar in the gearbox, for example, the alignment of the carriage can be both tune a first, as well as a second tap hole, without the pivoting movement of the boom must be limited. Hereby can determine the distance between the carriage and the taphole and the orientation of the carriage in front of each of the two stitch holes. It should also be noted that the two-part transfer function of Gearbox, swivel amplitudes of the boom over 180 ° without further ado can be achieved, which is not the case with the known machine from DE-A-19 62 953 is possible. As a result, the tap hole drilling machine according to the invention can For example, also use widely spaced stitch holes.

In a preferred embodiment, the transmission has a first and a second handlebar, the first handlebar in a first position and the second handlebar a second, different position in the transmission having. In this embodiment, the switching means comprise a first one Coupling device for engaging and disengaging the first handlebar from the Gearbox and a second coupling device for engaging and disengaging the second handlebar from the gearbox. When swinging the boom out the rest position in the first working position is the first handlebar Gearbox engaged and the second handlebar disengaged from the gearbox, so that the pivoting movement of the carriage through the first handlebar is produced. When swinging the boom from the rest position into the second working position, the second handlebar is coupled into the gearbox and the first handlebar is disengaged from the transmission so that the pivoting movement the carriage is generated by the second handlebar.

In a simple and at the same time reliable execution, the first and second coupling device each axially into the handlebar built-in telescopic (i.e. variable-length) element and means to lock and unlock the change in length of this telescopic Elements. This telescopic element is advantageously a with a pressure medium lockable cylinder controlled by a changeover valve. In In a first position, the changeover valve connects the cylinder of the first Coupling device with a pressure source and relieves the cylinder of the second Coupling device. In a second position, the changeover valve connects the Cylinder of the second coupling device with a pressure source and relieves the Cylinder of the first coupling device.

The tap hole drilling machine has a symmetrical swivel behavior when the first and second handlebars are in the middle position of the boom between the first and second working position, essentially symmetrical are a plane that contains the first and second axes. Such one Symmetrical swivel behavior is with the machine from DE-A-1962953 not achievable.

The two handlebars advantageously comprise means for changing them Working length. By changing the working length of the handlebars in indeed the alignment of the carriage in the first and second working positions of the Adjust the boom in the simplest way.

In a second embodiment, the transmission has a single handlebar on both the pivoting movement of the carriage when pivoting the Outrigger from the rest position into the first working position, as well as the Swiveling movement of the carriage when swiveling the boom out of the Rest position in the second working position. In this configuration have the switching means for switching the handlebar from the first Position in the second position and vice versa, at least one actuator on, with at least one of the two joints that this handlebar with connect the support structure and the carriage, on this adjusting device is mounted that its position, by actuating the adjusting device, in Gear is adjustable. The adjusting device is advantageously a swivel device.

In a first embodiment of the swivel device, the two are Joints of the handlebar designed as ball joints, a first Ball joint is arranged on the swivel device, and the swivel axis the pivoting device in the rest position through the center of the second Ball joint leads. It should be noted that when pivoting the pivoting device the orientation of the carriage is not changed in the rest position. Around to obtain a symmetrical swiveling behavior of the tap hole drilling machine if the boom is in the middle position between the first and second working position, the position of the ball joint on the swivel is arranged in the first and second position of the handlebar in the transmission, be symmetrical to a plane containing the first and second axes, and the center of the second ball joint lies in this plane.

In an alternative embodiment of the invention, the two joints, which connect the handlebar with the support structure and the carriage, each arranged on a swivel device. So when swiveling the Handlebar from its first position in the transmission to its second position in the Gearbox, the orientation of the carriage is not changed, the handlebar a telescopic (i.e. length-adjustable) axially built into the handlebar Element and means for locking and unlocking the change in length have this telescopic element. This telescopic element can be, for example, a cylinder that can be locked with a pressure medium.

The tap hole drilling machine has a symmetrical swivel behavior on when the positions of the two joints in the first and second position of the Handlebar, with the boom in the middle position between the first and second Working position, each are essentially symmetrical to a plane which contains the first and second axes.

Embodiments of the invention are in the accompanying drawings are shown and are described in more detail below.

Figur 1:

eine Draufsicht auf eine erste Ausführung einer erfindungsgemäßen Stichlochbohrmaschine in einer zentralen Ruhestellung, einer ersten Arbeitsstellung vor einem ersten Stichloch und einer zweiten Arbeitsstellung vor einem zweiten Stichloch;

Figur 2:

eine perspektivische Ansicht der Stichlochbohrmaschine aus Figur 1 in der zweiten Arbeitsstellung;

Figur 3:

ein Detail einer Ausführungsvariante der Stichlochbohrmaschine aus Figur 1;

Figur 4:

ein Detail (teilweise geschnitten) einer Lenkstange der Stichlochbohrmaschine aus Figur 1;

Figur 5:

eine perspektivische Ansicht einer zweite Ausführung einer erfindungsgemäßen Stichlochbohrmaschine in der Ruhestellung;

Figur 6:

eine Ansicht der Schwenkkonsole der Stichlochbohrmaschine der Figur 6;

Figur 7-9:

jeweils eine Draufsicht auf eine dritte Ausführung einer erfindungsgemäßen Stichlochbohrmaschine in einer Ruhestellung, beim Umschwenken der Lenkstange aus einer ersten Stellung (Figur 8), über eine Zwischenstellung (Figur 9), in eine zweite Stellung (Figur 10).

Show it:

Figure 1:

a plan view of a first embodiment of a tap hole drilling machine according to the invention in a central rest position, a first working position in front of a first tap hole and a second working position in front of a second tap hole;

Figure 2:

a perspective view of the tap hole drilling machine of Figure 1 in the second working position;

Figure 3:

a detail of an embodiment of the tap hole drilling machine of Figure 1;

Figure 4:

a detail (partially cut) of a handlebar of the tap hole drilling machine of Figure 1;

Figure 5:

a perspective view of a second embodiment of a tap hole drilling machine according to the invention in the rest position;

Figure 6:

a view of the swivel console of the tap hole drilling machine of Figure 6;

Figure 7-9:

in each case a top view of a third embodiment of a tap hole drilling machine according to the invention in a rest position, when the handlebar is pivoted from a first position (FIG. 8), via an intermediate position (FIG. 9), into a second position (FIG. 10).

In Figure 1 is a blast furnace 10 with a first tap hole 12 and second tap hole 14 shown schematically. An inventive Tap hole drilling machine 16 is in the middle between the two tap holes 12 and 14 set up. The solid hole drilling machine is 16 in with solid lines Shown rest position. The tap hole drilling machine 16 is with dashed lines in the first working position before the first tap hole 12 and in the second working position shown in front of the second tap hole 14.

The structure of the tap hole drilling machine 16 is based on the Figures 1 and 2 described in more detail. The tap hole drilling machine 16 shown comprises a support structure which is designed as a fixed bracket 18. On this bracket is a boom 20 with its first end around a first Axis 22 pivotally mounted. This axis 22 is preferably in a vertical plane 24 which is a plane of symmetry of the two stitch holes 12 and 14 trains. The axis 22 can within this plane, as in Figure 2 shown to be arranged vertically; however, it can also have an inclination in Have direction blast furnace 10. The boom 20 can thus from the Rest position in a first working position in front of the first tap hole 12 and in swivel a second working position in front of the second tap hole 14. One on known carriage 26 is pivotable with the second end of the boom 20 connected so that the carriage 26 relative to the boom by a second Axis 28 is pivotable. This mount usually carries, as in Figure 2 shown, a hammer drill 30 of one guided on the carriage 26 Tap hole drill 32 drives.

The tap hole drilling machine 16 comprises a gear which is designed in this way is that when the boom is pivoted into the first working position Mount is aligned with the first tap hole 12 and when swiveling the boom in the second working position onto the second tap hole 14 is aligned. In Figure 1, this transmission includes a first Handlebar 34 'and a second handlebar 34' '. Each of these two Articulated rods 34 ', 34' 'is connected via a first articulation 36', 36 '' with a fixed one Arm 38 ', 38' 'of the console 18 connected. A second joint 40 ', 40' ' connects the handlebars 34 ', 34' 'to a double crank 42 which is connected in a rotationally fixed manner to the mount 20 which can be pivoted about the axis 28.

The two handlebars 34 'and 34' 'are alternately in the transmission engaged and disengaged. In Figure 1, for example, when swiveling the Boom 20 in the (first) working position in front of the first tap hole 12 the first Handlebar 34 'coupled into the transmission and the second handlebar 34' ' disengaged from the transmission. When swinging the boom 20 into the However, the (second) working position in front of the second tap hole 14 is the first Handlebar 34 'disengaged from the transmission and the second handlebar 34' ' engaged in the transmission. As a result, the handlebar, which the Pivotal movement of the carriage 26 when pivoting the boom 20 from the Rest position in the first working position, another position in Gearbox on as the handlebar, which the pivoting movement of the carriage 26th when swinging the boom 20 from the rest position into the first Working position generated.

The clutch rods 34 'and 34' 'are advantageously engaged and disengaged each via a telescopic axially built into the handlebars 34 'and 34' ' (i.e. variable-length) element 44 ', 44' ', for coupling a handlebars 34 ', 34' 'in the gearbox, its telescopic function is lockable. An embodiment of such a telescopic element 44 ', 44' 'is shown in FIG. 4. In this embodiment, it is telescopic element 44 ', 44' 'designed as a hydraulic cylinder. This Hydraulic cylinder includes a piston 46 which is connected to a first part of the handlebar 34 'is connected, and a housing 48 which is connected to a second part of the Handlebar 34 'is connected. The piston 46 seals in the housing 48 Pressure chamber 50 axially. The pressure chamber 50 is connected via a connection 52 pressurized with a pressure medium. When pressurized this Pressure chamber 50 (see Figure 4), the piston 46 against an end stop pressed in the housing 48 and is consequently blocked, at least as long as the Tensile forces in the handlebar 34 'do not affect the compressive force acting on the piston exceeds. In other words, the handlebar 34 'is mechanically effective in the transmission is engaged. When the pressure in the pressure chamber 50 is relieved Pistons 46, however, are moved freely in the housing 48, so that no forces are transmitted and the handlebar 34 'consequently from the transmission is disengaged. In Figure 1 you can see that in the middle position of the Boom 20 both hydraulic cylinders 44 ', 44' 'have their shortest length. At the The hydraulic cylinder 44 'is pivoted into the first working position with a Pressurized medium, so that the length of this hydraulic cylinder 44 ' is hydraulically blocked. The hydraulic cylinder 44 '', however, is relieved by For example, it is connected to the tank so that this hydraulic cylinder 44 '' can freely expand when swiveling into the first working position. At the The hydraulic cylinder 44 ″ is pivoted into a second working position Pressurized medium, so that the length of this hydraulic cylinder 44 '' is hydraulically blocked. The hydraulic cylinder 44 ', however, is relieved, so that this hydraulic cylinder 44 'free itself when pivoting into the second working position can expand. The two hydraulic cylinders 44 ', 44' 'are switched over for example, as indicated in Figure 4, by a 4/2-way switching valve 54. Es remains to be noted that it is also possible to use hydraulic cylinders that are hydraulically lockable at maximum length. In this case, however in Figure 1, the handlebar 34 'when pivoting into the second working position and the handlebar 34 '' when swiveling into the first working position work. The unlocked hydraulic cylinder in the non-working handlebar would be squeezed together.

• der Ausleger 20 muß in Mittelstellung zwischen erster und zweiter Arbeitsstellung stehen;
• die Ebene 72 welche die erste Drehachse 22 und die zweite Drehachse 28 enthält muß die Längsachse der Lafette 26 enthalten;
• die ersten Gelenke 36', 36'' und zweiten Gelenke 40', 40'' müssen jeweils symmetrisch zu der Ebene 72 angeordnet sein, oder anders ausgedrückt, die zwei Lenkstangen 34' und 34'' müssen symmetrisch zu der Ebene 72 angeordnet sein.

If the pivoting movement of the carriage 26 into the first working position is to be symmetrical with the pivoting movement into the second working position, the following conditions must essentially be fulfilled in the rest position, in which the transmission is switched over:

• the boom 20 must be in the middle position between the first and second working position;
• the plane 72 which contains the first axis of rotation 22 and the second axis of rotation 28 must contain the longitudinal axis of the mount 26;
• the first joints 36 ', 36''and second joints 40', 40 '' must each be arranged symmetrically to the plane 72, or in other words, the two handlebars 34 'and 34''must be arranged symmetrically to the plane 72.

However, it may also be desirable that the position of the carriage 26 before the tap hole 12 not symmetrical to the position of the carriage 26 before Tap hole 14 is. This can be achieved, for example, in that the Working length of one of the two handlebars 34 ', 34' 'is changed. To one The handlebars can easily adjust the working length 34 ', 34' 'each have, for example, a threaded rod 56', 56 ''.

FIG. 3 shows an embodiment detail that is asymmetrical Alignment of the carriage 26 in both working positions, with unchanged Position of the carriage 26 in the middle position results. For this purpose, the joint 36 'as slidably mounted swivel or ball joint. The degree of freedom of movement is essentially vertical in the middle position of the boom to the longitudinal axis of the handlebar 34 '..

Figures 5 and 6 show a second embodiment of an inventive Tap hole drilling machine. This tap hole drilling machine 116 has one only handlebar 134 on. The latter is by means of a first ball joint 136 connected to a swivel device 160, which is fixed on the console 18th is mounted. A second ball joint 140 connects the handlebar 134 to a crank 142 which is non-rotatably connected to the carriage 26. The swivel device 160 is mounted on the console 18 such that in the rest position of the Boom 20 the extension of its pivot axis 162 through the center of the second ball joint 140 leads. In this rest position, the Handlebar can thus be pivoted about the pivot axis 162 and describes a cone jacket without rotation of the crank 142 To cause gun carriage 26. In other words, the boom is at rest 20 can be the ball joint 136 by means of the pivoting device 160 from a swivel the first position in the gearbox into a second position in the gearbox, without the alignment of the mount 26 is changed.

The swivel device 160 essentially comprises a swivel arm 164, which is mounted in a bearing block 166 on the bracket 18. This Swivel arm 164 is via an actuator, for example a pressure cylinder 168, pivotable from a first position into a second position and in this Lockable position. Two adjustable end stops allow the two end positions of the swivel arm 164 in which it can be locked, independent of each other, and thus the necessary corrections regarding the alignment of the carriage 26 in the first and second working position to make. It should be noted that these corrections affect the position of the Do not influence carriage 26 in the rest position.

• der Ausleger muß in Mittelstellung zwischen erster und zweiter Arbeitsstellung stehen;
• die Ebene 172, welche die erste Drehachse 22 und die zweite Drehachse 28 enthält, muß die Längsachse der Lafette 26 enthalten;
• die erste und zweite Stellung des Kugelgelenks 136 müssen symmetrisch zu der Ebene 172 sein, und
• das Zentrum des zweiten Kugelgelenks 140 muß in dieser Ebene 172 liegen.

If the pivoting movement of the carriage 26 into the first working position is to be symmetrical with the pivoting movement into the second working position, the following conditions must essentially be fulfilled in the rest position, in which the transmission is switched over:

• the boom must be in the middle position between the first and second working position;
• plane 172, which includes first axis of rotation 22 and second axis of rotation 28, must contain the longitudinal axis of mount 26;
• the first and second positions of ball joint 136 must be symmetrical about plane 172, and
• the center of the second ball joint 140 must lie in this plane 172.

Another embodiment of the invention is shown in FIGS. 7, 8 and 9 described. This tap hole drilling machine 216 has a single one Handlebar 234 on. The latter is connected to a by means of a first joint 236 connected to the first swivel device 260 ′, which is fixed on the bracket 18 is mounted. A second joint 240 connects the handlebar 234 to one second swivel device 260 ''. This second swivel device is 260 ″ firmly mounted on a crank 242, which rotatably with the carriage 26th connected is. The two swivel devices 260 ', 260' 'are through Actuators 262 ', 262' 'each in a first and second angular position can be blocked. Around both the first and second joints 236, 240 swivel a first position in the transmission into a second position in the transmission to be able to, without the orientation of the Mount 26 is changed, the handlebar 234 has an axially installed, telescopic (i.e. variable-length) element 262, the telescopic Function can be locked or unlocked. This element 262 is for Example of a cylinder 262 which can be locked with a pressure medium, as is shown in FIG 4 has been described. For pivoting the handlebar 234 from a first position in the transmission to a second position in the transmission, the Cylinder 262 unlocked so that the handlebar 234 its length without substantial Resistance can change. To prevent the rest Resistance in changing the length of the handlebar 234 a rotational movement the carriage 26 is generated about the axis 28, of course, the Torque caused by the remaining resistance when changing the length the handlebar 234 is generated, less than the friction torque to be overcome be in the pivot bearing of the carriage 26. If this is not guaranteed, it must a braking device or a blocking device that can be switched on and off in the Rotary bearing of the carriage 26 can be provided. After the handlebar 234 in their first or second position is arranged and blocked in the transmission, the cylinder 262 is locked and the boom 20 can now move into the first or second working position.

• der Ausleger muß in Mittelstellung zwischen erster und zweiter Arbeitsstellung stehen;
• die Ebene 272 welche die erste Drehachse 22 und die zweite Drehachse 28 enthält muß die Längsachse der Lafette 26 enthalten;
• die erste und zweite Stellung des ersten Gelenks 236 müssen symmetrisch zu der Ebene 272 sein, und
• die erste und zweite Stellung des zweiten Gelenks 240 müssen symmetrisch zu der Ebene 272 sein.

If the pivoting movement of the carriage 26 into the first working position is to be symmetrical about the pivoting movement into the second working position, the following conditions, for example, must essentially be fulfilled in the rest position in which the gearbox is switched:

• the boom must be in the middle position between the first and second working position;
• the plane 272 which contains the first axis of rotation 22 and the second axis of rotation 28 must contain the longitudinal axis of the mount 26;
• the first and second positions of the first hinge 236 must be symmetrical about the plane 272, and
• the first and second positions of the second hinge 240 must be symmetrical about the plane 272.

Claims (19)

Tap hole drilling machine, with: a support structure (18); a boom (20), the first end of which is pivotally mounted in the support structure (18), so that the boom (20) is pivotable relative to the support structure (18) about a first axis (22); a carriage (26) pivotally connected to the second end of the boom (20) so that the carriage (26) is pivotable relative to the boom (20) about a second axis (28); an active handlebar (34 ', 34'', 134, 234) which is connected to the support structure (18) via a first joint (36', 36 '', 136, 236) and via a second joint (40 ', 40'', 140, 240) is connected to the pivotable mount (26) in such a way that a gear is formed in which a pivoting movement of the arm (20) about the first axis (22) and a pivoting movement of the mount (26) about the second axis (28) generated,
characterized, that the transmission switching means (44 ', 44'', 160, 260', 260 '') for switching the active handlebar (34 ', 34'', 134, 234) from a first position in the transmission to a second position in the transmission having. Tap hole drilling machine according to claim 1, characterized in that that the transmission has a first and a second steering rod (34 ', 34''), the first steering rod (34') having a first position and the second steering rod (34 '') having a second different position in the transmission, and that the switching means comprise the following devices: a first coupling device (44 ') for engaging and disengaging the first handlebar (34') from the transmission; and a second coupling device (44 '') for engaging and disengaging the second handlebar (34 '') from the transmission. Tap hole drilling machine according to claim 2, characterized in that the first and second coupling devices each axially into the handlebar (34 ', 34 '') built-in telescopic element (44 ', 44' ') and locking means and unlocking the change in length of this telescopic element include. Tap hole drilling machine according to claim 3, characterized in that the telescopic element can be locked with a pressure medium Cylinder (44 ', 44' '). Tap hole drilling machine according to claim 4, characterized by a Changeover valve (54) which has a first position and a second position, being in the first position the cylinder (48) of the first coupling device (44 ') connects to one pressure source and the cylinder (48) the second Coupling device (44 '') relieved, and in the second position the cylinder (48) of the second coupling device (44 '') connects to a pressure source and relieves the cylinder (48) of the first coupling device (44 '). Tap hole drilling machine according to one of claims 2 to 5, characterized in that the boom (20) can be pivoted into a first working position in front of a first tap hole (12) and in a second working position in front of a second tap hole (14), and has a central position between the first and second working positions, and that the first and second steering rods (34 ', 34''), when the boom (20) is in the middle position, are essentially symmetrical to a plane (72) which contains the first and second axes (22, 28). Tap hole drilling machine according to one of claims 2 to 6, characterized by means (56 ', 56' ') for changing the working length of the two handlebars (34 ', 34' '). Tap hole drilling machine according to one of claims 2 to 6, characterized characterized in that the first joint (36 ', 36' ') has at least one handlebar (34 ', 34' ') is a slidably mounted swivel or ball joint. Tap hole drilling machine according to claim 8, characterized in that the Extension arm (20) in a first working position in front of a first tap hole (12) and can be pivoted into a second working position in front of a second tap hole (14) and between the first and second working position Has middle position, and the degree of freedom of displacement mounted swivel or ball joint in the middle position of the boom (20) in is substantially perpendicular to the handlebar (34 ', 34' '). Tap hole drilling machine according to claim 1, characterized in that that the switching means for switching the handlebar (134, 234) from the first position to the second position have at least one adjusting device (160, 260), at least one of the two joints (136, 236, 240), which the handlebar (134, 234) with the support structure (18) and the carriage (26), is mounted on this adjusting device (160, 260) in such a way that its position in the gearbox is adjustable. Tap hole drilling machine according to claim 10, characterized in that the switching means furthermore at least one actuator (168, 262 ', 262' ') for actuating the actuating device (160, 260 ', 260' '). Tap hole drilling machine according to claim 10 or 11, characterized in that that the adjusting device is a swivel device (160, 260 ', 260' '). Tap hole drilling machine according to claim 12, characterized in that the two joints (134, 140) are designed as ball joints, one first ball joint (134) is arranged on the swivel device (160), and the pivot axis (162) of the pivot device (160) in a particular one Position of the boom (20) through the center of the second Ball joint (140) leads. Tap hole drilling machine according to claim 12, characterized in that the boom (20) in a first working position in front of a first tap hole (12) and in a second working position in front of a second tap hole (14) can be swung in and between the first and second working position Has middle position, and that at the middle position of the boom (20), the Position of the first ball joint (136) on the swivel device (160) is arranged, in the first and second position of the handlebar (134) is symmetrical about a plane (172) which is the first and second axes (22, 28) contains, and the center of the second ball joint (140) in this Level lies. Tap hole drilling machine according to claim 13 or 14, characterized in that that the pivoting device (160) at least one adjustable End stop (170 ', 170' ') has. Tap hole drilling machine according to claim 10, characterized in that the two joints (236, 240), which connect the handlebar (234) with the support structure (18) and the mount (26), are each arranged on a swivel device (260 ', 260''), and that the handlebar (234) has a telescopic element (264) axially built into the handlebar (234) and means for locking and unlocking the change in length of this telescopic element (264). Tap hole drilling machine according to claim 16, characterized in that the telescopic element can be locked with a pressure medium Cylinder (264). Tap hole drilling machine according to claim 15 or 17, characterized in that the boom (20) in a first working position before a first Tap hole (12) and in a second working position before a second Tap hole (14) can be swiveled in and between the first and second working positions has a central position that the positions of the two joints (236, 240) in the first and second position of the handlebar (234), in the middle position of the boom (20), each symmetrical to a plane (272) which contains the first and second axes (22, 28). Tap hole drilling machine according to one of claims 1 to 18, characterized characterized in that the second joint (40 ', 40' ', 140, 240) on a crank (42, 142, 242) is arranged, which is fixedly connected to the carriage (26).

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