EP2361731A2 - Rotary percussion drilling device and method - Google Patents

Abstract

The device (1) has a rotary drive (10) for rotatably driving a tool threaded end (3) of a striking piston (22), and a pressure-controlled fluid-feeding device (50) variably controlling supply of hydraulic fluid i.e. oil, and pressure from a pressure source to pressure chambers (42, 44). One of the pressure chambers with a return stroke surface (24) is spacer-connected with another pressure source in the turning operational position for the tool threaded end. The latter pressure source operates the rotary drive, where the pressure sources are designed as hydraulic pumps. An independent claim is also included for a method for operating an impact drilling device.

Description

The invention relates to a Schlagdrehbohrvorrichtung according to the preamble of claim 1. The invention further relates to a method for operating a Schlagdrehbohrvorrichtung according to the preamble of claim 11.

The impact rotary drilling apparatus has a rotary drive for rotationally driving a tool insertion end and a percussion mechanism with a percussion piston which reverses in a housing between a first pressure chamber which is bounded by a return stroke of the percussion piston, and a second pressure chamber which is bounded by a working stroke of the percussion piston is movably mounted on. The Schlagdrehbohrvorrichtung further comprises a controlled pressure fluid supply means with which a supply of a pressurized fluid from a first pressure source on the one hand to the first pressure chamber and the second pressure chamber is variably controllable, wherein a reversing movement of the percussion piston with a working stroke in the direction of the tool insertion end and a return stroke can be generated in the opposite direction.

Such Schlagdrehbohrvorrichtung is for example from the DE 0 473 968 B1 known.

Impact rotary drilling devices are used in particular in the civil engineering for the creation of Erdbohrungen or for introducing piles, anchors or the like in the ground. When creating holes, the drilling progress can be significantly increased by the striking action of the tool insertion end. This reduces the time required to make a hole, minimizing overall drilling costs.

The rotary drive such Schlagdrehbohrvorrichtungen can usually - depending on the working conditions - operated alone or together with the percussion become. In order to reduce wear of the tool insertion end and the percussion piston in a pure rotary operation, it is known to lift the percussion piston during the pure rotary operation of the tool insertion end, so to space.

Known lifting devices include mechanical components that make the system expensive and prone.

In the EP 0 473 968 B1 It is proposed to mechanically fix the percussion piston in a retracted return stroke position by means of a stop element arranged annularly around the percussion piston. Since the stop element is arranged in an annular manner around the percussion piston, both the stop element and the percussion piston are exposed to wear on the respective contact surface. In addition, for proper operation of the device a sealing of Schlagkobens against the stop element is required, which requires a high accuracy of fit and increases manufacturing costs.

The invention has the object of providing a Schlagdrehbohrvorrichtung, which is further reduced wear of the percussion piston and particularly economical to manufacture and operate. The invention is also based on the object to provide a corresponding method for operating a Schlagdrehbohrvorrichtung.

The object is achieved according to the invention by a Schlagdrehbohrvorrichtung according to claim 1 and a method for operating a Schlagdrehbohrvorrichtung according to claim 11. Preferred embodiments are given in the dependent claims.

The Schlagdrehbohrvorrichtung invention is characterized in that an adjusting element is provided which is adjustable between a stroke operating position and a rotational operating position. It is provided that in the rotary operating position for spacing the percussion piston from the tool insertion end, the first pressure chamber with the return stroke surface with a second pressure source is line connected.

A first aspect of the invention is to provide a percussion mode of operation and a rotary mode of operation of the percussion rotary type apparatus. In the percussion mode is turned on the percussion, usually also in addition, the rotary drive is turned on. In the rotary operating mode, only the rotary drive is in operation while the hammer mechanism is switched off.

Another basic idea of the invention is to provide a purely hydraulic device for lifting the Schlagkobens, which can be used for example in a hydraulically operated percussion hammer. By lifting the purely axially moving percussion piston of the usually rotating tool insertion end harmful friction and thereby resulting wear between the Schlagkoben and the Werkzeuginsteckende is virtually eliminated.

By means of the impact rotary drilling device according to the invention, the percussion piston is brought into a return stroke position during the turning operation purely hydraulically - without mechanical components - and held therein. During turning operation wear of the percussion piston is thus practically impossible. In addition, the device is compared to known lifting devices cheaper to manufacture and less prone to operation.

A first aspect of the invention may be seen to provide the first pressure chamber in the impact mode of operation from a first pressure source with a pressurized fluid, whereby the return stroke of the percussion piston is acted upon by the pressurized fluid and the percussion piston is pressed in the direction of Rückhubstellung. In the pure rotary operating mode, that is to say when the striking mechanism is switched off, the first pressure chamber is connected to a second pressure source, so that the return stroke surface of the percussion piston is pressurized via a second pressure source. As a result, the pressure fluid at pressure on the return stroke of the percussion piston is also in a pure rotary operation of the Schlagdrehbohrvorrichtung and this is pressed despite switched-Schlagwerk in the direction of Rückhubstellung. Since no pressure is applied to the working lifting surface in the rotary operating mode, the percussion piston is pressed into the return stroke position by the pressure applied to the return stroke surface. In this return stroke, the percussion piston is lifted from the tool insertion end, so that no contact between the percussion piston and tool insertion is given.

Another basic idea of the invention can therefore be seen in the fact that the return stroke surface of the percussion piston is acted upon directly by the pressurized fluid both during an impact operation and during a pure rotational operation. In other words, the pressurized fluid is in direct contact with the return stroke surface in both the hammering mode and the rotary operating mode. In this case, the required pressure is provided during the impact operation by the first pressure source and during the rotational operation by the second pressure source.

A particularly preferred embodiment of the invention is given by the fact that the second pressure source is a pressure source for operating the rotary drive. As a result, an already existing pressure source can be used for spacing the impact head from the tool insertion end and the provision of further pressure sources is not required. In addition, the pressure source for operating the rotary drive in rotary operation mode is already in operation.

A further preferred embodiment is characterized in that the first pressure chamber is conductively connected to the first pressure source and to the second pressure source and that a pressure line between the first pressure chamber and the first pressure source and a pressure line between the first pressure chamber and the second pressure source by the actuating element, in particular alternately, can be closed. In this way, a pressurization of the first pressure chamber, in particular selectively, by the first and the second pressure source allows in a simple manner. The return stroke of the percussion piston is therefore conductively connected to both the first and the second pressure source and acted upon by both pressure sources, in particular alternately, with a pressurized fluid.

Furthermore, it is preferred that with the opening of the pressure line between the first pressure chamber and the second pressure source, the pressure line between the first pressure chamber and the first pressure source is closed and vice versa. This is to be understood in particular that simultaneously with the opening of the pressure line between the first pressure chamber and the second pressure source, a closure of the pressure line between the first pressure chamber and the first pressure source is effected. This ensures that, apart from a possible, certain overlap area, the first pressure chamber only with one of the two pressure sources in line connection. The return stroke of the percussion piston is thus pressurized either by the first pressure source or by the second pressure source with the pressurized fluid. As a result, the impact head is always raised automatically and in accordance with the respective mode of operation without an operator having to monitor or trigger it.

A particularly suitable structural embodiment is that the adjusting element is designed as a control slide, which can be pressurized by the first pressure source and the second pressure source, and that the control element is automatically adjustable in the rotational operating position at drop in pressure of the first pressure source. It is therefore not necessary to actively adjust the control element when switching to the pure rotary operating mode in the rotary operating position. Rather, the adjustment is done automatically by the drop in pressure of the first pressure source.

In this context, it is particularly preferred that the actuating element has at least two control surfaces, wherein a first control surface with the second pressure source and a second control surface with the first pressure source is conductively connected. By this embodiment, the actuator itself is controlled by the two pressure sources. By acting on the first control surface, the actuating element is pressed in the direction of the impact operating position and by acting on the second control surface in the direction of the rotary operating position. It is particularly preferred that the first control surface is larger than the second control surface, so that at the same applied pressure from both pressure sources, the actuator is arranged in the impact mode in the impact mode.

Furthermore, it is preferred that the actuating element has a third control surface, which is conductively connected to a pressureless environment or a non-pressurized tank. Under a depressurized state, on the one hand, a state at normal ambient pressure, ie in particular about 1.013 bar (abs) can be understood. On the other hand, some tanks can also be prestressed, with the return line used having a dynamic pressure of approximately 1-5 bar. The third control surface serves, in particular, to provide differently sized first and second control surfaces.

In principle, the adjusting element can be arranged separately from the housing of the striking mechanism. According to the invention, however, it is preferred that the adjusting element is integrated in the housing. The arrangement in the housing results in a compact construction and allows short line connections to the first and second pressure chamber.

A further preferred embodiment of the invention is given by the fact that the working stroke of the percussion piston is greater than the return stroke. This embodiment allows operation of the hammer mechanism in which the smaller return stroke is permanently pressurized, while the larger working stroke surface is subjected to intermittent pressure. When a pressurization of both surfaces so a stroke is carried out due to the larger working stroke and the percussion piston - against the action of a constant restoring force - moves in the direction of the tool insertion end. In contrast, the working stroke of the percussion piston is depressurized to perform a return stroke, so that the percussion piston is displaced in the opposite direction under the action of the restoring force.

Accordingly, it is particularly preferred that the working stroke surface by means of the pressure fluid supply means alternately pressurizable and depressurized switchable. This can be achieved by means of the controlled discharge fluid supply device which, in a manner known per se, has a control slide and a line system via which the first pressure source can be line-connected and disconnected at intervals with the second pressure chamber.

In the method according to the invention it is provided that the Schlagdrehbohrvorrichtung has a percussion piston, which is mounted reversibly movable in a housing between a first pressure chamber, which is bounded by a return stroke of the percussion piston, and a second pressure chamber, which is bounded by a working stroke of the percussion piston , A tool insertion end is driven in rotation by means of a rotary drive. By means of a controlled pressure fluid supply device, a supply of a pressure fluid from a first pressure source on the one hand to the first pressure chamber and on the other hand to the second pressure chamber is variably controlled, wherein a reversing movement of the percussion piston is produced with a working stroke in the direction of the tool insertion end and a return stroke in the opposite direction.

Under a variably controlled supply of the pressurized fluid on the one hand to the first pressure chamber and on the other hand to the second pressure chamber is to be understood in particular a supply of the pressure fluid to the two pressure chambers, wherein at least the supply to one of the two pressure chambers is controllable such that alternately connect the corresponding pressure chamber the first pressure source is produced and interrupted. The other pressure chamber may be permanently connected to the pressure source. Usually, there is always a working pressure at the return stroke surface in impact mode. This working pressure is provided via the first pressure source.

The working surface is alternately pressurized by the actuator and depressurized. About control edges on the percussion piston, which are each arranged at a transition from a smaller diameter region to a larger diameter region, the actuator is controlled.

In a lower end position, the percussion piston hits the tool insertion end. Due to the impact of the percussion piston on an impact surface of the tool insertion end, the kinetic energy of the percussion piston is transferred as striking energy to the tool insertion end. At an opposite end of the tool insertion end 3, the impact energy is delivered to a drilling tool, for example via a drill rod.

The inventive method is characterized in that an adjusting element is set in a rotational operating position, wherein in the rotational operating position, the first pressure chamber with the return stroke surface is conductively connected to a second pressure source and the percussion piston is spaced from the tool insertion end. With the method according to the invention, the advantages described in connection with the Schlagdrehbohrvorrichtung be achieved.

Fig. 1

eine Schlagdrehbohrvorrichtung im Schlagbetriebsmodus und

Fig. 2

eine Schlagdrehbohrvorrichtung im reinen Drehbetriebsmodus.

The invention will be further explained with reference to the accompanying drawings, in which an embodiment of the invention is shown schematically. In these shows:

Fig. 1

a hammershot drill in hitting mode and

Fig. 2

a hammer drill in pure rotary mode.

In the FIGS. 1 and 2 is a Schlagdrehbohrvorrichtung invention 1 schematically shown in the form of a percussion hammer. The Schlagdrehbohrvorrichtung 1 has a rotary drive 10 and a striking mechanism 20. Fig. 1 shows the impact rotary drilling apparatus 1 in a hitting operation mode in which the striking mechanism 20 is turned on. Fig. 2 shows the Schlagdrehbohrvorrichtung 1 in a rotary operating mode in which only the rotary drive 10 is turned on and the hammer mechanism 20 is turned off.

By means of the rotary drive 10, a tool insertion end 3 can be set in rotation. The rotary drive 10 has a hydraulic motor 12. A torque of the hydraulic motor 12 is transmitted to the tool insertion end 3 via at least one pinion 14. For driving the hydraulic motor 12, a second pressure source is provided, with which a hydraulic fluid can be supplied depending on the direction of rotation of the motor in the direction of arrow 16 or 17.

The percussion mechanism 20 has a percussion piston 22 which can be accelerated alternately, in particular up and down, via a return lift surface 24 and a working lifting surface 26. The striking mechanism 20 can be operated by means of a first pressure source, via which the hydraulic fluid can be supplied in the direction of the arrow 18. The first and the second pressure source may, for example, have a hydraulic pump.

The percussion piston 22 is mounted axially displaceably in a cylindrical percussion piston chamber 41 of a housing 40 between a return stroke position and a working stroke position. In the return stroke position, the percussion piston 22 is displaced in the direction opposite to the tool insertion end 3 and can in particular be lifted off the tool insertion end 3. The return stroke position of the percussion piston 22 can also be referred to as a raised position. During the working stroke of the percussion piston 22, however, moved in the direction of the tool insertion end 3 to the so-called impact point.

In a first annular peripheral area around the percussion piston 22, a first pressure chamber 42 is formed which is bounded by the return stroke surface 24. The first pressure chamber 42 is about a first smaller diameter axial region of the Impact piston 22 is formed. The return stroke surface simultaneously forms a first control edge 36.

In a second annular peripheral area around the percussion piston 22, a second pressure chamber 44 is provided, which is bounded by the working surface 26. The second pressure chamber 44 is formed around a second smaller diameter axial region of the percussion piston 22.

In a third annular peripheral area around the percussion piston 22, a switching chamber 43 is provided, which is bounded by two equal sized annular surfaces of Schlagkobens. The switching chamber is formed around a third smaller diameter axial region of the percussion piston 22. The tool insert end 3 facing annular surface forms a second control edge 38th

In the housing 40, a control slide 52 for controlling the direction of movement of the percussion piston 22 is further arranged. The spool 52 is axially displaceably mounted in a first cylinder chamber 51 of the housing 40 and has an axial through-hole 54 and at least one transverse bore 56 which extends radially from the axial through-hole 54. On an outer circumferential surface of the spool 52, a circumferential circumferential groove 58 is formed. Further, the spool 52 has at least one axial switching surface 60 which is formed on a larger diameter axial portion of the spool 52. By a pressure relief of the switching surface 60 of the spool 52 can be moved axially in a first end position and by pressurizing in a second end position. A relief surface 62 is connected via a first relief line 28 to a pressureless environment or a non-pressurized tank. A longitudinal axis 53 of the control slide 52 is parallel to a longitudinal axis 23 of the percussion piston 22 in this embodiment.

A first pressure line 30 is arranged between the first cylinder chamber 51 and the first pressure chamber 42 and connects the first pressure source via the through-bore 54 of the spool 52 to the first pressure chamber 42. The first pressure line 30 may be formed as a bore in the housing 40.

By means of the first pressure source, pressurized hydraulic fluid, for example an oil, can be supplied via the first pressure line 30 to the first pressure chamber 42 become. About the pressurized fluid, the return stroke surface 24 can be acted upon, so that a return stroke force can be exerted on the percussion piston 22 in the direction of the return stroke position of the percussion piston 22.

A second pressure line 31 is arranged between the first cylinder chamber 51 and the second pressure chamber 44 and connects the first pressure source via the transverse bore 56 of the spool 52 with the second pressure chamber 44. The second pressure line 31 may also be formed as a bore in the housing 40. About the pressurized fluid from the first pressure source, the working surface 26 can be acted upon, so that a working stroke force can be exerted on the percussion piston 22 in the direction of the impact point. First and second pressure lines 30, 31 may also be referred to as first and second oil passages.

The percussion mechanism 20 further has a return line 32, which opens on the one hand between the first pressure chamber 42 and second pressure chamber 44 in the percussion piston chamber 41 and on the other hand to a non-pressure environment or a non-pressurized tank (arrow 19) is connected.

Further, a switching line 33 is provided, which connects the percussion piston chamber 41 with the switching surface 60 of the spool 52.

As part of the impact mechanism 20, the impact rotary drilling device 1 has an actuating element 70. The actuator 70 is disposed in the housing 40 of the percussion mechanism 20 and may also be referred to as a second control slide. In principle, it is possible deviating from the illustrated embodiment, the actuator 70 externally, ie outside the housing 40 to arrange.

The actuator 70 is mounted longitudinally displaceable in a second cylinder chamber 69 in the housing 40. The second cylinder chamber 69 is conductively connected to both the first pressure source, the second pressure source and the first pressure chamber 42. The adjusting element 70 has at least one closing region 80, with which the first pressure line 30 can be closed between the first pressure chamber 42 and the first pressure source. The actuator 70 further includes a first opening portion 82 having a smaller diameter than the closing portion 80 to open the first pressure line 30. Furthermore, a second opening area 84 is provided, which likewise has a smaller diameter With the second opening portion 84, a connection between the second pressure source and the first pressure chamber 42 can be opened. Finally, an axial region 86 is provided, which can be designated as a guide region for guiding the adjusting element in the second cylinder chamber 69.

The control element 70 also has three control surfaces 72, 74, 76. A first control surface 72 is connected to the second pressure source and presses the actuator 70 under pressure loading in the direction of the rotational operating position. A second control surface 74 is conductively connected to the first pressure source and urges the actuator 70 toward the impact mode position. The second control surface 74 is connected via a side channel 34 to the first pressure source, in particular via the first pressure line. A third control surface 76 is connected via a second relief line 29 to a non-pressurized tank. The actuator 70 is a substantially rotationally symmetrical body having a longitudinal axis 71 which is aligned transversely to a longitudinal axis of the first pressure channel.

The control element 70 designed as a second control slide is introduced into the first pressure line 30 in order to close and open a connection between the first pressure chamber 42 and the first pressure source. At the same time can be connected to the second pressure source and separated by the actuator 70, the first pressure chamber 42. The second pressure source simultaneously serves to drive the hydraulic motor 12 of the rotary drive 10.

The actuator 70 is actuated by the first and second control surfaces 72, 74, wherein, as shown above, the third control surface 76 is depressurized. Once the striking mechanism 20 is turned on, the actuator 70 is also supplied via the side channel 34 with the working pressure provided by the first pressure source for operation of the percussion mechanism. Since the second control surface 74 is larger than the first control surface 72, the actuating element 70 is always arranged in the impact operating position, even if a pressure is applied to both control surfaces 72, 74. The difference in size of the two control surfaces 72, 74 is dimensioned such that even with significantly greater pressure on the first control surface 72, the actuator 70 is disposed in the impact mode position.

To seal the percussion piston 22 against the housing 40, a plurality of annular sealing elements 46 are provided in the housing 40.

Hereinafter, the impact operation mode of the impact rotary drilling apparatus will be described.

Fig. 1 shows the impact rotary drilling apparatus 1 in the impact operation mode. In this case, the percussion piston 22 is shown at the impact point. The spool 52 is in the first axial end position. In this, the second pressure line 31 is line-connected via the circumferential groove 58 in the spool 52 to the return line 32 and thus connected without pressure. In the first axial end position of the spool 52, the transverse bore 56 is further axially displaced so that the connection of the second pressure line 31 is closed to the first pressure source. The second pressure chamber 44 is thus relieved of pressure and at the working stroke surface 26 of the percussion piston 22 is no pressure.

The first pressure chamber 42 of the percussion piston 22 is in contrast connected via the through-bore 54 of the spool 52 with the first pressure source, so that via the pressure fluid, a force is exerted on the return stroke 24, which presses the percussion piston 22 in the direction of Rückhubstellung. Return stroke surface 24 and first pressure chamber 42 are thus connected to the first pressure source and the return stroke surface 24 is pressure-loaded.

The percussion piston 22 moves under the action of the pressurization of the return surface 24, starting from the in Fig. 1 illustrated impact point up in the return stroke position.

As soon as the first control edge 36 reaches the changeover line 33, the changeover line 33 is connected via the first pressure line 30 and the first pressure chamber 42 to the first pressure source and thus pressurized. This pressure acts on the switching surface 60 of the spool 52 and moves it into the second axial end position.

In the second axial end position of the spool 52, the second pressure chamber 44 is connected via the second pressure line 31 and the transverse bore 56 to the first pressure source and also the connection of the second pressure line 31 is interrupted with the return line 32. Thus, there is at the working surface 26 a Pressure on, due to the larger surface of the working surface 26 relative to the return stroke 24, the percussion piston 22 - against a restoring force - moves back into the working stroke position.

Once the second control edge 38 of the percussion piston 22 reaches the Umschaltleitung 33, it is connected via the switching chamber 43 to the return line 32 and depressurized. As a result, the spool 52 is again moved to the first axial end position. The Schlagwerk 20 now has the in Fig. 1 reached position and the cycle begins again.

In the in Fig. 1 shown position, the actuator 70 is in the impact mode position. The second control surface 74 of the actuating element 70 is acted upon by the pressure from the first pressure source. The first control surface 72 of the actuating element 70 is acted upon via a third pressure line 35 with the pressure of the second pressure source. Since the second control surface 74 is larger than the first control surface 72, the actuator 70 is shifted to the impact operating position.

In this, the first pressure line 30 between the first pressure chamber 42 and the first pressure source is opened by the actuator 70 and the hammer mechanism can work. Further, the connection between the first pressure chamber 42 and the second pressure source is closed. The first opening portion 82 of the actuator 70 is disposed in the first pressure line 30 to open the first pressure line 30. The closing portion 80 closes the connection between the first pressure chamber 42 and the second pressure source.

Hereinafter, the rotation operation mode will be described.

Fig. 2 shows the Schlagdrehbohrvorrichtung 1 in pure rotary operation. Here, the first pressure source is switched off. In the direction of arrow 18 so no pressure is provided. In the direction of arrow 15 further pressure is provided due to the switched-rotary drive, so that the first control surface 72 of the actuating element 70 is acted upon by the third pressure line 35 with pressure. Since no pressure is applied to the second control surface 74 of the actuating element 70, the actuating element 70 is displaced into the rotary operating position due to the pressure applied to the first control surface 72 via the second pressure source. In this case, the control element 70 moves to the first pressure line 30 after a certain way with the closing area 80. simultaneously the third pressure line 35 is conductively connected to a transfer channel 27, which opens into the part of the first pressure line 30 leading to the first pressure chamber 42. The actuator 70 has thus reached its rotational operating position.

In this, the first pressure line 30 is closed between the first pressure chamber 42 and the first pressure source and made a connection between the first pressure chamber 42 and the second pressure source. The connection between the first pressure chamber 42 and the second pressure source via the second opening portion 84 of the actuating element 70th

Since no pressure is applied to the second pressure chamber 44 and the working stroke surface 26 of the percussion piston 22 due to the disconnection of the first pressure source, the percussion piston 22 is moved into the return stroke position by the pressure applied to the first pressure chamber 42 via the second pressure source and, in particular, by the tool insertion end 3 spaced and lifted. At the stop surface between percussion piston 22 and 3 Werkzeuginsteckende now no contact takes place. A friction between these components is thus excluded.

Upon renewed activation of the percussion mechanism 20, the second control surface 74 of the actuating element 70 is pressurized again via the side channel 34, so that the actuating element 70 is adjusted to the impact operating position. In this connection, the connection between the first pressure chamber 42 and the second pressure source is again closed by the closing area 80 of the actuating element 70 and the first pressure line 30 is opened by the first opening area 82 of the actuating element 70.

Claims (11)

Schlagdrehbohrvorrichtung with a rotary drive (10) for rotationally driving a tool insertion end (3), - A hammer mechanism with a percussion piston (22) which in a housing (40) between a first pressure chamber (42) which is bounded by a return stroke surface (24) of the percussion piston (22) and a second pressure chamber (44), which of a working stroke (26) of the percussion piston (22) is limited, is mounted reversibly movable, and - A controlled pressure fluid supply means (50), with which a supply of a pressurized fluid from a first pressure source on the one hand to the first pressure chamber (42) and on the other hand to the second pressure chamber (44) is variably controllable, wherein a reversing movement of the percussion piston (22) with a Working stroke in the direction of the tool insertion end (3) and a return stroke in the opposite direction can be generated, characterized - That an actuating element (70) is provided, which is adjustable between a Schlagbetriebsstellung and a rotational operating position, - In the rotary operating position for spacing the percussion piston (22) from the tool insertion end (3), the first pressure chamber (42) with the return stroke surface (24) is conductively connected to a second pressure source. Rotary rotary drilling apparatus according to claim 1,
characterized,
that the second pressure source is a pressure source for the operation of the rotary drive (10). Rotary rotary drilling apparatus according to claim 1 or 2,
characterized,
that the first pressure chamber (42) is conductively connected to the first pressure source or the second pressure source, and
in that a pressure line between the first pressure chamber (42) and the first pressure source and a pressure line between the first pressure chamber (42) and the second pressure source can be closed by the adjusting element (70), in particular alternately. Rotary rotary drilling apparatus according to claim 3,
characterized,
that with the opening of the pressure line between the first pressure chamber (42) and the second pressure source, the pressure line between the first pressure chamber (42) and the first pressure source is closed and vice versa. Rotary rotary drilling apparatus according to one of claims 1 to 4,
characterized,
in that the adjusting element (70) is designed as a control slide which can be pressurized by the first pressure source and the second pressure source, and in that the actuating element (70) is automatically adjustable into the rotational operating position when the pressure of the first pressure source drops. Impact rotary drilling apparatus according to one of claims 1 to 5,
characterized,
in that the actuating element (70) has at least two control surfaces (72, 74), wherein a first control surface (72) is conductively connected to the second pressure source and a second control surface (74) is connected to the first pressure source. Rotary rotary drilling apparatus according to one of claims 1 to 6,
characterized,
in that the actuating element (70) has a third control surface (76), which is conductively connected to a pressureless environment or to a pressureless tank. Impact rotary drilling apparatus according to one of claims 1 to 7,
characterized,
in that the adjusting element (70) is arranged in the housing (40). Rotary rotary drilling apparatus according to one of claims 1 to 8,
characterized,
that the working stroke surface (26) of the percussion piston (22) is greater than the return stroke surface (24). Rotary rotary drilling apparatus according to one of claims 1 to 9,
characterized,
that the working stroke surface (26) can be acted upon alternately by pressure and without pressure by means of the pressure fluid supply device (50). Method for operating a percussion rotary drilling device, in particular according to one of claims 1 to 10,
in which - The Schlagdrehbohrvorrichtung (1) has a percussion piston (22) which in a housing (40) between a first pressure chamber (42) which is bounded by a Rückhubfläche (24) of the percussion piston (22), and a second pressure chamber (24) which is bounded by a working lifting surface (26) of the percussion piston (22), is mounted to be reversibly movable, - A tool insertion end (3) by means of a rotary drive (10) is driven to rotate and - By means of a controlled pressure fluid supply means (50) a supply of a pressurized fluid from a first pressure source on the one hand to the first pressure chamber (42) and on the other hand to the second pressure chamber (44) is variably controlled, wherein a reversing movement of the percussion piston (22) with a working stroke in Direction of the tool insertion end (3) and a return stroke is generated in the opposite direction,
characterized, - That an actuating element (70) is set in a rotational operating position, - Wherein in the rotational operating position, the first pressure chamber (42) with the return stroke surface (24) is conductively connected to a second pressure source and the percussion piston (22) from the tool insertion end (3) is spaced.

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