EP3192569A1 - Penetration device for penetrating a wall structure - Google Patents

Abstract

In a piercing device (11) for piercing a wall structure, comprising at least one puncturing unit (12), a base body (13), at least one with respect to the base body (13) movable piercing tool (14) and drive means (15) for causing a puncture movement of the puncturing tool (14), the drive means (15) have an electric drive as drive source.

Description

The invention relates to a puncture device for piercing a wall structure, comprising at least one puncture unit, which has a base body, at least one puncture tool movable with respect to the base body, and drive means for causing a puncturing movement of the puncturing tool.

Such puncture devices, which may also be referred to as penetrators, are used in particular in the fire fighting of fires in aircraft interiors. In this case, the piercing device is located at a distal end of a pivotable arm, which in turn is mounted on an airfield fire engine. For firefighting the airfield fire engine moves in the vicinity of the aircraft and the boom with the piercing device is pivoted in the vicinity of the fuselage. Subsequently, a piercing of the fuselage by means of the piercing device, so that the extinguishing medium, which is advantageously supplied via the piercing tool, can get into the interior of the aircraft.

From the EP 1 781 383 B1 a puncturing tool is known, which is arranged at the distal end of a boom of an airfield fire engine and lance-like. A wall structure, in particular aircraft fuselage, is here by the hammering pierced the perforating tool due to the pivotal movement of the boom.

The EP 1 980 294 B1 discloses a firefighting deployment apparatus having a penetrating device which may also be disposed at a distal end of a boom of an airfield fire fighting vehicle. The penetration device has a lancet-like penetrating tool for piercing a wall structure. The penetrating tool is moved hydraulically by means of a hydraulic system.

The EP 1 369 145 B1 discloses a rescue boom having a piercing tool disposed at a distal end that can pierce a wall structure by spring force.

The provision of a hydraulic system for a penetrating tool, as is known from the EP 1 980 294 B1 is known, is complicated and requires the provision of hydraulic medium, whereby there is a need to keep the hydraulic medium always within the hydraulic system, so to prevent the hydraulic medium enters the environment. It is thus a closed and sealed against the environment hydraulic system necessary.

In the spring-based system for driving the penetration tool from the EP 1 369 145 B1 the puncture force is dependent on the spring characteristics of the spring means used. With changing properties of the wall structure to be pierced, for example, change in thickness or material, there is a need for the puncturing force to be changed. This is possible here only in the region of the linear expansion of the spring means.

The object of the invention is therefore to provide a puncture tool of the type mentioned, which is on the one hand compact and on the other hand offers a large variability in the piercing of most diverse wall structures.

This object is achieved by a puncturing tool having the features of independent claim 1. Further developments of the invention are shown in the subclaims.

The piercing tool according to the invention is characterized in that the drive means have an electric drive as drive source.

Such an electric drive is compact in comparison with the hydraulic system used in the prior art as a drive source. Furthermore, the puncture force can be adapted to different properties of the wall structure, for example, different wall thicknesses or different wall materials, by appropriate control or regulation of the electric drive.

In a development of the invention, the electric drive and the puncturing tool are coupled to one another via a transmission device.

In a particularly preferred manner, the transmission device has a spindle which can be driven rotationally by an output movement of the electric drive and a spindle nut which can be moved linearly along the spindle by the spindle rotation, to which the piercing tool is coupled. In this case, the electric drive is thus designed as a spindle drive.

In a particularly preferred manner, the electric drive has a rotatably driven output shaft, which is for transmission the rotational movement connected to the spindle, in particular via a shaft coupling is coupled thereto.

In a further development of the invention, a separate from the spindle guide means for guiding the spindle nut is provided. The guide device is used to absorb shear forces that may occur during the puncture movement of the puncturing tool.

Expediently, the guide device has at least two guide rails, one of which is arranged on one side and the other beyond the spindle on the main body, parallel to the spindle, wherein the spindle nut is guided on the guide rails by means of guide means. The guide means may be, for example, arranged on the spindle nut carriages, which are guided on the associated guide rails.

In a particularly preferred manner, the electric drive is designed as an electric motor. Particularly preferably, a servomotor is provided as the electric motor. Servo motors have the advantage of having at least one position sensor, i. having the determination of the rotational position of the output shaft. Thus, a control of the angular position and the rotational speed and acceleration of the output shaft and thus the coupled spindle is possible. As an alternative to the servo motor and a stepper motor can be used.

As an alternative to the electric motor, the puncturing movement of the puncturing tool can also be produced by means of an electric drive in the form of a particularly electrodynamic linear direct drive.

In a development of the invention, the electric drive can be controlled / regulated by means of a control / regulating unit, wherein preferably the control / regulating unit is located on board the piercing device. The control / regulating unit can be arranged for example on the base body. Alternatively, it is possible to control the electric drive via an external control unit. The signal transmission is expediently wireless.

In a particularly preferred manner, the puncture tool is formed like a lance. Conveniently, the piercing tool has a tip for piercing the wall structure and a shaft which is coupled to the transmission device.

In a particularly preferred manner, the puncturing tool is hollow for the supply of extinguishing medium and has a plurality of outlet openings for the extinguishing medium in the area of the tip. The extinguishing medium is thus supplied via the hollow piercing tool in this case.

In a further development of the invention, the base body is formed as a housing, wherein the electric drive is housed by the housing, wherein preferably the housing has a front end wall, on which the spindle is mounted and which has a passage opening for the piercing tool.

Particularly preferably, an extinguishing medium supply device is provided with respect to which the puncturing tool is movably guided in such a way that the supply of extinguishing medium to the puncturing tool is made possible irrespective of the position of the puncturing tool for the extinguishing medium supply device. Expediently, the extinguishing medium supply device has a feed tube, on which the shaft of the puncturing tool is mounted telescopically.

In a further development of the invention, the piercing device comprises a boom, via which it can be moved to the wall structure to be pushed through. The boom is suitably arranged on an emergency vehicle, in particular fire engine.

Finally, the invention also includes an emergency vehicle, in particular a fire engine, characterized by a puncture device according to one of claims 1 to 15.

Figur 1

eine perspektivische Darstellung eines bevorzugten Ausführungsbeispiels der erfindungsgemäßen Durchstoßvorrichtung ohne Seitenwände des Gehäuses,

Figur 2

eine Seitenansicht auf die Durchstoßvorrichtung von Figur 1 und

Figur 3

eine Stirnansicht auf die Durchstoßvorrichtung von Figur 1.

A preferred embodiment of the invention is illustrated in the drawing and will be explained in more detail below. In the drawing show:

FIG. 1

a perspective view of a preferred embodiment of the piercing device according to the invention without side walls of the housing,

FIG. 2

a side view of the piercing device of FIG. 1 and

FIG. 3

an end view of the piercing device of FIG. 1 ,

The FIGS. 1 to 3 show a preferred embodiment of the puncture device according to the invention 11. The puncture device 11 comprises a puncture unit, which at a distal end of a cantilever (not shown) arranged, in turn, in particular on the roof of an emergency vehicle, preferably airfield fire engine, arranged is. The boom is pivotable in all three spatial directions and consists of several pivotally interconnected boom parts, at the distal or free end of the puncture unit 12 is located.

The puncture device 11 is used to puncture a wall structure, in particular the hull or the shell of an aircraft, which has caught fire inside. There is therefore a need to be able to carry out the piercing of the wall structure precisely and quickly in order to be able to bring through the resulting hole hole medium into the interior of the aircraft. The puncturing device 11 has at least one puncture unit 12, which has a base body 13 and at least one push-through tool 14 movable relative to the base body 13 and drive means 15 for causing a puncturing movement of the puncture tool 14.

As in particular in FIG. 1 illustrated, the base body 13 is formed as a housing, which is shown in the example as a cuboid body. The housing has two mutually parallel longitudinal walls, which are not shown in the drawing. The front end of the housing form a front end wall 18 and a rear end wall 19. At the front end wall 18 is a particular circular passage opening 20, which is penetrated by the piercing tool 14.

Overall, the two longitudinal walls, the bottom wall 16, the ceiling wall 17, the front end wall 18 and the rear end wall 19 define a housing interior 21.

As in particular in FIG. 2 shown, the drive means 15 as a drive source to an electric drive 22 which is located in the housing interior 21 of the housing and is housed by the housing, whereby it is protected from smoke, dirt and possibly extinguishing medium. The electric drive 22 is formed in the example shown as an electric motor in the form of a servo motor. The electric drive 22 is coupled to the piercing tool 14 via a transmission device 23.

The transmission device 23 has a spindle 24, which can be driven in rotation by an output movement of the electric drive 22, and a spindle nut 25, which can be moved linearly along the spindle 24 by the spindle rotation, to which the piercing tool 14 is coupled. Spindle 24 and spindle nut 25 may together form a Wälzschraubtrieb, in particular form a ball screw when using balls as rolling elements.

The spindle 24 in turn is coupled to a rotatably driven output shaft 26 of the electric motor, whereby the rotational output movement of the output shaft 26 is transmitted in a rotational movement of the spindle 24. Spindle 24 and output shaft 26 are arranged coaxially with each other, wherein the spindle 24 is connected via a shaft coupling 27 to the output shaft 26.

As in particular in FIG. 1 shown, is located in the housing interior of the housing a transverse to the longitudinal extent of the spindle 24 extending bearing wall 28 to which the spindle 24 by means of a bearing, in particular rolling bearing, is rotatably mounted. Below the bearing is located on the bearing wall 28 is still a window-like opening 29th

As in particular in FIG. 2 shown, the spindle 24 is rotatably mounted in addition to the bearing on the bearing wall 28 on the front end wall 18. Here is also a camp, such as bearings, provided.

As in particular in FIG. 1 shown, the piercing device 11 has a separate from the spindle 24 guide means 30 for guiding the spindle nut 25. The separate guide means 30 serves to receive acting on the spindle nut 25 transverse forces. In the example shown, the guide device 30 has two mutually parallel aligned, opposite guide rails 31a, 31b, of which the upper guide rail 31a on the underside of the top wall 17 and the lower guide rail 31b are arranged on the top of the bottom wall 16. The spindle nut 25 has on its upper side facing the top wall 17 an upper slide 32a and on its bottom wall 16 facing lower side a lower slide 32b. The upper carriage 32a is mounted linearly movable on the upper guide rail 31a and the lower carriage 32b on the lower guide rail 31b.

An important element of the spindle nut 25 is a cam portion 33 which is connected to the piercing tool 14, whereby the linear movement of the spindle nut 25 along the spindle 24 is transmitted to the piercing tool 14. In the example shown, the driver portion 33 has a cylindrical channel 34, in which a subsequently described in more detail component of the piercing tool 14 relative to the spindle nut 25 is rotatably received.

The core of the piercing device 11 is the piercing tool 14. In the example shown, the piercing tool 14 lance-like and could therefore be referred to as puncture lance. The piercing tool 14 has a tip 35 for piercing the wall structure and a shaft 36 which is coupled to the gear device 23. The piercing tool 14 is hollow overall, with which the supply of extinguishing medium, for example water or water / foam mixtures, is made possible via the piercing tool 14.

In the wall of the tip 35 a plurality of outlet openings 37, in particular distributed over the circumference, are provided, via which the extinguishing medium supplied via the hollow shaft 36 can exit. Appropriately, several rows of such outlet openings 37 are provided in the axial direction one behind the other. The outlet openings 37 are designed as nozzle openings so that the escaping extinguishing medium is sprayed on all sides, whereby the fire can be effectively combated.

As in particular in FIG. 2 shown, the shaft 36 is received in the cylindrical channel 34 of the driving portion 33 of the spindle nut 25.

As further in FIG. 2 illustrated, the piercing device 11 has an extinguishing medium supply means 38, via which the piercing tool 14 extinguishing medium is supplied. The extinguishing medium supply device 38 has a hollow base part 39, which is arranged in the example shown below the electric motor coaxial with the piercing tool 14. The base part 39 has on its lateral surface a tubular connecting piece 40, which opens on the one hand into the cavity of the base part 39, which projects beyond the bottom wall 17 of the housing to the outside. The tubular nozzle 40 serves as a connection for supplied extinguishing medium.

To the base part 39, a feed pipe 41 is attached, on which the shaft 36 of the piercing tool 14 is mounted telescopically. Between the inner wall of the hollow shaft 36 of the piercing tool 14 and the outer wall of the feed tube 41, a seal is provided.

As in particular in FIG. 1 shown, the feed tube 41 protrudes through the window-like opening 29 of the end wall 28 therethrough.

As in particular in FIG. 1 shown, the electric motor is controlled or regulated by means of a control / regulating unit 42. The control unit 42 is as a compact block on board the piercing device 11 and is located in particular at the top of the ceiling wall 17. In the case of an electric motor designed as a servomotor, the control / regulating unit 42 is designed as a servo controller. In this case, there is a monitoring of the rotational position of the output shaft 26 and possibly readjustment of their rotational speed, whereby the speed of the puncture movement can be varied. The control unit 42 is designed so that it can receive higher-level control commands, for example wirelessly. The control commands can be transmitted to the control / regulating unit 42, for example, by a control console arranged in the driver's cab of the airfield fire fighting vehicle.

As in particular in FIG. 1 illustrated, the piercing device 11 may be provided with a trigger fuse 43. The trigger fuse 43 is formed in the example shown as a kind of ring cage, which is attached to the front end wall 18. The ring cage has a ring 44 which defines an annular surface 45 oriented transversely to the piercing direction. Conveniently, the tip 35 of the piercing tool 14 is withdrawn in the non-use state behind the annular surface 45.

It is possible that 44 triggering elements, such as trigger sensors are arranged on the front of the ring, which trigger the puncture movement of the puncturing tool 14 on contact with the piercing wall structure.

To fire-fighting a fire in the interior of an aircraft, the airfield fire engine first moves in the vicinity of the affected aircraft. Thereafter, the boom is pivoted in the vicinity of the fuselage. If necessary, then the ring 44 of the piercing device 11 is attached to the outside of the fuselage, so that a puncture movement is triggered.

To initiate the puncturing movement, the output shaft 26 of the electric motor is set in rotational motion, which is transmitted in a rotational movement of the coupled spindle 24. As a result, the spindle nut 25 mounted in a linearly movable manner on the spindle 24 is displaced forwards away from the electric motor. About the driver portion 33 of the spindle nut 25 which is aligned parallel to the spindle 24 piercing tool 14 is coupled. The movement of the spindle nut 25 thus causes movement of the piercing tool 14 to the front, whereby the tip 35 of the piercing tool 14 moves beyond the annular surface 45 of the ring 44, so that the front of the tip 35, which is optionally provided with a hard metal coating, in the Wall structure of the aircraft fuselage penetrates and pierces a hole. The tip 35 of the puncturing tool 14 is displaced so far into the interior of the aircraft that all the outlet openings 37 are located inside the aircraft, so that supplied extinguishing medium in the form of a particular hemispherical spray pattern is sprayed into the interior of the aircraft. By changing the direction of rotation of the output shaft 26, the puncture tool 14 can be moved back again.

Claims (15)

Puncturing device for piercing a wall structure, comprising at least one puncturing unit (12) having a base body (13), at least one puncture tool (14) movable relative to the base body (13) and drive means (15) for causing puncturing motion of the puncture tool (14); characterized in that the drive means (15) have an electric drive as the drive source. Punching device according to claim 1, characterized in that the electric drive and the piercing tool (14) via a transmission device (23) are coupled together. Punching device according to claim 1 or 2, characterized in that the transmission device (23) has a rotationally drivable by a driven movement of the electric drive spindle (24) and a spindle by the spindle rotation linearly along the spindle (24) movable spindle nut (25) to which the Punching tool (14) is coupled. Punching device according to claim 3, characterized in that the electric drive has a rotatably driven output shaft (26) which is connected to transmit the rotational movement with the spindle (24), in particular by means of a shaft coupling (27) with the spindle (24) coupled. Punching device according to one of claims 3 or 4, characterized in that one of the spindle (24) separate guide means (30) for guiding the spindle nut (25) is provided, wherein preferably the guide means (30) at least two guide rails (31a, 31b) of which one on this side and the other beyond the spindle (24) on the base body (13), aligned parallel to the spindle (24) are arranged, wherein the spindle nut (25) guided by guide means on the guide rails (31a, 31b) is. Punching device according to one of the preceding claims, characterized in that the electric drive as an electric motor, in particular servomotor, is formed. Punching device according to one of claims 1 to 5, characterized in that the electric drive is designed as a particular electrodynamic linear direct drive. Breakthrough device according to one of the preceding claims, characterized in that the electric drive by means of a control / regulating unit (42) is controlled / regulated, wherein preferably the control / regulating unit (42) on board the piercing device (11), in particular on the main body (13) is arranged. Punching device according to one of the preceding claims, characterized in that the piercing tool (14) is lancet-shaped, wherein preferably the piercing tool (14) has a tip (35) for piercing the wall structure and a shaft (36) which is coupled to the transmission device (23). Piercing device according to claim 9, characterized in that the piercing tool (14) is hollow, for supplying extinguishing medium and in the region of the tip (35) a plurality of outlet openings (37) are formed for the extinguishing medium. Punching device according to one of claims 3 to 10, characterized in that the base body (13) is designed as a housing, wherein the electric drive is housed by the housing, wherein preferably the housing has a front end wall (18) on which the spindle (24) is mounted and having a through hole (20) for the piercing tool (14). Puncturing device according to one of the preceding claims, characterized by an extinguishing medium supply device (38), with respect to which the puncture tool (14) is movably guided such that regardless of the position of the puncturing tool (14) to extinguishing medium supply means (38) the supply of extinguishing medium to piercing tool (14) is possible. Punching device according to claim 12, characterized in that the extinguishing medium supply means (38) comprises a feed tube (41) on which the shaft (36) of the piercing tool (14) is telescopically mounted. Punching device according to one of the preceding claims, characterized by a boom, by means of which it can be moved up to the wall structure to be pierced. Emergency vehicle, in particular fire engine, characterized by a puncture device (11) according to one of claims 1 to 14.

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