WO2008080856A1 - Modular unit for an avalanche probe, and avalanche probe - Google Patents

Abstract

The present invention relates to a modular unit (10) for an avalanche probe (14), wherein the modular unit (10) has: at least one antenna (46); a receiver device (48) which is coupled to the at least one antenna (46) in order to provide a receiving signal; a processing device (50) for processing the receiving signal and for providing an activation signal; an output device for receiving the activation signal and for outputting an output signal (54); a region (30) for receiving a current supply device for at least the receiver device (48) and the processing device (50); and a first connecting device (36) for coupling the modular unit (10) to the lower end of an avalanche probe (14). It relates furthermore to an avalanche probe in which the at least one antenna, the receiver device, the processing device, the output device and a region for receiving a current supply device are arranged in the lower third of the avalanche probe.

Description

 International patent application

Modular unit for an avalanche probe and avalanche probe

DESCRIPTION:

The present invention relates to a modular unit for an avalanche probe. It also concerns a corresponding avalanche probe.

In the usual, known from the prior art approach to salvage a buried in an avalanche, two different search systems are used sequentially in time: On the one hand a spill detector, as for example from DE 195 10 875 C1, DE 30 46 895 A1, the DE 197 52 939 C1 or DE 35 31 726 A1 is known. This is a portable locator that has a transceiver that transmits and receives at the internationally fixed frequency of 457kHz. Such a device carries both the buried and the search for the victim. The closer the seeker comes to the victim, the louder the noise that the searcher's spy-searching device makes. Alternatively or additionally, a corresponding optical output can be provided.

The problem is that, depending on the depth at which the victim is buried, the reception level within a certain area on the surface of the avalanche on which the searcher stands, corresponding to the transmission cone, is approximately the same. At a burial depth of 3 m, for example, a cone with a diameter of 3 m, corresponding to an area of more than 7 m ² , within which no differences in volume can be perceived. Would attempting to remove the volume of more than 21 m ^{3 of} compressed snow and ice would require a period of time which would be detrimental to a positive outcome of the recovery. Therefore, in the prior art, after such confinement of the area where

5 teten suspected, so-called avalanche probes used. A particularly preferred avalanche probe, which is characterized in that it consists of several probe parts, which can be assembled by means of a connecting cable almost in no time to form the avalanche probe, is known from DE 37 29 058 A1. Such a training allows every ski tour operator an avalanche probe in

0 can carry his backpack with him and that this is within a very short time, without time-consuming screwing together of the probe parts, ready for use.

Another avalanche probe is known from DE 100 30 719 A1, in which an antenna is provided at the tip, which is connected via an RF line to a receiver 5, which is connected in a variant fixed to the upper part of the avalanche probe. To search for spilled persons, the probe with the antenna is driven ahead into the snow.

A problem with the avalanche probe according to DE 100 30 719 A1 is that its use in collapsible avalanche probes, as described, for example, in DE 37 29 058 A1, makes it impossible due to the HF line used. It therefore allows only one use in which one-piece avalanche probes are flown in, for example by helicopter or in which an avalanche probe is constructed by screwed items, with the threading: 5 of the RF line through the interior of the probe parts, especially in a state of great excitement, extremely undesirable is.

The object of the present invention is therefore to provide a modular unit for an avalanche probe and an avalanche probe, which allows an improved, in particular faster recovery, than has hitherto been possible with the known collapsible avalanche probes. This object is achieved by a modular unit for an avalanche probe having the features of patent claim 1 and by an avalanche probe having the features of patent claim 10.

The present invention is based on the finding that a collapsible avalanche probe according to DE 37 29 058 A1 can be improved without having the disadvantages according to the avalanche probe of DE 100 30 719 A1 if, on the one hand, a modular unit is formed comprising at least one antenna, a receiver device coupled to the at least one antenna for providing a receive signal, a processing device for processing the receive signal and providing a drive signal, an output device for receiving the drive signal and outputting an output signal, a region for receiving a power supply device for at least the receiver device and the processing device further comprises a first connection device for coupling the modular unit to the lower end of an avalanche probe.

By providing the dispenser in the modular unit which is to be coupled to the lower end of an avalanche probe, for example by a screw or a bayonet lock, the possibility is opened of wireless transmission from below to the person operating the avalanche probe. to enable. This wireless transmission can be done, for example, by the output device comprising at least one loudspeaker. This allows the desired signal to be transmitted by structure-borne noise from the avalanche probe end under the snow to the portion of the probe tip above the snow. This is facilitated by the fact that the probe parts of the avalanche probe are hollow and preferably made of plastic, Kevlar or aluminum.

It can also consist in that the output device comprises a transmitting device whose transmission frequency is not equal to 457 kHz, in particular in the UHF range. Thus, the possibility is given, for example, to provide a corresponding receiver in the handpiece of the probe device, which receiver is set to the signal emitted by the transmitting device of the modular unit. This recommendation The start signal can then be converted into an acoustic, optical or, for example, a vibration signal.

While the invention is preferably to be seen in providing a modular unit which can be coupled to a conventional avalanche probe for realizing the success of the invention, it is of course also possible to design an avalanche probe appropriately without using a modular unit. d. H. to arrange the at least one antenna, the receiver device, the processing device, the output device and the area for receiving a power supply device in the lower third of the avalanche probe. It is particularly preferably arranged in the last and / or penultimate probe part of such an avalanche probe when it is designed as a collapsible avalanche probe, wherein the avalanche probe may be composed, for example, of a plurality of screwable probe parts.

The preferred embodiments mentioned with respect to the modular unit and their advantages therefore apply correspondingly to an avalanche probe according to the invention and are therefore not repeated.

A particularly preferred embodiment of a modular unit according to the invention further comprises a second connection device for coupling the modular unit to a probe tip. Particularly preferably, the second connection device and the area for accommodating a power supply device are designed such that, when the probe tip is not connected to the second connection device, at least one power supply device can be introduced in the area for receiving a power supply device. As a result, no additional opening must be provided, which would require additional effort for a seal or during manufacture.

It is also particularly preferred if the second connection device is designed in such a way that an electrical contact with a pole of at least one power supply device introduced into the region for receiving a power supply device is produced by a probe tip connected to the second connection device. To realize this reliably, a contact spring be provided, which biases the batteries against the probe tip. In other words, by unscrewing the probe tip, batteries can be inserted into the modular unit. By screwing on the probe tip, the circuit is closed and at least the receiver device and the processing device are powered from the batteries.

In a preferred embodiment, a modular unit according to the invention is constructed in two parts, a first part comprising the area for receiving a power supply device, and a second part comprising the at least one antenna, the receiver device, the processing device, the output device and the first connection device. In a preferred development it is provided that the first and the second part are designed in such a way that at least one power supply device connected to the region for receiving a power supply device and a probe tip connected to the second connection device connect at least one third to the second part Connecting device at least the receiver device is activated. Accordingly, as long as the two parts of a modular unit according to the invention are not yet assembled, the receiver device is not yet activated, a power consumption does not take place. Only when the two parts for activation, d. H. in case of emergency, power is taken out of the battery.

A second aspect of the present invention relates to the following aspect: In the prior art, for example when using the avalanche probe known from DE 100 30 719 A1, the volume or the pitch increases as the burglar searcher of the victim becomes increasingly closer. However, between the insertion of the avalanche probe at a first position, the subsequent removal from that position, and insertion at a second position, time periods on the order of more than 30 seconds pass. This means for the operator to remember the previous volume or pitch for at least 30 seconds in order to determine if the avalanche probe is now closer to the victim's burial device at the position it was last buried or not. This is hardly possible in the hectic and panic that accompanies such an emergency. It therefore leads to a delay of salvage, which can cost lives. Moreover, in the cited prior art, a sound is already emitted, even if the antenna still has a greater distance to the actual location of the victim. If one encounters therefore with the probe tip to a resistance, it could be the victim. However, it could also be, and experience has shown that this is much greater, an avalanche-torn branch, ice, a torn backpack or ski, and the like. Already a wrong excavation with a burial depth of 3 m costs so much time that a buried person may not experience a second excavation attempt. The second aspect of the present invention aims to improve this malady, ie to increase the likelihood of a successful trenching attempt.

Therefore, according to the second aspect of the present invention, there is provided a modular unit or avalanche probe comprising at least one antenna, a receiver device coupled to the at least one antenna for providing a reception signal, a processing device for processing the reception signal, and providing a drive signal; an output device for receiving the drive signal and for outputting an output signal and a region for accommodating a power supply device for at least the receiver device and the processing device, such that the processing device is designed, below a predefinable threshold, a first drive signal and above the predeterminable threshold, a second one Output drive signal. By means of this binary evaluation it can be provided, for example, that at a distance of more than 30 or 50 cm from the transmission source a drive signal is output, which does not lead to an output of an output signal through the output device. As soon as the antenna approaches the transmitter to less than 30 or 50 cm, a second drive signal is output, which now leads to an output of an output signal through the output device. In other words, if one removes more than the predefinable threshold from the transmission source with the antenna, no acoustic signal is output, while when the threshold falls below the output device emits a sound. Of course, provided based on this principle will be that two different tones are generated, depending on whether the antenna is above or below the threshold distance.

Compared to the avalanche probe known from DE 100 30 719 A1, it is now possible to say with very high probability when an acoustic signal is emitted that the buried person has been found to be at least a very limited distance from the probe tip. The number of futile trench attempts is minimized, the reliability of the system is significantly increased by not requiring any pitch or volume memory of the rescuer.

According to a third aspect, the present invention relates to a modular unit or avalanche probe having at least one antenna, a first receiver device coupled to the at least one antenna for providing a received signal, a processing device for processing the received signal and providing a drive signal, an output device for receiving the drive signal and for outputting an output signal, a region for receiving a power supply device for at least the receiver device and the processing device, wherein the output device comprises a first transmission device whose transmission frequency is not equal to 457 kHz, in particular in the UHF range.

Accordingly, if a loudspeaker or vibration device that would transmit a signal through the serial sequence of the individual probe parts to the operator is not used as the output device arranged in the modular unit, then, unlike in DE 100 30 719 A1, a collapsible avalanche probe can be used when the signal used by the receiver device - after passing through the processing device - is forwarded using a first transmitting device. It is of course clear that this transmission frequency must be different from the above-mentioned, internationally agreed frequency of 457 kHz. Therefore, the first transmitting device preferably transmits in the UHF range. The second receiver device which is correlated with this first transmission device can be accommodated or arranged, for example, in the handpiece of the avalanche probe, the second receiver device being designed to act on the sensor element. Defrequenz the first transmitting device to receive. Of course, the second receiver device or an additional receiver device may also be arranged outside an avalanche probe, for example in a control console which is designed to receive the transmission signals of various such avalanche probes, for example to coordinate the recovery by a central station. Such a control panel can be designed to be portable and carried in the salvage on the ground or in the air, for example in a helicopter. Thus, this aspect of the invention in this particular application opens up the possibility of attaching a modular unit or avalanche probe according to the invention to the outside of a helicopter, wherein the receiver device is arranged in the helicopter, for example on an operating unit. This eliminates the laying of a cable from the modular unit or avalanche probe, which is located outside the helicopter cockpit, in the pulpit to the control unit, which has repeatedly led to unwanted disturbances in the prior art. The installation cost for such an arrangement is virtually reduced to zero.

Such a modular unit or avalanche probe may comprise a further receiver device according to a preferred embodiment. If, as in the modular unit or avalanche probe according to the second aspect of the invention, the processing device is designed to output a first drive signal below a predefinable threshold and a second drive signal above the predefinable threshold, the further receiver device can now be designed to transmit the transmit signal second transmitting device, which is not arranged in the modular unit or the avalanche probe. Particularly preferably, the modular unit or the avalanche probe is then designed to vary the predefinable threshold to the signal received by the further receiver device. Thus, with regard to the knowledge gained in the meantime, for example, the moisture content of the snow, the predefinable threshold and thus the sensitivity can be adjusted. Namely, depending on the wetness of the snow, one and the same threshold based on an electromagnetic field strength signal results in a variation of 20 to 30% in view of the resultant distance. Thus, for example, in the example given above, in which the modular unit or avalanche probe is arranged outside a helicopter cockpit, the predefinable threshold of a person sitting in the cockpit Person varies during the flight and thus adapted to the given conditions. A stopover or retrieval of the modular unit or avalanche probe to make the corresponding variation can be dispensed with. This results in a considerable saving of time and a reduction of the risk associated with the 5 variation of the predefinable threshold.

It should be understood that the three different aspects of the present invention may be implemented in different embodiments, respectively. However, two or three of these aspects may be realized in one embodiment. This also applies with reference to the particular preferred embodiments mentioned and their advantages.

Further preferred embodiments emerge from the subclaims.

In the following, embodiments of the invention will now be described in detail with reference to the accompanying drawings. Show it:

Fig. 1 in a schematic representation of a modular unit according to the invention in

Use in the recovery of a buried person; : 0

2a shows a collapsible avalanche probe, to which a modular

Unit is coupled;

2b shows an external view of a modular unit according to the invention; : 5

Fig. 2c is a partially sectioned view of a modular unit according to the invention with the probe tip removed;

3a is a schematic cross-sectional view of a modular unit according to the invention according to a second embodiment;

FIG. 3b shows the left part of the modular unit according to the invention shown in FIG. 3a; FIG. FIG. 3c shows the right-hand part of the modular unit according to the invention shown in FIG. 3a; FIG.

4 shows a block diagram of the construction of a modular unit according to the invention; and

Fig. 5 shows a third embodiment of a modular unit according to the invention in a typical application situation.

FIG. 1 shows a schematic representation of the use of a modular unit 10 according to the invention in a typical salvage situation. In this case, a mountain transmitter 12 uses a collapsible avalanche probe 14, as is known, for example, from DE 37 29 058 A1, in which the individual probe parts are joined to the avalanche probe 14 by pulling on a wire cable 16 guided in the probe parts.

5 adds. From this avalanche probe 14, the probe tip 18 is removed and coupled in their place the modular unit according to the invention. The probe tip 18 is now coupled to the other end of the modular unit 10. A spill 20 is buried under a blanket of snow 22 carrying an avalanche transceiver 24 transmitting at a frequency of 457 kHz. As soon as

When the antenna arranged in the modular unit 10 approaches the sputtering searcher 24 more closely than a predefinable threshold 26, which can be, for example, 30 to 50 cm, a sound signal is generated via a loudspeaker arranged in the modular unit 10 Structure-borne sound is transferred to the hand part 28 of the avalanche probe 14 and from there - as by the corresponding

: 5 sound waves 29 marked - is perceived as an acoustic signal from the Bergenden 12. As long as the antenna of the modular unit 10 is outside the predeterminable threshold 26, no acoustic signal is output to the mountain ends 12.

FIG. 2 a shows the avalanche probe 14 from FIG. 1 to which the modular unit 10 according to the invention is coupled. The modular unit 10 is shown in more detail in Figures 2b and 2c. First, Fig. 2b shows the two-piece structure of the modular unit 10. It comprises a first part 30, which is connected via a connecting device 32 with a second part 34. On the first part 30 is coupled via a connecting device 38, the probe tip 18. The second part 34 has a connecting device 36, by means of which it can be mounted on the lower end of the avalanche probe 14.

Fig. 2c is a partial cross-sectional view of Fig. 2b with the probe tip 18 uncoupled from the first part 30 by loosening the connecting device 38. Recognizable is a sealing ring 40 and a contact spring 42 which is arranged to engage against the negative pole of the left, which presses in the first part 30 arranged batteries 44 so as to make an electrical contact. The

In addition, the probe tip 18 allows replacement of the batteries 44. The second portion 34 of the modular unit 10 includes an antenna 46 and a receiver device 48 coupled to the antenna 46 for providing a receive signal. This antenna 46 may also consist of several antennas in order to achieve the most uniform directional sensitivity possible.

5 A processing device 50 arranged on a circuit board is used to process the received signal and to provide a drive signal. Moreover, an output device, in the present case a loudspeaker, is provided which outputs a corresponding output signal after the reception of the drive signal. In the present case, the loudspeaker 52 outputs an acoustic signal 54, which is a structure-borne noise

0 is transmitted to the handle 28 of the avalanche probe 14. Cables 56, 58 ensure that the receiver device 48 and the processing device 50 are electrically connected to the batteries 44. It should be noted that the first part 30 and the second part 34 are designed such that when inserted in the first part 30 batteries 44 and mounted probe tip when connecting the first

With the second part 34, the receiver device 48 and the processing device 50 are activated.

In the description of the further exemplary embodiments of the invention shown in the following figures, the reference signs inserted in connection with FIGS. 1 and 2 are used, as far as identical or similar elements are concerned. They are therefore not mentioned again.

3 shows a second exemplary embodiment of a modular unit 10 according to the invention. FIG. 3 a shows the two parts 30, 34 in the assembled state, while Fig. 3b represent the first part 30 and Fig. 3c, the second part 34 in the released state.

Accordingly, FIG. 3 a shows the part 30 to which the probe tip 18 is attached at one end via a first connecting device 38 and the second part 34 at a second end via a second connecting device 32. The part 30 comprises a tube 60, the part 34 a tube 62. The first part 30 comprises an insulating piece 64 which isolates the positive contact and the negative contact with the batteries 44 from each other. Referring to FIG. 3c, the second part 34 has a positive contact 66 which is electrically isolated from the negative contact 69 by another insulator 68. The connecting device 36 serves for coupling to the lower end of an avalanche probe 14 and can be designed, for example, as a screw thread or bayonet closure or the like.

As will be apparent to those skilled in the art, if at least one of the metal tubes 60, 62 is formed, it may also be used as a negative pole. The outer diameter of the tubes 60, 62 is preferably 10 to 20 mm, so that the snow of an avalanche can be penetrated as easily as possible with sufficient stability of the avalanche probe. As is apparent from Fig. 3, after the joining of the first 30 and the second part 34, the circuit is closed, the receiver device and the processing device are energized.

4 shows a block diagram of the interconnection of the electronic components which are arranged in the second part 34. First, the antenna 46 can be seen, followed by an amplifier 70, which usually comprises filtering for suppressing interference signals. It further comprises a comparator 72, which compares the received signal with a set predefinable threshold. This threshold is provided by a threshold 74, with the threshold 74 having an interface 76 over which this threshold may optionally be varied. As soon as the predetermined threshold is exceeded, a tone generator 78 is activated, which activates the loudspeaker 52, so that an acoustic signal is transmitted into the tube of the modular unit and from there into the tube of the avalanche probe 14. Optionally or alternatively, an optical signal output 80 may be provided. Furthermore, optional or alternative a transmitting device 82 may be provided which comprises a transmitting antenna 84, wherein the transmitting frequency of this transmitting device 82 is not 457 kHz, but is preferably in the UHF range. The transmitting device 82 transmits to a receiving device 86, which comprises a receiving antenna 88 and, for example, in FIG

5 hand part of the avalanche probe may be arranged, but also in a control panel of a rescue center or a helicopter. An acoustic, optical or vibration-based signal converter unit can be connected to this receiver device 86. In another embodiment, not shown, the processing is done without comparator 72 and threshold 74 under continuous

0 processing of the signal received by the antenna 46, .h. At least one of the output devices 78, 80, 82 transmits a signal that is proportional to the signal received by the antenna 46.

5 shows a typical application situation of a further embodiment 5 of a modular unit 10 according to the invention. It is mounted outside a helicopter 90 for this purpose and has the first receiver device 48, the first transmission device 82 and, in addition, a further receiver device 92 which is designed receive a transmission signal of a rescue center 94. The modular unit 10 is designed in this exemplary embodiment to vary the predefinable threshold via the interface 76, see FIG. 4, to the signal received by the further receiver device 92. In the embodiment of FIG. 5, a first one of the receiver devices 86 is arranged in the cockpit of the helicopter 90, a second one in the rescue center 94.

It should be pointed out that all exemplary embodiments of a modular unit according to the invention can be realized in an avalanche probe, so that correspondingly designed avalanche probes are also the subject of the present invention.

Claims

 International patent application

Modular unit for an avalanche probe and avalanche probe

CLAIMS:

A modular unit (10) for an avalanche probe (14), characterized in that the modular unit (10) comprises:

- At least one antenna (46);

a receiver device (48) coupled to the at least one antenna (46): 5 for providing a received signal;

- A processing device (50) for processing the received signal and for providing a drive signal;

- An output device for receiving the drive signal and for outputting an output signal (54);

0 - a region (30) for receiving a power supply device (44) for at least the receiver device (48) and the processing device (50); and

- A first connecting device (36) for coupling the modular unit (10) with the lower end of an avalanche probe (14).

■ 5

Modular unit (10) according to claim 1, characterized in that it further comprises a second connection device (38) for coupling the modular unit (10) to a probe tip (18).

3. Modular unit (10) according to claim 2, characterized in that the second connecting device (38) and the area (30) for receiving a power supply device (44) are designed such that when not connected to the second connecting device (38) probe tip (18) at least one power supply device (44) in the region (30) for receiving a power supply device can be introduced.

4. Modular unit (10) according to any one of claims 2 or 3, characterized in that the second connecting device (38) is designed such that by a with the second connecting device (38) connected to the probe tip (18) has an electrical contact with a pole at least one power supply device (44) introduced into the area (30) for receiving a power supply device is produced.

5. Modular unit (10) according to one of the preceding claims, characterized in that the output device comprises at least one loudspeaker (52).

6. Modular unit (10) according to any one of the preceding claims, characterized in that the output device comprises a transmitting device (82) whose transmission frequency is not equal to 457 kHz, in particular in the UHF range.

7. Modular unit (10) according to any one of the preceding claims, characterized in that it is constructed in two parts, wherein a first part (30) comprises the region (30) for receiving a power supply device, wherein a second part (34), the at least one Antenna (46), the receiver device (48), the processing device (50), the output device and the first connection device (36).

8. Modular unit (10) according to claim 7, characterized in that the first (30) and the second part (34) are designed such that at least one in the region (30) for receiving a power supply device introduced power supply device and with the second connection device (38) connected probe tip (18) when connecting the first (30) to the second part (34) via at least one third connection device (32) at least the receiver device (48) is activated.

9. Modular unit (10) according to any one of the preceding claims, characterized in that the processing device (50) is designed to output below a predetermined threshold (26), a first drive signal and above the predetermined threshold (26), a second drive signal.

10. avalanche probe (14) with

- At least one antenna (46);

a receiver device (48) coupled to the at least one antenna (46) for providing a receive signal;

- A processing device for processing the received signal and for providing a drive signal;

- An output device for receiving the drive signal and for outputting an output signal (54); and

- a region (30) for receiving a power supply device (44) for at least the receiver device (48) and the processing device (50); characterized in that the at least one antenna (46), the receiver device (48), the processing device (50), the output device and the area (30) for receiving a power supply device are arranged in the lower third of the avalanche probe (14).

11. Modular unit (10) or avalanche probe (14) with

- At least one antenna (46); a receiver device (48) coupled to the at least one antenna (46) for providing a receive signal;

- A processing device (50) for processing the received signal (54) and for providing a drive signal;

5 - an output device for receiving the drive signal and outputting an output signal (54); and

- a region (30) for receiving a power supply device (44) for at least the receiver device (48) and the processing device (50);

0, characterized in that the processing device (50) is designed to output a first drive signal below a presettable threshold (26) and a second drive signal above the predefinable threshold (26).

5 12. Modular unit (10) or avalanche probe (14) with

- At least one antenna (46);

- a first receiver device (48) coupled to the at least one antenna (46) for providing a received signal;

- a processing device (50) for processing the received signal: 0 (54) and for providing a drive signal;

- An output device for receiving the drive signal and for outputting an output signal (54); and

a region (30) for receiving a power supply device for at least the first receiver device (48) and the processing device

: 5 (50); characterized in that the output device comprises a first transmitting device (82) whose

Transmission frequency is not equal to 457 kHz, especially in the UHF range.

A modular unit (10) or avalanche probe (14) according to claim 13, characterized in that it comprises a second receiver device (86) adapted to receive at the transmission frequency of the first transmission device (82).

14. Modular unit (10) or avalanche probe (14) according to any one of claims 13 or 14, characterized in that it comprises a further receiver device (92).

15. Modular unit (10) or avalanche probe (14) according to claim 14, characterized in that the processing device (50) is designed to output below a predefinable threshold (26) a first drive signal and above the predefinable threshold (26) a second drive signal wherein the further receiver device (92) is adapted to receive the transmission signal of a second transmission device, which is not arranged in the modular unit (10) or the avalanche probe (14).

16. Modular unit (10) or avalanche probe (14) according to claim 15, characterized in that the modular unit (10) or the avalanche probe (14) is designed, on the signal received from the further receiver device (92) the predetermined threshold (26) to vary.