EP0738943A1 - Diving measuring device, in particular diving computer - Google Patents

Abstract

The measurement device has a water tight housing (3) containing electronic components (4), at least one diving data display (5) and an electrical power source (6) with a mechanism (7.1,7.2) for connecting the power source to the electronic components. The display has an illumination device which can be switched on and off. The switching device for the illumination device is an element (8) which responds to changes in movements, e.g. an acceleration sensor or microphone, which can be arranged inside the water tight housing. The diving data display can be an LCD module with back illumination.

Description

The present invention relates to a diving measuring device, in particular a diving computer, with a housing in which electronic components, at least one diving data display means and an electrical energy source are arranged in a watertight manner and has the means for switching on the energy source on electronic components, the diving data display means being assigned lighting which can be switched on and off is.

Diving gauges or diving computers of the above-mentioned type have been known for a few years and are used by divers, in particular sport divers, who use compressed air diving devices to increase their safety.

Our breathing air is a mixture of approximately 21% oxygen, 78% nitrogen and 1% other gases. Nitrogen is in the blood and in human body tissue in a dissolved form. The amount depends on the pressure surrounding the human body. On the surface of the earth this is the air pressure. If a diver dives to a certain depth, the pressure surrounding his body increases. It follows that the blood and body tissue of the diver can absorb more nitrogen at depth than is possible on the surface. When the diver appears, the nitrogen diffuses from the tissues back into the blood due to the decreasing ambient pressure and is transported by it to the lungs, where it is excreted. If the ambient pressure drops too quickly, the nitrogen dissolved in the blood and body tissue cannot be exhaled quickly enough. As a result of these supersaturations, gas bubbles precipitate, which can lead to damage in the organism.

A dive computer now has the essential task of helping to prevent the damage mentioned above from occurring. The dive computer carried during a dive determines the dive profile of the diver as a function of time and uses it to calculate the nitrogen increase or decrease in the human body when the diver stays in a greater or a smaller depth using known formulas or tables. In particular, the dive computer shows the diver how to surface and at what depth he has to stay for how long, so that the aforementioned gas bubbles cannot form in the blood. Newer dive computers independently keep a so-called log book, which also takes into account the time spent on the surface of the earth between two or more dives.

State-of-the-art technology is used in these small wonder devices. The calculations are carried out by microprocessors and the dive data are preferably displayed today with a liquid crystal display (LCD, Liquid Cristal Display). Liquid crystal display modules with a backlight are used to ensure that the diving data can be read easily, especially at greater depths. The latter is designed to be switched on and off by the diver. The US company seaQuest has launched a dive computer under the name SUUNTO EON with an illuminable LCD module, which has to be pressed at a marked point on the housing of the dive computer to switch the lighting on and off. This is a very difficult process to undertake, especially under water. With the thick diving gloves it is problematic to precisely actuate a firmly defined small pressure point. Usually both hands are required. In addition, the design and manufacture of a tight, elastic housing point, below which a pressure switch is arranged, is technically very difficult and complex.

It is the object of the present invention to provide a diving measuring device, in particular a diving computer, which does not have the disadvantages mentioned above.

This object is achieved in that an organ which is responsive to changes in movement is present for switching the lighting on and off.

It is thus achieved that one only needs to knock on the dive computer with one hand or an object in order to switch the illumination of the dive data display means on or off or that the latter is hit against another object. If, for example, the dive computer is worn with a fastening strap on the wrist or arm, it is sufficient to hit the wrist or arm against the body. As a result, said organ, which is responsive to changes in movement, generates an electrical signal which can be used to switch the lighting on or off.

No matter how the diving computer according to the invention is carried, the switching on and off is simple because no specific point on the housing has to be pressed and can in any case be carried out with only one hand.

An accelerometer is preferably used as an organ responsive to changes in motion. Instead of this, the use of a microphone would also be conceivable. The acceleration sensor or the microphone are built into the housing of the dive computer in a watertight manner and are not accessible from the outside. The arrangement is consequently simple and unproblematic compared to a pressure switch which must be at least indirectly operable from the outside. In particular, there are no sealing problems. Thin-walled elastic points, so-called weak points, are not present on the housing of the dive computer according to the invention.

Liquid crystal display modules with a backlight are usually used today to display the dive data. Other types of display means with lighting that can be switched on and off are also conceivable and are not excluded from this invention.

The preferred acceleration sensor outputs an electrical signal that is dependent on the size of a change in movement. This signal is fed to evaluation electronics for switching the illumination of the diving data display means on and off and is evaluated there accordingly. An electronic evaluation circuit essentially comprises an amplifier, a bistable switching stage and a driver circuit for controlling the lighting. The evaluation electronics is designed such that, in particular small signals, which are only caused by rubbing on the housing of the dive computer or by moving it slowly, do not cause the lights to switch.

By tapping the housing or striking the latter against another object, typical signals are emitted by the accelerometer in a low frequency range. In order to be able to distinguish interference signals from these typical signals which are intended to switch the lighting on or off, a low-pass filter or preferably a band-pass filter is provided. The upper cut-off frequency of the filter used is approximately between 20 and 50 Hz, preferably 25 Hz. The lower cut-off frequency of the bandpass filter preferably used is 6 Hz. It can be in a frequency range from 3 to 15 Hz. The low pass filter or the band pass filter can be constructed as an active or passive RC filter. The filter is advantageously connected upstream of the amplifier mentioned.

• Fig. 1 eine Aufsicht auf einen erfindungsgemässen Tauchcomputer, der in der Art einer Armbanduhr in einer Tragvorrichtung mit einem Befestigungsband angeordnet ist,
• Fig. 2 eine Seitenansicht des aus der Tragvorrichtung der Fig. 1 herausgelösten Tauchcomputers,
• Fig. 3 eine Rückansicht des Tauchcomputers gemäss den Fig. 1 und 2,
• Fig. 4 eine Seitenansicht einer Ausführungsvariante des Tauchcomputers,
• Fig. 5 ein Blockschaltbild eines Auswerteelektronikstromkreises für das Ein- und Ausschalten der Beleuchtung der Tauchdatenanzeigemittel und
• Fig. 6 Dämpfungskurven von im Auswerteelekronikstromkreis einsetzbaren Filtern.

A preferred embodiment of the immersion measuring device according to the invention is described below with reference to figures, for example. Show it

• 1 is a plan view of a diving computer according to the invention, which is arranged in the manner of a wristwatch in a carrying device with a fastening strap,
• FIG. 2 shows a side view of the dive computer detached from the carrying device of FIG. 1,
• 3 shows a rear view of the dive computer according to FIGS. 1 and 2,
• 4 shows a side view of an embodiment variant of the dive computer,
• 5 is a block diagram of an electronic evaluation circuit for switching the illumination of the dive data display means on and off
• Fig. 6 damping curves of filters that can be used in the evaluation electronic circuit.

1 shows a top view of a first embodiment of an immersion measuring device 1 according to the invention. It is a diving computer 2, which is held in a carrying device 20, preferably made of an elastic material, for example a silicone-containing material. The diving computer 2, which is essentially cylindrical and tablet-shaped in the example shown, is inserted into a hollow cylindrical opening of the carrying device 20. On the latter there is a fastening strap 21 which is intended for fastening the immersion measuring device 1 to an arm or leg of the diver. For this purpose, it is looped around the corresponding link, passed through a through opening 23 of a fastening tab 22 of the carrying device, passed through further through openings 25.1, 25.2 and brought into engagement with a locking tab 24. The fastening strap 21 and the fastening tab 22 are attached to the carrying device 20, which essentially corresponds to a watch case, in a bracelet of a wristwatch. So that the fastening strap 21 can come into engagement with the locking tab 24, slot-like openings running transversely to the strap are provided at periodic intervals on the part of the fastening strap not shown.

The dive computer 2 is installed in a cup-shaped housing 3, advantageously made of a transparent plastic. In the exemplary embodiment shown, a circumferential housing rib 26 limits the insertion depth into the hollow-cylindrical opening of the carrying device 20. A display means 5 is arranged on the inside immediately adjacent to the housing base. This is preferably a liquid crystal display module 5, the display field of which is visible through the transparent housing base. Two small openings are made in the bottom of the housing, through which a metal pin 7.1, 7.2 is guided, in such a way that the end face of said metal pins, preferably made of stainless steel, are flush with the outer surface of the bottom of the housing. The metal pins are designed to turn on the dive computer. They are electrically connected to each other in the water by the water conductance and thus switch on of the dive computer. As a result, this remains switched on at least during the entire diving process.

In the side view of the diving computer 2 according to FIG. 2, the liquid crystal display module 5, the contact pins 7.1, 7.2 can be seen through the transparent housing, which components are essentially arranged on the side of a printed circuit board 27 facing the housing base of the housing 3. On the opposite side of this circuit board 27 there are several electronic elements shown as block 4. These include a microprocessor, storage means, resistors, capacitors and a pressure sensor 28. The electronic components are supplied with an electrical energy source, preferably a lithium battery 6. This can be connected to the electronic components using the switch-on means 7.1, 7.2. The organ according to the invention, which responds to changes in movement, is drawn at 8. As already said, this organ is preferably an accelerometer. However, a microphone, for example an electret microphone, can also be used. An evaluation electronics circuit is identified by 10, which evaluates signals which are output by the acceleration sensor when there are changes in movement and thereby generates an output signal which is intended for switching on and off a backlight which is integrated in the liquid crystal display module 5. The cup-shaped housing 3 is filled with a permanently elastic silicone compound. All components housed in the housing are therefore protected against water and moisture. The battery 6 is replaced, which must only be done after a period of about five years when the dive computer is in heavy use, by opening the silicone casting compound at the appropriate point and by re-casting after changing the battery. The pressure sensor 28 can sense the ambient pressure outside the housing thanks to the permanently elastic silicone casting compound.

The acceleration sensor 8 can also be designed such that it preferably detects changes in movement in one direction. This direction can be a direction approximately perpendicular to the end faces of the tablet-shaped dive computer 2.

When viewed from the rear according to FIG. 3, essentially the printed circuit board 27, the electronic components 4 combined as a block, the organ 8 responsive to changes in movement, the evaluation electronics circuit 10 associated therewith and the electrical energy source 6 are visible. The electronic evaluation circuit 10 and the organ 8, which parts are only shown symbolically here, are of course preferably also arranged on the printed circuit board 27. For a relatively simple change of the battery, the space facing away from the circuit board above the energy source or battery is freely accessible. The silicone potting compound can therefore be easily removed at this point, the battery replaced and the opening created for this purpose closed again with a silicone potting compound.

Of course, it is also conceivable to cover the cup-shaped housing 3 with a housing cover 30. Such an embodiment is shown in FIG. 4. Advantageously, the housing cover 30 is provided with a first opening through which a battery compartment in which the electrical energy source 6 is inserted is accessible. The battery compartment can be closed watertight with a battery compartment closure 31. There is a further opening 32 in the housing cover, which on the one hand serves as a potting opening for filling the silicone potting compound. On the other hand, it is intended to transmit the pressure acting on the dive computer 2 from the outside to the pressure sensor 28.

5, the evaluation electronics circuit for evaluating the signal 9 output by the acceleration sensor 8 is shown in block diagram form. The electrical signal 9 emitted by the acceleration sensor when there is a change in movement is fed to a filter 14. This can be an active or passive RC filter and can be designed as a low-pass filter or preferably as a band-pass filter. The filtered signal passes through a filter output 34 to an amplifier designated 11. The signal is amplified there and then fed to a bistable switching stage 2. This switches a driver circuit 13 either on or off. In the switched-on state, the driver circuit 13 supplies the electrical energy 33 which is necessary for the backlighting of the LCD module 5. Every time the bistable switching stage 12 at its input receives a correspondingly large signal from the amplifier 11, which exceeds a certain preset threshold, switches the switching stage from its current on or off state to the other bistable state. It remains there until an input signal that exceeds the specified threshold arrives again. The illumination of the display means, in particular the backlight of the LCD module 5, is also always switched off when no data is provided on the latter. This is always the case when the dive computer is switched off. However, a displayless state can also occur when the dive computer is switched on. The lighting in the latter case can be switched off, for example, via a line which acts on the bistable switching stage 12 and is connected to the electronic elements 4. The filter 14 has the task of filtering the typical signals, which the acceleration sensor 8 emits when the dive computer 2 strikes or knocks, and feeds it to the amplifier 11. The filter is intended to prevent signals from only slight changes in movement or rubbing noises from also causing the lighting to be switched on or off. It has been found that when the dive computer is struck or knocked on, the acceleration sensor 8 emits pronounced signals in the frequency range between 6 and 25 Hz. So that preferably only these signals are applied to the amplifier 11, it is provided that a bandpass filter with a pass characteristic shown in FIG. The bandpass filter has an upper cut-off frequency 37 of preferably 25 Hz and a lower cut-off frequency of preferably 6 Hz. However, the cut-off frequencies can lie approximately in the frequency ranges mentioned at the beginning.

Instead of a bandpass filter, a lowpass filter could also be provided. A corresponding characteristic curve of such a filter is identified in FIG. 6 by reference number 35.

The described embodiment of switching the lighting of the display means of the dive computer according to the invention on and off shows that the switching operation is carried out only by knocking on the dive computer or by striking the latter on any other object, in particular can be done easily and safely under water. It does not matter whether the dive computer, as shown in FIG. 1, is worn looped around an arm or a leg, or whether it is simply attached to a fastening strap at one point of the diving suit or to an object of the diving equipment.

The entire device for switching the lighting on and off is cast watertight in the sealing compound. Special problems, in particular sealing problems when manufacturing the diving computer, therefore do not occur.

It is obvious that the solution according to the invention for switching the lighting on and off could also be used for switching on and off other diving measuring devices or other parts of the diving computer. More than one liquid display element could also be installed, of which the background lighting of only one or more of these LCD modules could be switched on and off with the switching device according to the invention.

Claims (10)

Diving measuring device (1), in particular diving computer (2), with a housing (3) in which electronic components (4), at least one diving data display means (5) and an electrical energy source (6) are arranged watertight, and the means (7.1, 7.2) for switching on the energy source to the electronic components, the diving data display means being assigned a switchable and switchable lighting, characterized in that an organ responsive to changes in movement is present for switching the lighting on and off. Immersion measuring device according to claim 1, characterized in that the organ responding to changes in movement is an acceleration sensor (8). Immersion measuring device according to claim 1, characterized in that the organ responding to changes in movement is a microphone (8). Immersion measuring device according to one of claims 1 to 3, characterized in that the organ (8) responsive to changes in movement is installed in the housing (3) in a watertight manner. Diving measuring device according to one of claims 1 to 4, characterized in that the at least one diving data display means is an LCD module (5) with a backlight. Immersion measuring device according to one of Claims 1 to 5, characterized in that the organ (8) which responds to changes in movement outputs an electrical signal (9) which is dependent on the size of a change in movement, which signal can be fed to an electronic evaluation circuit (10) which essentially comprises an amplifier (11), a bistable switching stage (12) and a driver circuit (13) for controlling the lighting. Immersion measuring device according to claim 6, characterized in that the electronic evaluation circuit (10) contains a low-pass filter (14), the cut-off frequency of which is 20 to 50 Hz, preferably 25 Hz. Immersion measuring device according to claim 6, characterized in that the electronic evaluation circuit (10) contains a bandpass filter (14), the upper limit frequency of which is 20 to 50 Hz, preferably 25 Hz, and the lower limit frequency of which is 3 to 15 Hz, preferably 6 Hz. Immersion measuring device according to claim 7 or 8, characterized in that the low-pass filter or the band-pass filter is an active or a passive RC filter (14). Immersion measuring device according to one of claims 7 to 9, characterized in that the low-pass filter (14) or the band-pass filter (14) is connected upstream of the amplifier (11).

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