EP2729354B1 - Diving equipment - Google Patents

Description

The invention relates to diving equipment, comprising a compressed air bottle, which is connected to a breathing apparatus, and an inflatable vest, via which buoyancy can be balanced, by the vest being connectable to the compressed air bottle for inflation or to an outlet for deflating air in normal operation A control device is provided which can be activated via a control valve depending on the ambient water pressure and has a time control unit which, after a defined period of time and if there is no breathing activity on the breathing apparatus, switches to an emergency mode and controls an emergency valve via a control line. that connects the vest to the compressed air bottle and thus forces the vest to inflate.

Modern diving equipment usually includes a buoyancy control, also called BCD (Buoyancy Control Device), which serves as a support frame for a compressed air bottle of the diving equipment and with the help of which the diver can precisely regulate and balance his buoyancy at any depth by blowing in or releasing air.

In general, several valves are provided in a buoyancy compensator, which are provided for controlling the blowing in or discharging of air into an air bubble in the vest and often also for initiating emergency measures. These emergency measures are initiated, for example, if the compressed air bottle falls below a defined amount of compressed air or if the diver does not breathe.

The WO 2008/143581 A1 , which is considered to be the closest prior art, describes a safety method for controlling the buoyancy of a diver, wherein the diver is equipped with diving equipment, the at least one compressed air tank and a valve device connected thereto to deliver air from the pressure tank to a via a first supply device Regulators and over to lead a second feed device to an inflatable buoyancy compensator. There is an actuator that automatically inflates the buoyancy compensator if the diver does not breathe for a certain time.

From the WO2007 / 058615 A1 emerges a diving equipment, which consists of a buoyancy compensator and a compressed air bottle, as well as a valve arrangement for controlling a compressed air supply from the compressed air bottle to the buoyancy compensator. A buoyancy of a diver is balanced via the buoyancy compensator by either inflating the vest in a normal operation via the compressed air bottle or releasing compressed air from the vest. The valve arrangement comprises a control device by means of which it is possible to switch from normal operation to emergency operation. For this purpose, a control valve is provided which activates the control device depending on the surrounding water pressure. The control device has a time control unit, which is composed of a diaphragm valve and delay means. When the control device is activated via the control valve, the diaphragm valve is pressurized with compressed air from the compressed air bottle and passes the compressed air on to the delay means via a first working line. If a breath is now taken by the diver on the breathing apparatus, the compressed air directed to the diaphragm valve is passed on to the delay means via a second working line, the pressure supply via the second working line causing the delay means to be reset. However, if the diver does not take a breath from the breathing apparatus for a period of time defined by the delay means, the delay means actuates an emergency valve via a control line, which connects the vest to the compressed air bottle and thus forces it to inflate. As a result, the supposedly non-breathing diver is then transported back to the water surface.

Starting from the prior art described above, it is the object of the present invention to provide diving equipment in which functions of the control device can be influenced manually by the diver, this influencing being able to be brought about by the diver as easily as possible.

This object is achieved on the basis of the preamble of claim 1 in conjunction with its characterizing features. The subsequent dependent claims reflect advantageous developments of the invention.

According to the invention, diving equipment comprises a compressed air bottle, which is connected to a breathing apparatus, and an inflatable vest, via which the buoyancy of a diver can be balanced. For this purpose, the vest can be connected to the compressed air bottle for inflation in normal operation or air is released from the vest through an outlet. In addition, a control device is provided which is activated via a control valve depending on the ambient water pressure and has a time control unit, this time control unit converting to an emergency mode after a defined time and if the diver's breathing activity fails to occur. An emergency valve is controlled via a control line, so that the vest is connected to the compressed air bottle and the vest is forced to inflate.

In the sense of the invention, the time control unit is composed in particular of a filler panel, a control volume and an emptying valve, the control volume being continuously filled with compressed air from the compressed air bottle via the filler panel after activation of the control device by the control valve and thereby with a control line of the emergency valve in Connection is established. As soon as a defined pressure is reached in the control volume, this ensures that the emergency valve is actuated accordingly, which, as already described above, forces inflation in the vest. When the diver breaths on the breathing apparatus, on the other hand, the drain valve is actuated and the control volume is thereby emptied. As a result, the time control unit is reset with every breath by emptying the volume. For the purposes of the invention, the control device is activated by the control valve by setting the surrounding water pressure in relation to a reference pressure, preferably the atmospheric pressure, and by connecting the control volume of the time control unit to the compressed air bottle when a pressure threshold is exceeded by the surrounding water pressure becomes.

The invention now encompasses the technical teaching that an inflation valve and a drain valve are provided, the inflation valve with manual actuation by the diver, the vest with the compressed air bottle and the drain valve with manual control by the diver Diver connects the vest to the outlet for deflating air from the vest. These valves are used to balance the vest by filling or emptying it accordingly. As a special feature, at least one control valve is also provided, via the respective actuation of which the control device and / or the control valve can be influenced during the dive. In other words, at least one additional control valve is provided, via which the control valve is acted upon by the diver when actuated. As an alternative or in addition to this, the control device is influenced when the at least one control valve is actuated. Such an embodiment has the advantage that the diver can thus act on the activation of the control device and / or on the monitoring function of the control device via the at least one control valve and can thus specifically adapt it to the conditions that exist during the respective dive.

The difference is in the WO2007 / 058615 A1 it is not possible to influence the control device or the control valve of the buoyancy compensator. However, this means that if the time range in the time control unit is exceeded without taking a breath on the breathing apparatus, for example due to intentional stopping to breathe or during certain exercises during diving training, the vest is always inflated and transported back to the water surface. If the vest inflates once, this process can no longer be stopped until it reaches the water surface. It is also not possible to manually reset the time recording in the delay means.

According to the invention, the respective actuation of the at least one control valve is coupled, at least from a defined degree, with an actuation of the inflation valve and / or with an actuation of the drain valve. This has the advantage that the control device and / or the control valve for activating the control device can also be acted on via the elements which are usually already provided in the area of a buoyancy compensator in the form of an inflation valve and a drain valve, without the need to provide separate control elements. The diver can thus influence the safety functions of the respective buoyancy compensator with the valves that are familiar to him, which accordingly simplifies operation and prevents the diver from being overwhelmed in individual cases due to a large number of control elements. Furthermore, with a corresponding assignment to the inflation valve and the release valve, easy control is possible, which is intuitive by the operating diver can be made. Finally, the interventions in the safety functions of the vest can also be carried out by a diving partner, as they can be easily accessed and operated from the outside. Finally, the manufacturing effort for the formation of diving equipment can also be reduced, since separate buttons, which would otherwise have to be provided for resetting the safety functions, can be saved.

In a further development of the invention, the drain valve can be actuated via an actuating element, wherein in a first half of an actuating range of the actuating element an actuating movement of the actuating element is only coupled with a displacement of the drain valve and, from a second half of the actuating range, the actuating movement is additionally coupled with a displacement of the at least one control valve is. By means of such a configuration, the degree of actuation of the actuating element can be used to control whether only a triggering of the drain valve for balancing a buoyancy or whether the control device should also be influenced in order to carry out the aforementioned functions such as resetting and / or aborting an inflation of the vest , The diver can thus control centrally via the type of actuation of the actuating element, whether he performs the functions in normal operation or whether he would like to make changes to the control device in addition.

According to the invention, the at least one control valve is designed as a shut-off valve, which is provided between the emergency valve and the compressed air bottle and, in an actuated position, interrupts the connection between the emergency valve and the compressed air bottle. The check valve is preferably coupled to a movement of the drain valve at least from a defined degree of actuation of the drain valve. In this way, inflation of the vest initiated in emergency operation can be stopped by interrupting the pressure supply to the emergency valve via the shut-off valve. When coupled to the drain valve, the diver can make this interruption manually by actuating the drain valve, since the check valve is coupled to the drain valve at least from a certain degree of actuation of the drain valve. The shut-off valve is preferably designed as a 2/2-way valve which, in a basic position, allows compressed air to flow to the emergency valve and interrupts the connection in an actuated position. Furthermore, the blocking valve, when coupled to the drain valve, is connected in particular mechanically, for example via a corresponding linkage, to the drain valve According to the invention, however, a pneumatic, hydraulic or electrical coupling is also conceivable.

According to a further embodiment of the invention, the at least one control valve is designed as a reset valve, to which a working line branches off from the control line of the emergency valve and which in an actuated position relieves the pressure on the control line. In particular, this reset valve is then coupled with a movement of the drain valve at least from a defined degree of actuation of the drain valve. Advantageously, a timing procedure in the time control unit is reset by actuating the reset valve due to the pressure relief. Thus, the reset valve can be used to restart the time counting in the time control unit which runs after the last breath taken on the breathing apparatus, the diver being able to control this restart manually by actuating the drain valve if it is coupled to the drain valve. If the time control unit is designed with a volume and a directional control valve, the volume is emptied when the reset valve is actuated, which brings about the desired reset. In the sense of the invention, the reset valve is in particular mechanically coupled to the drain valve, but can also be connected pneumatically, hydraulically, electrically or in some other way to the movement of the drain valve. If a reset valve is provided in addition to the shut-off valve described in advance, these two valves can be coupled to the drain valve in particular via a common linkage, so that actuation of the drain valve at least from a certain degree causes the shut-off valve and the reset valve to be actuated. Furthermore, the reset valve is preferably designed as a 2/2-way valve.

According to the invention, the at least one control valve is designed as a reset valve, which is placed between the control valve and the compressed air bottle, the reset valve connecting a working line of the control valve with the compressed air bottle in a basic position and relieving the working line of the control valve in an actuated position. The reset valve is preferably actuated together with the inflation valve at least from a defined degree of actuation, so that a supply to the control valve is subsequently depressurized. Such an embodiment has the advantage that a monitoring function of the control device can be switched on again after an interruption by the provision of the reset valve and the pressure-free switching of the supply to the control valve, the diver switching on when actuated can make the inflation valve manually via the inflation valve. A coupling between the inflation valve and the reset valve is again preferably configured mechanically, but can also be provided hydraulically, pneumatically, electrically or in another way in the sense of the invention. Furthermore, the reset valve is designed in particular as a 3/2-way valve which, in a basic position, connects an inflow to the control valve with the compressed air bottle and in an actuated position connects the inlet to the control valve with an unpressurized line to the vest.

In a development of the invention, the at least one control valve is formed by a check valve which is arranged between the control valve and the time control unit. The shut-off valve can be moved into a shut-off position, in which a connection between the time control unit and the control valve is interrupted, whereas the shut-off valve establishes the connection between the time control unit and control valve in a basic position, into which the shut-off valve is connected via a control line connected to an outlet side of the inflation valve is transferable. Such an embodiment has the advantage that a temporary interruption of the breath monitoring function can be brought about via the shut-off valve, the monitoring being then reactivated by the time control unit when the inflation valve is actuated again. For example, when taking underwater photographs and usually stopping the breath in connection with this, the monitoring can be specifically switched off in order to avoid undesired inflation of the vest.

According to the invention, the at least one rain valve is formed by a bypass valve which can be moved into an actuation position in which a line branching off from a control volume of the time control unit is connected to an additional volume. In contrast, the check valve interrupts the connection between the line and the additional volume in a basic position, into which the check valve can be transferred via a control line connected to an outlet side of the inflation valve. In this way, a time window, after which the emergency measures have been initiated and the diver's breathing has stopped, can be increased in a targeted manner by forming a larger total volume by connecting the additional volume to the control volume, which results in a later reaching of a trigger pressure for transferring the emergency valve to the emergency position ,

According to a further advantageous embodiment of the invention, a pre-test valve with an actuating element is provided, the pre-test valve in an actuated position connecting a control line of the control valve to the compressed air bottle, so that the control valve activates the control device. By providing the pre-test valve, proper functioning of the control device can thus be checked on the water surface before a dive. Otherwise, the control valve only activates the control device when a corresponding surrounding water pressure has been reached. By pressurizing a control line of the control valve, this pressure control is now bypassed and the time control unit of the control device is thus already connected to the compressed air bottle on the water surface. It can then be checked whether the time control unit of the control device and subsequently the emergency valve for emergency inflation of the vest are functioning properly. In combination with the provision of the aforementioned reset valve in the area of the inflation valve, this check function can then be interrupted again by depressurizing an inlet to the control valve through the reset valve. In this case, an actuating element of the pre-test valve is preferably designed as a push button, but can also be implemented in another way within the scope of the invention.

The invention is not limited to the specified combination of the features of the main claim or the dependent claims. There are also possibilities to combine individual features, also insofar as they emerge from the claims, the following description of an embodiment or directly from the drawings. Reference of the claims to the drawings by the use of reference numerals is not intended to limit the scope of the claims.

Figur 1

ein Blockschaltbild einer Tauchausrüstung gemäß einer bevorzugten Ausgestaltung der Erfindung;

Figur 2

ein Funktionsschema zum Zurücksetzen einer Zeitablaufprozedur einer Zeitkontrolleinheit der Tauchausrüstung gemäß Figur 1;

Figur 3

ein Funktionsschema einer Unterbrechung einer Notfallaufblasung einer Weste der Tauchausrüstung gemäß Figur 1;

Figur 4

ein Funktionsschema bezüglich eines Zurücksetzens einer Kontrolleinrichtung der Tauchausrüstung gemäß Figur 1; und

Figur 5

ein Funktionsschema zum Zurücksetzen eines Vorabfunktionstests der Tauchausrüstung gemäß Figur 1.

Further advantageous embodiments of the invention result from the following description of a preferred embodiment of the invention, which refers to the figures shown in the drawings. It shows:

Figure 1

a block diagram of diving equipment according to a preferred embodiment of the invention;

Figure 2

a functional diagram for resetting a timing procedure of a time control unit of the diving equipment according to Figure 1 ;

Figure 3

a functional diagram of an interruption of an emergency inflation of a vest of diving equipment according to Figure 1 ;

Figure 4

a functional diagram regarding a reset of a control device of the diving equipment according to Figure 1 ; and

Figure 5

a functional diagram for resetting a pre-function test of the diving equipment according to Figure 1 ,

Out Figure 1 shows a block diagram of diving equipment according to a preferred embodiment of the invention. This diving equipment in this case comprises a compressed air bottle 1 which supplies compressed air to a breathing apparatus (not shown further here), so that a diver can be supplied with breathing air under water. Furthermore, an inflatable vest 2 is provided, which is provided with an air bubble (likewise not shown in the present case), which can either be inflated with compressed air by the compressed air bottle 1 or can be released from the air. Corresponding to the supply or discharge of air, buoyancy of the diver can be balanced via the vest 2, in that an increase and a decrease can be represented by supplying an appropriate amount of air.

In normal operation, the supply and discharge of air into the vest 2 is controlled via intermediate valves in the form of an inflation valve 3 and a discharge valve 4, which can each be actuated by the diver via an associated control element 5 or 6, these control elements 5 and 6 are each designed as push buttons in the present case. Both the inflation valve 3 and the drain valve 4 are designed as 2/2-way valves and are biased by an associated spring into the basic position shown here, from which they can be moved into an actuating position by the associated actuating element 5 or 6. In this actuation position, the inflation valve 3 then connects the compressed air bottle 1 to the vest 2, so that the vest 2 is inflated by supplying compressed air. When the actuating element 6 is actuated and the drain valve 4 is moved into the actuating position, the vest 2, on the other hand, is connected to a mouthpiece 7, via which compressed air escapes from the vest 2 into the environment and thus a discharge of compressed air from the vest 2 can be represented. It can also via the mouthpiece 7 manual filling of the vest 2 can be carried out in individual cases. By appropriately actuating the two valves 3 and 4, the diver can thus balance his buoyancy in accordance with the filling or emptying of the vest 2.

Furthermore, the diving equipment according to the invention has a control device 8, by means of which there is no breathing activity by the diver on the breathing apparatus and in an emergency operation an inflation of the vest 2 can be forced, so that the diver is transported back to the water surface as a result of the inflation. For this purpose, the control device has an emergency valve 9, which in the present case is also designed as a 2/2-way valve and in an actuation position connects the compressed air bottle 1 directly to the vest 2, so that the vest 2 is inflated. In the basic position of the emergency valve 9 shown here, however, this connection is interrupted, the emergency valve 9 being biased into this basic position by an associated spring element and by pressurization by means of a control line 10. The control line 10 is supplied with the currently surrounding water pressure by a pressure connection 11. Contrary to the spring element and the control line 10, the emergency valve 9 can be shifted and held in the actuating position by corresponding pressure in two further control lines 12 and 13, the control line 12 being connected to a time control unit 14, while the control line 13 is connected to the outlet side of the emergency valve 9 and the feed to the vest 2 is connected. To move the emergency valve 9 into the actuation position, a pressure in the control line 12 must exceed a pressure in the control line 10 and a pressure caused by the spring element. If the emergency valve 9 is then moved into the actuation position, it is held in this position by the control line 13 due to the then prevailing pressure.

If the diver is not breathing, the time control unit 14 applies a pressure suitable for opening the emergency valve 9 to the control line 12 for a defined period of time. This time control unit 14 comprises a control volume 15 which, when the control device 8 is activated, is continuously filled with air under pressure via a filler panel 16, the control volume 15 being connected to the control line 12 of the emergency valve 9. When a certain pressure in the control volume 15 is reached, an actuation pressure for moving the emergency valve 9 into the actuation position is reached. On the discharge side of the control volume 15, an emptying valve 17 is also provided, which is designed as a 2/2-way valve and at Breathing activity of the diver and a concomitant pressure drop in the line system connected to the compressed air bottle 1 is moved from the illustrated basic position into an actuating position. The control volume 15 is then emptied in the actuation position. In accordance with the selection of a suitable volume of the control volume 15 and a restriction via the filler panel 16, a time range can be defined after which an emergency operation is initiated by the control device 8.

However, this time range can be extended in a targeted manner by adding an additional volume 18 to the control volume 15. For this purpose, a line 19 branches off on the outlet side of the control volume 15 and can be connected to the additional volume 18 via an intermediate bypass valve 20. This bypass valve 20 is designed as a 2/2-way valve, the line 19 being separated from the additional volume 18 in the basic position of the bypass valve 20 shown. The bypass valve 20 can now be specifically moved via an actuating element 21, in the present case in the form of a push button, into an actuating position in which the line 19 and the additional volume 18 are connected to one another, so that fluid can flow into the additional volume 18. As a result, the volume between the filler orifice 16 and the drain valve 17 increases and the actuation pressure for shifting the emergency valve 9 into the actuation position is also reached later. To reset the bypass valve 20, a control line 22 is provided, which is connected to an outlet side of the inflation valve 3, so that the bypass valve 20 is converted into the basic position separating the additional volume 18 from the line 19 as soon as the inflation valve 3 is actuated.

To activate the control device 8, a control valve 23 is connected upstream of the time control unit 14, which activates the control device 8 as a function of the currently surrounding water pressure. For this purpose, the control valve 23 is connected on the one hand via a control line 24 to the pressure connection 11 in normal operation and is thus pressurized with the surrounding water pressure via this control line 24 and on the other hand is connected via another control line 25 to a reference volume 26, in which a Reference pressure, preferably atmospheric pressure, prevails. The control valve 23 designed here as a 2/2-way valve separates the time control unit 14 behind it from the inlet in the basic position shown, but the control valve 23 then connects this inlet to the time control unit 14 in an actuation position as soon as the surrounding water pressure pressures the pressure in the reference volume 26 and one represented by a spring element of the control valve 23 Pressure has exceeded. In normal operation, the inlet is connected to the compressed air bottle 1. Consequently, the control device 8 is activated by the control valve 23 as soon as a defined water depth is reached.

However, the activation of the control device 8 and thus also the breathing monitoring function of the time control unit 14 can be temporarily ended by interrupting the connection between the filler panel 16 of the time control unit 14 and the control valve 23 via a check valve 27. This check valve 27 is arranged between the filler orifice 16 and the control valve 23 and in the present case is designed as a 2/2-way valve. In the basic position shown, the shut-off valve 27 enables fluid to flow from the control valve 23 to the filler orifice 16 as soon as the surrounding water pressure has exceeded the pressure threshold explained above. By means of an actuating element 28 in the form of a pushbutton, the shut-off valve 27 can, however, be specifically moved into an actuating position in which a flow of fluid to the filler orifice 16 is prevented and, accordingly, no monitoring of the breathing activities by the time control unit 14 takes place. The check valve 27 is reset via a control line 29, which, like the control line 22, is connected to an outlet side of the inflation valve 3. Accordingly, the check valve 27 is moved into the basic position connecting the control valve 23 and the filler panel 16 as soon as the inflation valve 3 is actuated.

As a further special feature, the diving equipment also includes a shut-off valve 30 and reset valves 31 and 32, and a pre-test valve 33, the respective function of which is now performed with the help of the others Figures 2 to 5 should be described. In the Figures 2 to 5 material flows in the form of compressed air are shown as thick arrows, mechanical couplings as thin arrows and signal flows as dashed arrows.

How here from Figure 1 can be seen, the reset valve 31 is mechanically coupled to the drain valve 4, so that actuation of the drain valve 4 via the actuating element 6 also leads to actuation of the reset valve 31. However, this mechanical coupling is designed in such a way that this coupling only becomes effective from a second half of a possible actuating range of the actuating element 6. Thus, only the drain valve 4 is actuated over the first half of the total adjusting range of the adjusting element 6, the reset valve 31 also being moved from a second half of the adjusting range. In the present case, the reset valve 31 is designed as a 2/2-way valve, with an inlet side of the reset valve 31 branches off from the control line 12 of the emergency valve 9 and an outlet side of the reset valve 31 leads to the vest 2. As now in combination with the functional diagram in Figure 2 it can be seen, the reset valve 31 can be used to reset the timing procedure of the time control unit 14 by relieving the pressure on the control line 12 of the emergency valve 9. Because in the actuating position of the reset valve 31, this connects the control line 12 with a pressureless line to the vest 2. By depressurizing the control line 12, the timing procedure in the time control unit 14 is reset at the same time, since the control volume 15 is emptied, and subsequently one Monitoring of the diver's breathing activity restarts.

Movement of the reset valve 31 is also coupled with a movement of the check valve 30, so that the check valve 30 is also moved into an actuation position from a second half of the actuating range of the actuating element 6 of the drain valve 4. The check valve 30 is also designed as a 2/2-way valve and in the present case is arranged between the emergency valve 9 and the compressed air bottle 1. In the basic position shown, the blocking valve 30 enables compressed air to be supplied from the compressed air bottle 1 to the emergency valve 9. However, if the blocking valve 30 is now moved into the actuating position, the connection between the emergency valve 9 and the compressed air bottle 1 is interrupted. The diver thus has the possibility, via the shut-off valve 30, of interrupting this unwanted inflation by appropriate actuation of the shut-off valve 30 in the event of an unwanted inflation of the vest 2 in emergency operation, which can occur, for example, if the breath is held for a long time. In this case, an inflow to the emergency valve 9 is prevented, as also from the functional diagram in FIG Figure 3 evident.

Out Figure 1 it can also be seen that the further reset valve 32 is mechanically coupled to a movement of the inflation valve 3 when actuated via the actuating element 5. This reset valve 32 is designed as a 3/2-way valve, which in the basic position shown connects an inlet of the control valve 23 with the compressed air bottle 1, but when an actuation position is reached by moving it via the actuating element 5, the inlet of the control valve 23 with an unpressurized line Vest 2 communicates. Activation of the control device 8 is reset by this depressurization of the supply to the control valve 23, since in this case a control line 34 of the control valve 23 that branches off from the outlet side of the control valve 23 is also depressurized becomes. As a result, the control device 8 is activated by the control valve 23 only when the pressure applied to the control line 24 is higher than the pressure prevailing in the reference volume 26 and the pressure represented by the spring element of the control valve 23. This reset function is also from the functional diagram in Figure 4 seen.

Finally, another special feature, as in Figure 1 to recognize, a pre-test valve 33 is provided, which can be transferred manually from the basic position shown into an actuating position via an actuating element 35. This pre-test valve 33 is designed here as a 3/2-way valve and connects the pressure port 11 to the control line 24 of the control valve 23 in the basic position. When operated manually via the actuating element 35 and when the actuation position is reached, the control line 24 of the control valve 23 is connected to the Compressed air bottle 1 connected, which causes a direct transfer of the control valve 23 into the actuating position.

Accordingly, the control device 8 is activated and this is independent of a surrounding water pressure, so that a check of a proper function of the control device 8 can also be carried out above the water surface and independently of the criteria otherwise required for activation via the pre-test valve 33. As in combination with the functional diagram Figure 5 this preliminary function test can then be reset after the actuating element 35 has been released and by actuating the reset valve 32 via the actuating element 5. Otherwise, the control valve 23 would always be kept in the actuation position due to the control line 34 branching off from its discharge side.

In the present case, couplings of the check valve 30 and the reset valve 31 with the drain valve 4 and a coupling of the reset valve 32 with the inflation valve 3 are shown mechanically. Hydraulic, pneumatic or electrical coupling is also conceivable within the meaning of the invention. Resetting the emergency valve 9, the bypass valve 20, the check valve 27 and also the control valve 23 is in the present case pneumatically solved via control lines, but within the scope of the invention this can also be accomplished mechanically, hydraulically or electrically in accordance with a pressure detected at another point become.

By means of the configuration of diving equipment according to the invention, it is thus possible to easily influence functions of the control device 8 of the diving equipment. Such an operation can also be carried out by a diving partner, for example a diving instructor.

LIST OF REFERENCE NUMBERS

1

Druckluftflasche

2

vest

3

inflation

4

drain valve

5

actuator

6

actuator

7

mouthpiece

8th

control device

9

emergency valve

10

control line

11

pressure connection

12

control line

13

control line

14

Time control unit

15

control volume

16

filler panel

17

drain

18

additional volume

19

management

20

bypass valve

21

actuator

22

control line

23

control valve

24

control line

25

control line

26

reference volume

27

check valve

28

actuator

29

control line

30

check valve

31

reset valve

32

reset valve

33

Preliminary test valve

34

control line

35

actuator

Claims (8)

1. Diving equipment, comprising a compressed air cylinder (1) which is connected to a breathing apparatus, and an inflatable vest (2) by means of which buoyancy can be balanced by it being possible to connect the vest (2), in normal operation, to the compressed air cylinder (1) for inflating or to an outlet for letting out air, a monitoring device (8) being provided which can be activated by means of a control valve (23) depending on a surrounding water pressure and which has a time monitoring unit (14) which, after a defined time has elapsed and in the event of the absence of breathing activity in the breathing apparatus, can transfer into an emergency operation and can actuate an emergency valve (9) by means of a control line (12), which valve thereby connects the vest (2) to the compressed air cylinder (1) and thus forces the vest (2) to inflate, an inflation valve (3) and an outlet valve (4) being provided, the inflation valve (3) connecting the vest (2) to the compressed air cylinder (1) when manually activated and the outlet valve (4) connecting the vest (2) to an outlet when manually actuated, and at least one regulating valve being provided, by means of the relevant activation of which the monitoring device (8) and/or the control valve (23) can be influenced during a dive, characterized in that the relevant activation of the at least one regulating valve is coupled, at least from a defined degree, to an activation of the inflation valve (3) and/or to an activation of the outlet valve (4).
2. Diving equipment according to claim 1, characterized in that the outlet valve (4) can be activated by means of an actuating element (6), an actuating movement of the actuating element (6) in a first half of an actuating region of the actuating element (6) only being coupled to a displacement of the outlet valve (4) and the actuating movement from a second half of the actuating region additionally being coupled to a displacement of the at least one regulating valve.
3. Diving equipment according to claim 1, characterized in that the at least one regulating valve is designed as a shut-off valve (30) which is provided between the emergency valve (9) and the compressed air cylinder (1) and which interrupts the connection between the emergency valve (9) and compressed air cylinder (1) in an activated position.
4. Diving equipment according to claim 1, characterized in that the at least one regulating valve is designed as a reset valve (31) to which a working line branches off from the control line (12) of the emergency valve (9) and which depressurizes the control line (12) in an activated position.
5. Diving equipment according to claim 1, characterized in that the at least one regulating valve is designed as a reset valve (32) which is placed between the control valve (23) and the compressed air cylinder (1), the reset valve (32) connecting a working line of the control valve (23) to the compressed air cylinder (1) in an initial position and depressurizing the working line of the control valve (23) in an activated position.
6. Diving equipment according to claim 1, characterized in that the at least one regulating valve is formed by a shut-off valve (27) which is arranged between the control valve (23) and the time monitoring unit (14), the shut-off valve (27) being movable into a shut-off position in which a connection between the time monitoring unit (14) and the control valve (23) is interrupted, whereas the shut-off valve (27) establishes the connection between the time monitoring unit (14) and control valve (23) in an initial position into which the shut-off valve (27) can be transferred via a control line (29) connected to an outflow side of the inflation valve (3).
7. Diving equipment according to claim 1, characterized in that the at least one regulating valve is formed by a bypass valve (20) which can be transferred into an activation position in which a line (19) branching off from a monitoring volume (15) of the time monitoring unit (14) is connected to an additional volume (18), whereas the bypass valve (20) can interrupt the connection between the line (19) and the additional volume (18) in an initial position into which the bypass valve (20) can be transferred via a control line (22) connected to an outflow side of the inflation valve (3).
8. Diving equipment according to any of the preceding claims, characterized in that a pretesting valve (33) having an activation element (35) is provided, the pretesting valve (33) connecting a control line (24) of the control valve (23) to the compressed air cylinder (1) in an activated position such that the control valve (23) can activate the monitoring device (8).

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