EP2546139B1 - Diving equipment - Google Patents

Description

The invention relates to diving equipment comprising a compressed air source communicating with a respirator and an inflatable vest over which buoyancy can be balanced by allowing the vest to be inflated in normal operation to the inflator or to an air outlet is, wherein a pneumatic control device is provided with a control valve which activates the pneumatic control device in normal operation in response to a surrounding water pressure, so that safety-relevant parameters can be monitored via the control device and emergency measures can be introduced.

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

In general, a plurality of valves are provided in a BCD, which are provided for controlling the blowing or discharging of air into an air bubble of the vest and often also for the initiation of emergency measures. These emergency measures are initiated, for example, in the case of falling below a defined amount of compressed air in the compressed air cylinder or lack of breathing activity of the diver.

From the WO2007 / 058615 A1 Diving equipment emerges, which consists of a buoyancy compensator and a compressed air source in the form of a compressed air cylinder, and a valve assembly for controlling a compressed air supply from the compressed air cylinder to Tarjacket is composed. The buoyancy compensates buoyancy of a diver by inflating the vest in normal operation, either through the compressed air cylinder or by releasing compressed air from the vest. The valve arrangement in this case comprises a pneumatic control device, by means of which can be transferred from the normal operation in an emergency operation. For this purpose, the pneumatic control device has a control valve which activates the control device as a function of an ambient water pressure. Furthermore, the pneumatic control device has a time control unit, which is composed of a diaphragm valve and delay means. Upon activation of the control device via the control valve, the diaphragm valve is acted upon with compressed air from the compressed air cylinder and forwards the compressed air via a first working line to the delay means. If a breath is now taken by the diver on the breathing apparatus, the compressed air conducted to the diaphragm valve is continued via a second working line to the delay means, wherein the pressure supply via the second working line causes a reset of the delay means. However, if the diver does not take a breath on the breathing apparatus over a period of time defined by the delay means, then the delay means actuates an emergency valve via a control line, which thereby connects the vest to the compressed air cylinder and thus forces it to inflate. As a result, the supposedly non-breathing diver is then transported back to the water surface.

The WO 2008/143581 A1 describes a safety device and method for scuba diving, in which a diving equipment according to the preamble of claim 1 is shown.

Starting from the above-described prior art, it is now the object of the present invention to provide a diving equipment, in which a proper operation of safety-related functions can be determined.

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

According to the invention, diving equipment comprises an inflatable vest and a pneumatic control device as defined in claim 1. In the context of the invention, an activation of the pneumatic control device takes place, in particular, by the control valve located in front of it, by the control valve setting the surrounding water pressure in relation to a reference pressure, preferably the atmospheric pressure, and connecting the control device to the compressed air source when the reference pressure is exceeded.

The invention now includes the technical teaching that the pneumatic control device is connected to a test device, via which a functional capability of the pneumatic control device can be checked. In other words, in addition to the pneumatic control device, a further device of the diving equipment is provided, via which a proper function of the control device can be established and thus the monitoring of the safety-relevant parameters and a possible initiation of emergency measures can be ensured. Such a configuration has the advantage that the diver is thereby given the opportunity to monitor the proper function of the pneumatic control device of his equipment, so that safety-critical situations can be avoided. In particular, in this case a proper operation of a respiratory monitoring function of the control device can be checked, which initiates emergency measures in the form of inflation of the vest in the absence of respiratory activity after expiry of a time window defined by a time control unit, whereby the diver can be transported back to the water surface.

For the purposes of the invention, the test device may comprise functional elements for checking the functionality of the pneumatic control device in advance of a dive, functional elements for determining proper operation of the control device during diving, or a combination of both.

According to an advantageous embodiment of the invention, the test device comprises a pre-test valve, in its normal position in normal operation, a control line of the control valve is acted upon by the surrounding water pressure. On the other hand that can Pre-test valve are transferred in a test operation in an operating position in which the control line of the control valve is connected to the compressed air source and thus a transfer of the control valve is forced into an actuating position. In this operating position then the pneumatic control device is connected to the compressed air source. By means of such a configuration, it is possible to check already at the water surface, whether the pneumatic control device is working properly. Because in normal operation, the pneumatic control device is activated by the control valve in response to a surrounding water pressure, ie only after reaching a defined depth. By Vorzusestventil this immersion depth-dependent activation can now be overridden by the transfer of the control valve forced into the operating position and thus the control device is activated by connecting to the compressed air source.

In a further development of this embodiment, the pretesting valve has an actuating element, via which the pretesting valve can be transferred into the actuating position counter to a spring element. In this way, by selective operation, the test function of Vorabtestventils be started. In the context of the invention, the actuating element can be designed here as a push button, switch or the like. Preferably, however, the actuating element can be actuated only via a corresponding tool, which prevents an accidental triggering, for example when transporting the diving equipment, can occur.

According to an alternative or supplementary variant to the previous embodiments, the test device comprises a display element, which communicates with the control valve and via which an actuating position of the control valve can be displayed. This has the advantage that the diver can thus detect under water or in combination with the Vorabtestventil via water, whether the control valve is in the operating position. This then makes it comprehensible to the diver whether an activation of the pneumatic control device has already taken place and whether, accordingly, safety-related functions of the dive equipment are already being monitored. This can also be done by a dive partner or instructor.

In a further development of this embodiment, the display element is designed as a piston displaceably guided in a cylinder housing, wherein the piston is provided on one end side with a piston rod, whereas the piston on another, opposite end side via a control line can be acted upon with pressure and converted into an ad position, in which the piston rod protrudes through the cylinder housing. The control line is connected to an outgoing from the control valve working line, which is coupled in the operating position of the control valve to the pressure source. In such an embodiment, therefore, the control line leading to the cylinder housing is pressurized as soon as the control valve has been moved to the actuating position, so that the piston is displaced into the display position and the piston rod projects beyond the cylinder housing. In this position, the piston rod can then be felt by the diver, so that it can check an activation of the pneumatic control device even in poor visibility.

According to the invention, a line branches off from the cylinder housing on the end face of the piston provided with the piston rod, which line is in communication with the vest. As a result, air can escape during movement of the piston from the cylinder housing in this line, so that the piston can be moved with little resistance.

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

Further, advantageous embodiments of the invention will become apparent from the following description of a preferred embodiment of the invention, which refers to the figure shown in the drawing.

The sole figure shows a block diagram of a diving equipment according to a preferred embodiment of the invention. In this case, this diving equipment comprises a compressed air source 1 in the form of a compressed air cylinder, which supplies compressed air to a respirator, which is not further described here, so that a diver is supplied with breathing air under water can. Furthermore, an inflatable vest 2 is provided which is provided with a - also not shown here - bubble, which can either be inflated by the compressed air source 1 with compressed air or discharged from the air. According to the supply or discharge of air, a buoyancy of the diver can be compensated by the vest 2 by a rise and by discharging air, a drop is represented by supplying a corresponding amount of air.

In a normal operation, the supply and discharge of air into the vest 2 is here controlled by intermediate valves in the form of an inflation valve 3 and a drain valve 4, which can be actuated respectively via an associated actuator 5 and 6 by the diver, said adjusting elements. 5 and 6 in the present case are each designed as push buttons. Both the inflation valve 3 and the drain valve 4 are designed as 2/2-way valves and are biased via an associated spring in the basic position shown here, from which they can be moved by the respective associated actuator 5 and 6 in an operating position. The inflation valve 3 connects in this operating position then the compressed air source 1 with the vest 2, so that the vest 2 is inflated by supplying compressed air. On the other hand, upon actuation of the control element 6 and transfer of the drain valve 4 in the operating position, the vest 2 is connected to a mouthpiece 7, via which compressed air from the vest 2 escape into the environment and thus a discharge of compressed air from the vest 2 can be displayed. In addition, can be made on the mouthpiece 7 but also a manual filling of the vest 2 in an individual case. According to an actuation of the two valves 3 and 4, the diver can balance his buoyancy according to the filling or emptying of the vest 2.

Furthermore, the diving equipment according to the invention has a pneumatic control device 8, by which safety-relevant parameters of the diving equipment are monitored and targeted emergency measures can be initiated. Thus, the control device 8 monitors a breathing activity of the diver on the breathing apparatus, in the absence of a breathing activity of the diver in an emergency operation and forced inflation of the vest 2, so that the diver is transported as a result of inflation to the water surface. For this purpose, the control device 8 has an emergency valve 9, which in the present case is also designed as a 2/2-way valve and in an operating position, the compressed air source 1 connects directly to the vest 2, so that a Inflating the vest 2 is done. In the illustrated basic position of the emergency valve 9, however, this connection is interrupted, wherein the emergency valve 9 is biased by an associated spring element and by pressurization by means of a control line 10 in this basic position. The control line 10 is in this case supplied by a pressure port 11 with the currently surrounding water pressure. Contrary to the spring element and the control line 10, the emergency valve 9 can be moved and held by corresponding pressure in two further control lines 12 and 13 in the operating position, the control line 12 is in communication with a time control unit 14, while the control line 13 to the drain side of the emergency valve 9 and the supply to the vest 2 is connected. To move the emergency valve 9 in the operating position so 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 once moved into the actuation position, it is held in this position by the control line 13 due to the additional pressure then acting via the control line 13.

By the time control unit 14, a time window is defined, after which elapse and in the absence of breathing activity of the diver, the control line 12 is acted upon by a suitable opening for the emergency valve 9 pressure. For this purpose, the time control unit 14 comprises a control volume 15, which is filled continuously from an activation of the control device 8 via a filling panel 16 with pressurized air, wherein the control volume 15 is connected to the control line 12 of the emergency valve 9. From reaching a certain pressure in the control volume 15 while an actuating pressure is shown, which results in a displacement of the emergency valve 9 in the operating position. On the outlet side of the control volume 15, an emptying valve 17 is also provided, which is designed as a 2/2-way valve and is moved in respiratory activity of the diver and a concomitant pressure drop in the line system connected to the compressed air source 1 from the illustrated basic position into an actuating position. In this operating position, the control volume 15 is then emptied and the filling process starts again. In this case, a time range can be defined according to the choice of a suitable volume of the control volume 15 and a suitable throttling on the Füllblende 16, after its expiry an emergency operation by the control device 8 by driving the emergency valve 9 is initiated.

For activation, the control device 8 has a control valve 18, which activates the control device 8 as a function of the currently surrounding water pressure. For this purpose, the control valve 18 is connected in normal operation on the one hand via a control line 19 to the pressure port 11 and is thus acted upon via this control line 19 with the surrounding water pressure. On the other hand, the control valve 18 is coupled via a reference line 20 with a reference volume 21, in which a reference pressure, in this case the atmospheric pressure prevails. The present as a 2/2-way valve designed control valve 18 separates the underlying time control unit 14 in the illustrated basic position of a supply line 22, the control valve 18 but then connects in an operating position this supply line 22 to the time control unit 14, as soon as the surrounding water pressure in the pressure Reference volume 21 and has exceeded a pressure represented by a spring element of the control valve 18. In this case, the supply line 22 is connected to the compressed air source 1, so that in the operating position of the control valve 18 compressed air flows to the filler panel 16 of the time control unit 14. Consequently, therefore, the control device 8 is activated by the control valve 18 from reaching a defined water depth.

As a special feature, the diving equipment now also includes a testing device 23, via which a functionality of the control device 8 and thus a proper monitoring of safety-related parameters of the diving equipment can be tested. This test device 23 in this case has a pre-test valve 24, which is in the present case designed as a 3/2-way valve and in normal operation in the illustrated basic position, the control line 19 of the control valve 18 with the surrounding water pressure leading pressure port 11 connects. Accordingly, in the initial position of the pre-test valve 24, as already described above, the control valve 8 activates the control device 8 when the pressure in the reference volume 21 is exceeded by the surrounding water pressure. In addition, the pretesting valve 24 can be deliberately transferred into an actuated position against a spring element via an actuating element 25 in the form of a pushbutton, thereby initiating a test operation in which the control line 19 of the control valve 18 is connected by the pretesting valve 24 to a pressure line 26. This pressure line 26 is coupled to the compressed air source 1, so that the control valve 18 is supplied on the control side with compressed air and thus a movement of the control valve 18 is forced into the operating position. As a result, the control device 8 is activated so that the respiratory monitoring function of Kontrollirichtung 8 regardless of the depth of water starts. Thus, the diver can check by operating the actuator 25 before the dive, whether the control device 8 and in particular the respiratory monitoring function with the time control unit 14 work properly.

In the present case, the actuator 25 is designed as a normal push button. For the purposes of the invention, however, the actuating element 25 can also be configured such that its actuation is possible only via a tool corresponding thereto. In this way it can be prevented that the pre-scan valve 25 is actuated unintentionally, for example during transport of the diving equipment, and as a consequence an unwanted activation of the respiratory monitoring function of the control device 8 occurs.

As can also be seen from the single figure, the test device 23 also has a display element 27, which is formed by a piston 29 displaceably guided in a cylinder housing 28. The piston 29 is provided on one end side with a piston rod 30 which is guided on a piston 29 remote from the end in a - not shown here - through bore of the cylinder housing 28 and depending on the position of the piston 29 in the cylinder housing 28 through the cylinder housing 28 protrudes through. In addition, the piston 29 is biased by a spring element in the apparent from the single figure basic position.

On a side facing away from the piston rod 30 side of the piston 29, a control line 31 opens into the cylinder housing 28, which branches off from an outgoing from the control valve 18 and leading to the filler panel 16 working line. About this control line 31, the piston 29 is pressurized in the operating position of the control valve 18 and an associated flow of compressed air via the control valve 18 and subsequently moved against the spring element from the position shown in an ad position in which the piston rod 30 then on the outside over the cylinder housing 28 projects. Accordingly, the diver can feel underwater during diving and also in poor visibility conditions that the control device 8 has been activated via the control valve 18.

Further branches from the cylinder housing 28 on the side of the piston rod 30 from another line 32, which leads into a leading from the vest 2 to the drain valve 4 connecting line 33 opens. Via this line 32, air can escape from the cylinder housing 28 during movement of the piston 29, so that the piston 29 can be displaced with little resistance.

By means of the inventive design of a diving equipment, it is possible to check a proper function of a pneumatic control device 8 before or during the dipping process and thus to increase safety.

LIST OF REFERENCE NUMBERS

1

Compressed air source

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

control valve

19

control line

20

reference line

21

reference volume

22

supply line

23

test equipment

24

Preliminary test valve

25

actuator

26

pressure line

27

display element

28

cylinder housing

29

piston

30

piston rod

31

control line

32

management

33

connecting line

Claims (6)

1. Diving equipment, with an inflatable vest (2) for equilibrating buoyancy through connection of the vest (2) in normal operation to a pressurized air source (1) for inflation or to an outlet for discharging of air, and
   a pneumatic controller (8) for monitoring a breathing activity at a breathing device connected to the pressurized air source (1),
   wherein the pneumatic controller (8) has a control valve (18) that activates the pneumatic controller (8) in normal operation as a function of a surrounding water pressure, whereby a breathing activity at the breathing device can be monitored via the controller (8) and, in the absence of breathing activity at the breathing device, an emergency mode can be initiated, and
   wherein the pneumatic controller (8) is connected to a tester (23) for checking the functioning of the control valve (18),
   characterized in that
   the tester (23) has a display element (27) that is connected to the control valve (18) and through which an operating position of the control valve (18) can be displayed, and/or a pre-test valve (24), which pre-test valve (24) is embodied in a test mode so as to force switching of the control valve (18) to an operating position in which the pneumatic controller (8) is activated through connection to the pressurized air source (1).
2. Diving equipment as set forth in claim 1,
   characterized in that, in the pre-test valve (24) in its home position in normal operation, a control line (19) of the control valve (18) is exposed to the surrounding water pressure, whereas the pre-test valve (24) can be switched in a test mode to an operating position in which the control line (19) of the control valve (18) is connected to the pressurized air source (1), thus forcing the switching of the control valve (18) into an operating position in which the pneumatic controller (8) is activated through connection to the pressurized air source (1).
3. Diving equipment as set forth in claim 2,
   characterized in that the pre-test valve (24) has an actuating element (25) through which the pre-test valve (24) can be switched against a spring member into the operating position.
4. Diving equipment as set forth in claim 3,
   characterized in that the actuating element (25) can only be actuated via a corresponding tool.
5. Diving equipment as set forth in claim 4,
   characterized in that the display element (27) is embodied as a piston (29) slidably guided in a cylindrical housing (28), wherein the piston (29) is provided on a front side with a piston rod (30), whereas the piston (29) on the other, opposing front side can be exposed to pressure via a control line (31) and moved into a display position in which the piston rod (30) projects through the cylindrical housing (28), the control line (31) being connected to an active line which is coupled with the pressure source (1) in the operating position of the control valve (18).
6. Diving equipment as set forth in claim 5, characterized in that a line (32) that is connected to the vest (2) branches off from the cylindrical housing (28) on the front side of the piston (29) provided with the piston rod (30).

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