DE102011107028A1 - diving equipment - Google Patents

Abstract

The invention relates to a diving equipment, comprising a compressed air source (1), which communicates with a breathing apparatus, and an inflatable vest (2) over which a buoyancy is ausarierbar by the vest (2) in normal operation with the compressed air source (1) for inflating or connectable with an outlet for venting air. In addition, a control device (8) with a time control unit (9) is provided, which can be activated by connecting to the compressed air source (1) and has pneumatic delay means. After a defined period of time and absence of respiratory activity, the pneumatic deceleration devices transfer to an emergency mode on the breathing apparatus and move an emergency valve (18) via a first control line (19) to an emergency position, in this position the vest (2) with the compressed air source (1) connects and thus forces inflation of the vest (2). In order to always represent a constant transfer into emergency mode regardless of a diving depth, the emergency valve (18) has a second control line (20) which is acted upon by a surrounding water pressure and performs a control opposite to the first control line (19). In this case, the control via the second control line (20) with respect to a control via the first control line (19) is disproportionate.

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 connected to the compressed air source for inflation or to an outlet for discharging air during normal operation wherein a control device is provided with a time control unit which can be activated by connecting to the compressed air cylinder and has pneumatic delay means, wherein the pneumatic delay means after a defined time and in the absence of a respiratory activity on the respirator in an emergency operation transfer and an emergency valve on a first Move control line in an emergency position, which connects the vest in this position with the compressed air source and thus forces an inflation of the vest.

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

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 emerges a diving equipment, which is composed 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 the buoyancy compensator. 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 control device, by means of which can be changed over from the normal operation in an emergency operation. For this purpose, a control valve is provided which activates the control device in dependence on an ambient water pressure. The control device has a time control unit, which is composed of a diaphragm valve and pneumatic 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, the delay means actuates an emergency valve via a control line, thereby connecting the vest to the compressed air cylinder and thus forcing it to inflate. As a result, the supposedly non-breathing diver is then transported back to the water surface.

Starting from the above-described prior art, it is now the object of the present invention to provide a diving equipment available, in which, regardless of the depth always a constant period is defined, is passed after its elapse and lack of respiratory activity in an emergency operation.

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 includes a compressed air source communicating with a respirator and also has an inflatable vest over which buoyancy can be balanced by operating the vest in normal operation with the inflator for inflating or with an outlet for venting air is connected. Furthermore, a control device with a time control unit is provided, which is activated by connection to the compressed air source and has pneumatic delay means. By the pneumatic delay means is transferred after a defined time and in the absence of a respiratory activity on the breathing apparatus in an emergency operation and in this case an emergency valve is moved via a first control line in an emergency position. The emergency valve then connects the vest with the compressed air source and thus forces an inflation of the vest. For the purposes of the invention, the time control unit is activated by a 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 the time control unit is connected to the compressed air source when the reference pressure is exceeded.

The invention now includes the technical teaching that the emergency valve via a second Control line has, which is acted upon by a surrounding water pressure and performs a control opposite to the first control line, wherein the control via the second control line with respect to a control via the first control line is disproportionate. In other words, therefore, a second control line is provided, via which the emergency valve is moved when pressure is applied in the direction of a basic position. In this case, the second control line is acted upon by the surrounding water pressure, so that acts on the part of the second control line, a pressure in the amount of the current surrounding water pressure on a corresponding control side of the emergency valve. In this case, a control via this second control line is disproportionate compared to a control via the first control line, ie at the same prevailing pressure in both control lines would cause a strong control of the emergency valve and this thus actuated in the direction of the basic position via the second control line. Background of the embodiment of the invention is that with increasing the depth of the pressure of the compressed air source increases by the amount of the surrounding rising water pressure. This is done in order to keep the pressure prevailing in the respective lines of the diving equipment always at a constant level to the surrounding water pressure. By this coupling of the pressure of the compressed air source, however, the time window defined by the time control unit is influenced, so that the time to transfer the control device into the emergency operation and the forced inflation of the vest in case of absence of a respiratory activity is shortened with increasing the depth. This can then occasionally lead to a surprise for the diver, early inflation of the vest takes place.

By means of the embodiment of the invention, the second control line is now subjected to a pressure in the amount of the surrounding water pressure, which eliminates the pressure component in the amount of the surrounding water pressure on the part of the first control line due to the opposite control to the first control line. However, this alone would not effect a time-constant transfer to the emergency operation regardless of the depth, since the compressed air source side coupling with the surrounding water pressure also influences a flow behavior of the compressed air via the pneumatic retarder. Thus, with increasing pressure of the compressed air source filling times of the pneumatic delay means change, which also has an influence on the size of the time window of the time control unit until initiation of the emergency operation. Because in the pneumatic delay means usually the time window is defined by continuously filling a corresponding volume. This filling time is now in physical relation to the pressure source side pressure, as higher flow rates and thus faster filling takes place by a higher pressure. This aspect is now compensated for by the fact that, on the part of the second control line, a disproportionate activation takes place in comparison with an activation via the first control line. As a result of this measure, the filling time shortening of the pneumatic retarding means occurring with increasing depth of immersion and a concomitant reduction in the time window of the time control unit in the area of the emergency valve are compensated for. As a result, a constant time can be achieved until the emergency valve is transferred to the emergency position independently of the surrounding water pressure.

In contrast, at the WO 2007/058615 A1 no such compensation is made, so that with increasing depth the defined time window of the time control unit is steadily reduced by the triggering time of the delay means is influenced by the proportional to the surrounding water pressure increasing pressure of the compressed air source. As a result, with increasing depth in the absence of a breathing activity of the emergency operation is always initiated earlier, so that it may come to an unwanted inflation of the vest under certain circumstances.

According to an advantageous embodiment of the invention, the control lines are in each case associated with a respective associated control surface of the emergency valve, wherein a control surface assigned to the second control line is larger than a control surface of the first control line. By such a design of the associated control surfaces can be represented over the second control line in a reliable manner, the disproportionate control. In this case, the control surfaces are preferably configured in each case by an associated frontal piston surface of a displaceable piston of the emergency valve. Alternatively, however, a definition of the different control surfaces can also be represented by designing corresponding membranes.

In a further development of the invention, a pressure regulator is provided between the compressed air source and the delay means. Such an embodiment has the advantage that an influence on the delay means can be compensated by different pressure on the input side by the pressure regulator. For even a different filling pressure of the compressed air cylinder of the compressed air source causes different triggering times of the delay means of the time control unit, so that depending on the pressure level, a different early triggering of emergency operation can occur, which is not for the user of the respective diving equipment is predictable and can lead to an unwanted inflation of the vest. Thus, using a compressed air cylinder with a higher inflation pressure would again reduce the window of time until emergency operation is initiated. By the intermediate pressure regulator, the pressure source side pressure can now be set to a constant pressure level, regardless of the particular compressed air cylinder used, so that the pressure prevailing in the respective compressed air cylinder pressure does not affect the operation of the pneumatic retarder.

According to the invention, the pneumatic retarding means comprise a filling diaphragm, which is placed between the compressed air source and a control volume and allows a throttled flow of pressurized fluid into the control volume from activation of the pneumatic retarding means, wherein the pressure regulator is arranged immediately in front of the filling diaphragm. By means of such an embodiment of the pneumatic delay means, a time window can be defined in a reliable manner, beyond which, if the respiratory activity is not exceeded, it is transferred into the emergency mode. Because by providing a filler panel, which flows from activation of the control device continuously pressurized fluid in the downstream control volume, the desired time window of the pneumatic retarder can be reliably defined according to the throttling on the filler panel and the size of the control volume.

According to an advantageous embodiment of the two aforementioned embodiments of the pressure regulator is designed as a pressure relief valve. In this case, this pressure limiting valve is placed in such a way that, when a specified pressure is exceeded, compressed air is removed via a bypass lying parallel to the pneumatic retardation means. Advantageously, this can be done in a simple manner, an adjustment of the compressed air source side pressure.

The invention is not limited to the specified combination of the features of the main claim or the dependent claims. It also results in ways to combine individual features, even if they emerge from the claims, the following description of an embodiment or directly from the drawings. The reference of the claims to the drawings 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 figures shown in the drawings. It shows:

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

2 a schematic representation in the area of an emergency valve according to the diving equipment 1 ,

Out 1 is a block diagram of a diving equipment according to a preferred embodiment of the invention. This diving equipment includes a compressed air source 1 which supplies compressed air to a breathing apparatus, not shown here, so that a diver can be supplied with breathing air under water. This is this source of compressed air 1 formed by a - also not shown here - compressed air cylinder, wherein a pressure of the compressed air cylinder is thereby increased when using the diving equipment to the surrounding water pressure, so that in lines of the diving equipment always a constant pressure level compared to the surrounding water pressure is present.

Furthermore, an inflatable vest 2 provided, which is provided with an air bubble, said bubble either by the compressed air source 1 inflated with compressed air or specifically air can be discharged from this. About this a buoyancy of the diver can be balanced, in which by deliberately supplying a corresponding amount of air an increase and by discharging air, a drop is represented.

In normal operation, the supply and discharge of air into the vest 2 in this case via intermediate valves in the form of an inflation valve 3 and a drain valve 4 controlled, which in each case via an associated control element 5 respectively. 6 can be operated by the diver. These control elements are present 5 and 6 each designed as a push button, in its respective actuation of the inflation valve 3 or the drain valve 4 can be moved in an operating position. Both the inflation valve 3 as well as the drain valve 4 are designed as 2/2-way valves and are biased in each case via an associated spring in a basic position shown here, from which they then by pressing the associated control element 5 respectively. 6 can be moved into the operating position. In the operating position, the inflation valve connects 3 then the compressed air source 1 with the vest 2 so the vest 2 is inflated by supplying compressed air. On the other hand, upon actuation of the actuating element 6 and a transfer of the drain valve 4 in the Operating position the vest 2 with a mouthpiece 7 connected, via which compressed air from the vest 2 escape into the environment and thus a release of compressed air from the vest 2 is representable. In addition, over the mouthpiece 7 but also a manual filling of the vest 2 be made on an individual basis. According to an actuation of the two valves 3 and 4 So the diver can increase his lift according to the filling or emptying of the vest 2 austarieren.

As further out 1 it can be seen, the diving equipment according to the invention has a control device 8th , detected by which a lack of breathing activity of the diver on the respirator and in this case deliberately transferred to emergency operation and 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, has the control device 8th via a time control unit 9 , over which a time is defined, after the expiration of the absence of the breathing activity is transferred to the breathing apparatus in said emergency operation. The time control unit 9 It has pneumatic retarder, which in this case by a filler 10 , a control volume 11 and an emptying valve 12 are formed. From activation of the time control unit 9 becomes the control volume 11 over the filler panel 10 continuously filled with pressurized air, wherein the respiratory activity of the diver and a concomitant pressure drop in the compressed air source 1 connected piping system via the drain valve 12 an emptying of the control volume 1 is made. This is the drain side to the control volume 11 provided emptying valve 12 also designed as a 2/2-way valve and the control side so with the compressed air source 1 coupled, that when a breath of the diver on the breathing apparatus on a control side of said pressure drop occurs and subsequently the emptying valve 12 in the control volume 11 emptying operating position is moved. The time range until the transfer in the emergency operation is thereby by a suitable choice of a volume of the control volume 11 and a restriction on the filler panel 10 defined, since these parameters specify in the interaction, starting when with continuous filling of the control volume 11 over the filler panel 10 a defined pressure in the control volume 11 is reached. The achievement of this defined pressure indicates the time from which is transferred to the emergency operation.

To activate the control device 8th is the time control unit 9 a control valve 13 upstream, which is the control device 8th activated depending on the current surrounding water pressure. For this purpose, the control valve 13 on the one hand via a control line 14 with a pressure connection 15 connected, via which the control valve 13 is acted upon by the surrounding water pressure. The other is the control valve 13 still over another control line 16 with a reference volume 17 connected, in which a reference pressure prevails, preferably the atmospheric pressure. The present as a 2/2-way valve designed control valve 13 separates the time control unit behind it 9 in the illustrated basic position of the compressed air source 1 , where the control valve 13 but then transferred to an actuating position as soon as the surrounding water pressure the pressure in the reference volume 17 and one by a spring element of the control valve 13 has exceeded the pressure shown. In this operating position then the time control unit 9 with the compressed air source 1 connected so that compressed air to the filler panel 10 can flow. Consequently, therefore, the control device 8th from reaching a defined depth of water through the control valve 13 activated.

For transfer to emergency operation with the result of inflation of the vest 2 includes the control device 8th Furthermore, an emergency valve 18 , Which in the present case is also designed as a 2/2-way valve and in an operating position, the compressed air source 1 directly with the vest 2 connects, thereby doing a bloat of the vest 2 is made. To transfer to this operating position is the emergency valve 18 via a first control line 19 with the time control unit 9 connected, this first control line 19 between the control volume 11 and the drain valve 12 branches. On the opposite side to the first control line 19 is the emergency valve 18 however still over a second control line 20 controllable and also provided with a spring element, which is a transfer of the emergency valve 18 in the operating position opposes a corresponding resistance.

Over the second control line 20 is doing a compensation of the part of the first control line 19 reached with increasing depth of increasing pressure. Because due to the coupling of the compressed air source 1 shown pressure with the surrounding water pressure to keep the already mentioned in advance pressure level in lines of diving equipment relative to the surrounding water pressure constant, with increasing depth by the time control unit 9 specified time windows shortened. This is related to the fact that due to the higher pressure in the control volume 11 inflowing compressed air earlier the trigger pressure in the control volume 11 is achieved, resulting in a previous transfer of the emergency valve 18 would result in the operating position. Thus, that now on a to the first control line 19 opposite side of the emergency valve 18 the second control line 20 a Control of the emergency valve 18 takes place with a pressure equal to the surrounding water pressure, this proportion of pressure in the area of the emergency valve 18 over the second control line 20 compensated. Overall, this will be the emergency valve 18 moved to the operating position when a control of the emergency valve 18 over the first control line 19 greater fails than a control of the emergency valve 18 over the second control line 20 and in addition a force caused by the spring element is exceeded. Is the emergency valve 18 then once moved to the operating position, it will be through another control line 21 held in this position due to the then prevailing pressure.

As a special feature, however, now takes place via the second control line 20 with respect to a control via the first control line 19 a disproportionate control of the emergency valve 18 , Because although by providing the second control line 20 the pressure component at the level of the surrounding water pressure compensates, a flow behavior of the compressed air in the time control unit 9 but changes due to the increasing pressure with increasing depth, which in addition to a variation by the time control unit 9 defined time leads. With increasing pressure of the compressed air, namely, the flow of compressed air changes over the filler panel 10 by putting a high flow in the filler panel at a higher pressure 10 and thus a shorter filling time of the control volume 11 is pictured. Thus, by this faster filling of the control volume 11 also for transferring the emergency valve 18 reached in the operating position predetermined release pressure earlier and thus defined with increasing depth shorter tripping times. This circumstance is now counteracted by a control via the second control line 20 disproportionately with respect to a control via the first control line 19 is so on the part of the second control line 20 More than just the surrounding water pressure is compensated. This then has the overall result that with increasing depth of immersion due to the changing flow behavior of the compressed air on the filler panel 10 caused influence on the triggering of the emergency valve 18 is also compensated. As a result, this is what the time control unit does 9 defined time window independent of the diving depth constant.

With regard to the concrete representation of the disproportionate control via the second control line 20 will be the next one 2 taken to the rescue. How out 2 is apparent, is the part of the second control line 20 a control surface 22 designed larger than a control surface 23 from the first control line 19 , For this purpose, a front-side piston surface 24 on the side of the second control line 20 chosen larger than a frontal control surface 25 from the first control line 19 ,

As another special feature is parallel to the time control unit 9 a bypass 26 designed in which a pressure regulator in the form of a pressure relief valve 27 is provided. This bypass 26 branches between the control valve 13 and the filler panel 10 off and leads when opening the pressure relief valve 27 Compressed air directly to the vest 2 , By means of the bypass 26 and the pressure relief valve 27 can thus an input-side pressure of the time control unit 9 be limited to a defined extent, so that the unwanted influence of different filling pressures of compressed air cylinders by the compressed air source 1 can be prevented. Because this ensures that the input side of the time control unit 9 a certain pressure level is not exceeded and thus does not lead to an unwanted shortening of the by the time control unit 9 defined time window comes.

By means of the inventive design of a diving equipment, it is thus possible, a transfer to an emergency operation via the control device 8th regardless of the depth of immersion to take place within a constant time window.

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

Time control unit

10

filler panel

11

control volume

12

drain

13

control valve

14

control line

15

pressure connection

16

control line

17

reference volume

18

emergency valve

19

first control line

20

second control line

21

further control line

22

control surface

23

control surface

24

piston area

25

piston area

26

bypass

27

Pressure relief valve

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2007/058615 A1 [0004, 0010]

Claims (6)

Diving equipment comprising a compressed air source ( 1 ), which is in communication with a breathing apparatus, and an inflatable vest ( 2 ), over which a buoyancy can be balanced by the vest ( 2 ) in normal operation with the compressed air source ( 1 ) for inflating or is connectable to an outlet for discharging air, wherein a control device ( 8th ) with a time control unit ( 9 ), which by connecting to the compressed air source ( 1 ) is activated and has pneumatic delay means, wherein the pneumatic delay means after a defined time and in the absence of a respiratory activity on the respirator in an emergency operation transfer and an emergency valve ( 18 ) via a first control line ( 19 ) in an emergency position, the vest in this position ( 2 ) with the compressed air source ( 1 ) and thus inflating the vest ( 2 ), characterized in that the emergency valve ( 18 ) via a second control line ( 20 ), which is acted upon by a surrounding water pressure and one to the first control line ( 19 ) performs opposite control, wherein the control via the second control line ( 20 ) with regard to activation via the first control line ( 19 ) is disproportionate. Diving equipment according to claim 1, characterized in that the control lines ( 19 . 20 ) each with an associated control surface ( 22 . 23 ) of the emergency valve ( 18 ), wherein one of the second control line ( 20 ) associated control surface ( 22 ) is larger than a control surface ( 23 ) of the first control line ( 19 ). Diving equipment according to claim 2, characterized in that the control surfaces ( 22 . 23 ) in each case by an associated front-side piston surface ( 24 . 25 ) of a displaceable piston of the emergency valve ( 18 ) are configured. Diving equipment according to claim 1, characterized in that between the compressed air source ( 1 ) and the pneumatic delay means a pressure regulator is provided. Diving equipment according to claim 4, characterized in that the pneumatic retarding means comprise a filling diaphragm ( 10 ), which between the compressed air source ( 1 ) and a control volume ( 11 ) and from the activation of the pneumatic retarding means a throttled flow of pressurized fluid into the control volume ( 11 ), with the pressure regulator immediately before the filler panel ( 10 ) is arranged. Diving equipment according to claim 4 or 5, characterized in that the pressure regulator as a pressure relief valve ( 27 ) which is arranged in a bypass (parallel to the pneumatic retardation means ( 26 ) is placed.

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