NO742304L - - Google Patents

Description

Breathing apparatus for divers

The present invention relates to a breathing apparatus of that type

where the user breathes in from a breathing bag to which oxygen is fed from a pressure bottle and breathes out into the bag through a carbon dioxide absorber. Such devices are widely used by divers, and there is little or no release of exhaust bubbles from the system that can call out the diver's location.

A major disadvantage of known breathing devices of this type is that the last part of the exhaled gas has not passed through the absorber when the user starts to breathe in again. Consequently, this last volume of gas will be inhaled in an untreated state. It is a main object of the present invention to ensure that practically no gas that has just been breathed out will be breathed in again and that virtually all exhaled gas will pass

through the absorber at least twice.

For this purpose, according to the invention, a breathing apparatus is proposed which comprises two gas line sloifs which have a part in common over part of their length, which part is adapted to receive a gas-purifying substance, means which only allow gas movement in one direction through the sloifs, a nozzle arranged in one of the sloyfs, a gas-tight, inflatable bag forming part of the other sloyf and means for releasing gas to the apparatus.

In order to make it easier to understand the invention, two preferred embodiments will be described with reference to the drawing, where

fig. 1 shows a schematic arrangement of a breathing apparatus according to an embodiment of the invention,

fig. 2 shows an end view of a box which forms the common part for the two sloifs for the device according to fig. 1,

fig. 3 is a section of the box according to fig. 2, taken along line 3-3 in fig. 2P

fig. 4 is a partial section along the line 4-4 in fig. 2,

fig. 5 is a side view of an adjustable pressure relief valve provided on the inflatable, gas-tight bag for the apparatus shown in FIG. 1,

fig. 6 is a plan view of the valve according to fig. 5,

fig. 7 is a section along the line 7-7 of the valve in fig. 6,

fig. 8 is a partial section similar to fig. 3,

fig. 9 is an end view of the box shown in FIG. 8, seen in the direction indicated by the line 9-9 in fig. 8,

fig. 10 is an end section along the line 10-10 in fig. 8,

fig. 11 is an end view along the line 11-11 in fig. 8,

fig. 12 is a longitudinal section on a larger scale along the line 12-12 in fig. 8 and

fig. 13 is a section along the line 13-13 in fig. 8.

From fig. 1-7 it can be seen that the nozzle 1 of the breathing apparatus is in connection with ports 9 and 10 in a box 5 via non-return valves 2 and 3 and a flexible breathing hose 4. This device constitutes the first of the two gas line slbyfers. The second sloyf contains a gas-tight, inflatable bag 6 which opens towards the box by means of ports 7 and 8. In this way, the box forms the common part for the two gas-line sloyfers mentioned above.

The arrangement of check valves 2 and 3 in this particular embodiment ensures that any gas in the nozzle slough can only be moved in a clockwise direction around the circuit, while movement in the bag slough as shown is similarly restricted to a counter-clockwise direction by means of check valves 7 and 8 .

During operation, the box 5 is filled with an optional, suitable carbon dioxide absorbent and a separate oxygen cylinder 13 is, as shown at 11, via a pressure reduction valve 12 connected to the box. The latter valve will release just as much oxygen as is needed to replace the oxygen used up in the user's respiratory system, when the carbon dioxide he produces is gradually absorbed by the absorbent in the box.

When the user breathes in through the mouthpiece 1, the pressure in the system will be reduced and oxygen will pass through the pressure reduction valve 12 which allows a constant amount to pass, and into the box at connection 11. From here the oxygen will pass out of the box to the mouthpiece through the opening 10, follows a counter-clockwise path through the hose 4. Due to the arranged non-return valves 2 and 3, the exhaled gas will. return to the box via port 9, as check valve 3 is now closed. The increased pressure in the box will close check valve 7. In this condition, with valves 3 and 7A closed, the exhaled gas is forced to pass through the absorbent in the box and then to the inflatable bag through port 8 and check valve 8A. On the next inhalation, the pressure in the box will again decrease, but now the effect of the external ambient pressure on the gas in the inflatable bag will close the check valve 8A and force the gas into the box through port 7 via the open check valve 7A. From this valve, the gas is once again forced to pass the entire length of the box through the absorbent and into the nozzle via the opening 10 and the non-return valve 3. The non-return valve 2 ensures that the last part of the last exhaled gas cannot return to the nozzle without first passing through the absorbent in the box.

It will be obvious that when the breathing apparatus is used by a diver, it will be exposed to changes in gas working pressure, when the diver's depth varies. For this purpose it is desirable to

let the system include a pressure reducing valve for regulating the gas pressure, so that it can be suitable for all kinds of operating conditions. In the embodiment shown in fig. 1, the pressure reducing valve is indicated by 17 and arranged in the inflatable gas-tight bag 6.

An example of the valve itself is reproduced in more detail in fig. .5,6 and 7.

The pressure reduction valve comprises a hollow, cylindrical body 20 which carries a pressure regulation screw 26. The screw is turned by means of a head 19 and affects an axially movable disk 24 via an appropriate spring 23. The disk 24 in turn affects a membrane 25 which rests on a perforated disk arranged in the valve body 20 by means of a 'ring nut 29. The pressure reduction valve itself is sealed in an opening in the inflatable bag 6 by means of a ring nut 21, which clamps the bag material against a flange on the valve body 20. Gas-tight sealing is promoted by the O-ring 22 which is held in an annular groove in the ring nut 21 clamping surface.

If an increase in the pressure in the inflatable bag 6 causes a greater variation of the pressure across the reduction valve 17 than a set value, the net pressure affecting the diaphragm will overcome the spring force and open the reduction valve, so that excess gas in the inflatable bag can escape into the valve body 20 and pass out through outlet openings 27. When this has happened, the spring-actuated disk 24 will force the diaphragm 25 back on its seat and thus shut off the outlet gas drum. Disc 24 has sufficient radial clearance to allow escaping gas to pass around it.

According to fig. 2 and 3, the box 5 in the present embodiment comprises a cylindrical central part 16, the open ends of which are sealed with two removable covers 15 which are attached by means of the clamping bolt 18. Removal of the covers is achieved by extending the collapsible handle 14 and unscrewing the nut 30 from bolt 18.

Each cover is provided with two ports 7 and 9 respectively. 8 and 10. Ports 7 and 8 release gas to and from the inflatable bag 6, while ports 9 and 10 are connected to the nozzle hose 4. As both covers are in principle the same in fig. 3/will it be sufficient to describe only the construction of ports 8 and 9.

The gate 9 is identical to the gate 10 and comprises a gate liner 34 which is pressed into the cover 15 against the O-ring 33 and held by the ring nut 50. This gate liner 34 also serves to hold a knurled/ring nut 35 in place, which can be rotated freely and connect the mouthpiece's air hose 4 to the box 5. This is done by screwing on a flanged sleeve 37 which is then pulled up to sealing contact with the outer surface of the port liner 34 against an O-ring 36. The O-ring 36 lies in an annular groove on the clamp - the surface for the flange sleeve 37 as a sealing aid. The inner surface of the flange sleeve 37 is threaded to receive a flanged tubular connector 39 and an O-ring 38. When these two components are screwed together, the air hose is securely clamped by the two protruding flanges, as shown in fig. 3.

The port 8 is identical to the port 7 and comprises a port liner 48 which is drawn into the cover 15 against the O-ring 47 by means of a ring nut 49 for retaining a knurled ring nut 46. A flanged plug 42 is sealed in the inflatable bag 6 by by means of an annular nut 40, which clamps the bag material against an O-ring 41 which abuts the flange in the plug 42. The knurled ring nut 46 pulls the flanged plug 42 into sealing engagement with the outer surface of the gate liner 48. In the same way as the flanged the sleeve 37 for the port 9, the flanged plug 42 has an O-ring in an annular groove on the sealing surface.

The port liner 48 and the flanged plug 42 also serve to retain a check valve 8A. The valve comprises a perforated disc 45 located in the port liner 48 and carrying a flexible membrane 44. In the embodiment shown, the permitted gas flow through the ports is that indicated by arrows, provided that the nozzle line contains non-return valves provided

as shown in fig. 1.

It should be noted that both the inflatable bag and the nozzle hoses can be easily dismantled from the box in the present embodiment by simply unscrewing the corresponding ring nut 46 or 35.

Reference is now made in particular to fig. 2 and 4. Oxygen from a container 13 is supplied to the box via a hose (not shown) which is screwed in

in a connection 11 in the upstream end cover. This position is desirable if it becomes necessary to flush the box carefully with pure oxygen.

The joint part for the two gas line sloyfers is illustrated in fig. 8 through 13. The components in fig. 8-13 which correspond to parts of the embodiment mentioned above have reference numbers which are 100 greater than the corresponding numbers in fig. 1-7. In this embodiment, the joint part is again box-shaped and comprises a cylindrical central part 116 arranged against O-rings 32 in annular sealing grooves 131 and out into the two end covers 150 and 151. The end covers are secured to the cylinder ends by means of a clamping bolt 118 and a nut 130 In this case, however, all connections with the exception of the oxygen inlet are fast to the end cover 151.

The two line sloys, which are not fully shown, are served by 4 ports 107,108,109 and 110 with the same ratio to the total

circuits like the ports in the preceding embodiment example with corresponding reference numbers. Ports 109 and 110 thus do not contain valves and are connected to the nozzle hose by means of clamps which clamp the hose in protruding, flanged

sleeves 158. Each flanged sleeve 158 is screwed into the end cover 151 and sealed against the O-ring 159.

Ports 107 and 108 are adapted for communication with the inflatable gas bag and similarly with the nozzle-sloyfe connections. The ports also include a protruding flanged sleeve part 161 which is screwed against an O-ring 163 in the end cover 151. In this case, however, each sleeve part 161 retains a non-return valve 107A or 108A, which can be of the same membrane construction as discussed above. The check valve is retained by an inner sleeve 162 which is clamped against the valve by a ring nut 164 which is screwed into a bore in the flanged sleeve 161.

The ports 108 and 110 pass completely through the end cover 151 and open towards the main part of the box/while the other ports 107 and 109 communicate with a chamber 156 which is formed in the end cover itself. The chamber in turn opens towards a hollow/cylindrical bowl 157 which is threaded at the closed end and screwed into a corresponding threaded part 160 on the tension bolt 118. When the screw connection is tightened, the cylindrical bowl is pulled into the cover 151 and sealed against an O - call 165.

The open end of the cylindrical bowl 152 is sealed over one end of a long central tube 152/ which extends almost to the second cover, where it opens into the box body. This rudder 152 also repels a pair of perforated disks 153, which

is arranged on the rudder 152 towards each end of the box and serves to hold in place the gas cleaning agent in an annular space 166 from which it cannot escape to contaminate the air passages or valves. The arrangement is such that any gas entering the box through port 107 or 109 can only reach the annular space 166 by passing through the center tube 152 and exiting the open end of the tube near the cover 150, as shown by arrows in Fig. 8 .

The general sequence of operating phases in the present embodiment is similar to that discussed in connection with fig. 1 and requires only a few brief remarks explaining the function of the miscellaneous box.

Exhaled gas will again enter the box via port 109, but will then pass through the chamber 156 in the cover 151 and into the central tube 152. After passing through the entire length of the tube, the gas exits into the annular space 166 as shown by arrows in fig. 8. From here, the gas must pass through the entire length of the annular space, where the gas-purifying substance is arranged, for the gas enters the inflatable bag through port 108 and check valve 108A.

When the diver breathes in, external water pressure will force the partially purified gas out of the inflatable bag via the check valve 107A, through the port 107 and back to the chamber 156 in the cover 151. From here the gas again goes down along the central tube 152 and completely through the cleaning material a second time for it leaves the box via port 110 on its way to the nozzle.

Oxygen ("make-up oxygen") is in this case admitted into the system through the hose connection 111 arranged in the end cover 150 at the upstream end of the box.

Although the invention has been described with reference to two particular embodiments, it will be obvious that those skilled in the art can easily find many other variations of the invention, as defined in the claims. If diaphragm non-return valves are used, they can e.g. all be arranged at a distance from the box or the common part of the gas line sloyfs, provided that the necessary gas flow pattern is determined. In a similar way, the common part must not be cylindrical and the wire sloifs must not be connected to it via one or more covers.

Claims (12)

1. Breathing apparatus, characterized in that it comprises two gas line sloyfes which share a common part over a part of its length, which part is adapted for receiving a gas purifying substance, means for only allowing unidirectional gas movement through each line sloyfe, a nozzle provided in one of the sloyfs, a gas-tight, inflatable bag forming part of the other sloyf and means for introducing oxygen to the apparatus. 2. Breathing apparatus as specified in claim 1/characterized in that the common part has the shape of a box with at least one removable end cover. 3. Breathing apparatus as stated in claim 2, characterized in that the box comprises two end covers, each of which has two ports for communication with the gas line sloys. 4. Breathing apparatus as set forth in claim 3, characterized in that the box comprises two end covers, each of which comprises two ports for communication with the gas line sloys. 5. Breathing apparatus as stated in claim 4, characterized in that each of the two ports in each end cover communicates with a different wire sloyfe. 6. Breathing apparatus as stated in claim 4, characterized in that the two ports in each cover communicate with one and the same cable sloyfe. 7. Breathing apparatus as set forth in claim 3, characterized in that both cable sloys are connected to the box via ports in one end cover. 8. Breathing apparatus as specified in claim 7, characterized in that said end cover comprises 4 ports, of which 2 are connected to a channel that opens towards the box at a point near the far end of the box. 9. Breathing apparatus as specified in one of claims 1-8, characterized in that the means for only allowing unidirectional gas movement through the sloyfe include a pair of non-return valves arranged in each sloyfe on each side of the nozzle or the gas-tight, inflatable bag and not in the joint part. 10. Breathing apparatus as stated in one of claims 1-9, characterized in that the means for supplying oxygen gas to the apparatus comprises a pressurized gas container in connection with the apparatus via a pressure reduction valve. 11. Breathing apparatus as specified in claim 10, characterized in that the oxygen gas enters the apparatus at the upstream end of the joint part. 12. Breathing apparatus as specified in one of claims 1-11, characterized in that the gas-tight, inflatable bag is provided with an adjustable pressure reduction valve.