Breathing valve assembly with diaphragm control of the exhaust ports

A breathing apparatus having an exhaust valve and a diaphragm actuated inlet valve, wherein the exhaust valve includes a sealing surface against which the diaphragm normally is sealingly engaged to close the opening and from which the diaphragm is disengaged upon exhalation to open the exhaust valve.

BACKGROUND OF THE INVENTION 
(a) Field of the Invention 
This invention relates to breathing apparatus of the type wherein breathing 
fluid is provided to a mask upon a demand evidenced by inhalation by the 
user of the mask. 
(b) History of the Prior Art 
In the prior art, demand type valves for use in conjunction with breathing 
masks have been provided which are responsive to inhalation by the mask 
user. In one type of such mask a flexible member in the form of a 
diaphragm moves in response to the reduced pressure created in the mask 
chamber upon inhalation and actuates a lever which in turn opens a 
breathing fluid supply valve. Such masks, as shown in the prior art 
customarily are provided with an independent exhaust valve which opens 
upon exhalation to permit the escape of gas exhaled by the mask user. The 
exhaled gas both moves the diaphragm to its normal position of rest and 
opens the independent exhaust valve. 
BRIEF DESCRIPTION OF THE INVENTION 
In accordance with the invention there is provided demand type breathing 
apparatus wherein the exhaust valve and the diaphragm are combined thus 
eliminating the need for an independent exhaust valve. The diaphragm 
controls both the inlet and the exhaust valves, opening the former in 
response to inhalation and the latter in response to exhalation. 
The breathing apparatus of the invention comprises a hollow casing which is 
provided with an opening in the casing wall. A flexible diaphragm is 
positioned across the opening and in conjunction with the hollow casing 
forms a chamber. The diaphragm is movable in response to variations in 
differential pressure between the inside and outside of the chamber. A 
breathing fluid inlet valve communicates with the chamber and is opened in 
response to inward movement of the diaphragm resulting from a reduction of 
chamber pressure created upon inhalation by a user of the apparatus. An 
outlet valve is provided for exhausting fluid from the chamber when 
pressure within the chamber is increased above a predetermined value upon 
exhalation by the user. 
The improvement of the invention comprises providing a sealing surface 
against which the diaphragm normally is sealingly engaged and from which 
at least a portion of the diaphragm is disengaged upon exhalation into the 
chamber. The diaphragm and the sealing surface act as the outlet valve 
with the diaphragm controlling both the inlet valve and the exhaust ports, 
thereby eliminating the need for a separate outlet or exhaust valve.

DETAILED DESCRIPTION OF THE INVENTION 
Referring now in detail to the embodiment depicted by way of illustration 
in the accompanying drawing, there is shown a breathing apparatus 10 which 
comprises a casing 11, a flexible diaphragm 12 and a cover 13. The casing 
may be made of any suitable rigid material which is essentially impervious 
to air and oxygen, such as steel, aluminum and rigid plastics, and which 
will not incorporate toxic substances into breathing fluids. The casing is 
defined by a casing wall 14 through which a first opening 15 is provided. 
Flexible diaphragm 12 having internal and external surfaces 16 and 17 
respectively is positioned across opening 15. Flexible diaphragm 12 is 
manufactured from a flexible gas impervious material such as natural or 
silicone rubber or a flexible plastic. 
Flexible diaphragm 12 in conjunction with casing 11 defines a chamber 18 
into which a breathing fluid supply line 19 is connected through an inlet 
valve 20 of conventional design. Breathing fluid supply line 19 is 
connected to a source of breathing fluid, not shown, such as air or 
oxygen. Inlet valve 20 is opened in response to inward movements of 
diaphragm 12 by a tilt lever 21 which is moved by diaphragm 12 to open 
inlet valve 20 and which has a restoring spring 25 to close the valve upon 
outward movement of the diaphragm, all in a manner well known in the 
demand regulator art. 
The apparatus is provided with an outlet valve 22 for venting or exhausting 
fluid from chamber 18 when fluid pressure within chamber 18 exceeds a 
predetermined level. A second opening 23 into chamber 18 is provided which 
is adapted for airtight communication with the breathing function of a 
user, usually through a close coupling to breathing mask 30 as shown. If 
desired, such communication can be through a tube or hose, not shown, one 
end of which is tightly connected with second opening 23 and the other end 
of which is connected to breathing mask 30. 
In accordance with the invention, there is provided a sealing surface 24 
about opening 15 against which a circumferential portion 28 of internal 
surface 16 of diaphragm 12 normally sealingly engages to close opening 15 
and from which at least a portion of diaphragm 12 is disengaged when the 
pressure within chamber 18 increases above a predetermined level, thus 
permitting surface 16 of diaphragm 12 in conjunction with surface 24 to 
act as outlet valve 22. 
Casing wall 14 is formed to provide an exhaust channel 31 around opening 
15, communicating with chamber 18 when diaphragm 12 is disengaged from 
surface 24 and closed from communication with chamber 18 when diaphragm 12 
sealingly engages surface 24. Channel 31 is vented to atmosphere through 
ports 27' at the bottom of the channel, and is subdivided into an annular 
series of exhaust ports 27 by an annular series of radial bars 32 joined 
at their outer periphery by a ring 33 having a recessed bottom wall 
providing an annular chamber 34 communicating with exhaust ports 27 and 
with vent ports 27'. Bars 32 are of substantial width or thickness, and 
with ring 33 provide an inwardly sloping, inverted frusto-conical support 
surface 57 for the circumferential portion 28 of diaphragm 12 when it is 
sealing engaged against surface 24 to close outlet 22, as shown in FIG. 2. 
The slope of surface 57 is such that its inner periphery is only slightly 
below the sealing surface 24 of casing wall 14, and its outer periphery is 
at diaphragm ring 26 or substantially so. 
External surface 17 of diaphragm 12 is protected by cover 13 which is 
shaped to provide a chamber 29 on the side of diaphragm 12 opposite 
chamber 18 and which is provided with a vent 40 so that external surface 
17 of flexible diaphragm 12 is usually constantly exposed to atmospheric 
pressure. Periphery 26 of diaphragm 12 is a thick ring securely held in 
the recessed upper ends of casing wall 14 and of ring 33 by cover 13 but 
diaphragm 12 is not held against sealing surface 24 by cover 13. 
The diaphragm 17 is carefully designed so that in any orientation there is 
a preload built into a diaphragm sufficient to maintain contact with the 
sealing surface 24 with no differential pressure across the diaphragm. 
This means that a small positive pressure in chamber 18 must be induced to 
lift the diaphragm at sealing surface 24 and exhaust the exhaled gases 
through ports 27, 27'. 
In its most common usage, the gas in chamber 29 simply moves in and out 
through port 40 as the differential pressure across diaphragm 12 is 
altered by an induced negative or positive pressure in chamber 18. It is 
within the scope of the invention, however, that a positive pressure 
(above ambient) may be imposed on the diaphragm by some secondary device, 
as described below. However, the design is such that the differential 
pressure across diaphragm 12 needed to either open the demand valve 20 or 
in turn to lift diaphragm 17 from sealing edge 24 to exhaust gases, will 
remain almost constant. This is accomplished by the radial supports 32, 33 
which are incorporated in exhaust channel 31, so that the effective area 
of the diaphragm subject to the differential pressure remains in a 
substantially constant ratio of 1:1. 
When the regulator is of the pressure-demand type, to avoid any possibility 
of inboard leakage for example, an orificed flow of gas from the upstream 
side of inlet valve 20 to chamber 29 can be provided. As shown in FIG. 2, 
cover 13 can have a passage 50 communicating with chamber 29 and with a 
passage 56' in casing 11 communicating with the inlet supply. Casing 11 
also has a bore 56 communicating with passage 56' and containing an 
orifice button 52 having a restricted orifice 53 communicating with 
passage 56' through a filter 54. The opposite ends of bore 56 are sealed 
around passages 50 and 56' by O rings 51 and 55. With this arrangement a 
constant supply of inlet gas is bled to chamber 29, biasing diaphragm 12 
to maintain a positive pressure in chamber 18 in a manner known in the 
art. An aneroid 37 in a cap 35 on cover 13 carries a valve 38 adapted to 
engage a seat 39 around port 40, the cap having vent openings 36 to 
atmosphere. Port 40 and valve 38 are of a diameter approximately equal to 
the diameter of aneroid 37, whereby aneroid 37 and the pressure in chamber 
29 act against the same valve area. 
Support surface 57 is useful but not essential when operating in the 
straight demand mode and diaphragm 12 is subject only to ambient 
atmospheric pressure in chamber 29. When operating in the pressure demand 
mode, however, supporting surface 57 is necessary to maintain the desired 
uniform opening action of outlet 22 in response to increased pressure on 
surface 16 of diaphragm 12. 
In operation, when the user of apparatus 10 inhales, the pressure within 
chamber 18 is reduced which causes the center of diaphragm 12 to move 
inwardly, activating lever 21 which in turn opens inlet valve 20 thus 
permitting breathing fluid to enter chamber 18. This reinforces the 
self-sealing action of diaphragm 12 against surface 24, keeping outlet 
valve 22 closed. When the user of breathing apparatus 10 exhales, the 
pressure in chamber 18 is increased and diaphragm 12 moves outwardly 
permitting inlet valve 20 to close. However, outlet valve 22 remains 
closed and circumferential portion 28 of diaphragm 12 does not lift away 
from sealing surface 24 until the pressure within chamber 18 exceeds that 
within chamber 29 by an amount sufficient to overcome the built-in preload 
or self-sealing bias of diaphragm 12 whereupon diaphragm portion 28 is 
lifted from supporting surface 57 permitting exhaled gas to pass between 
internal surface 16 of diaphragm 12 and sealing surface 24 through exhaust 
ports 27 and vents 27' to the outside of apparatus 10. The amount of 
diaphragm portion 28 which is lifted from surface 57 increases with the 
pressure force of exhalation, thereby increasing the area of exhaust 
opening through ports 27 as shown by comparing FIGS. 3 and 4. 
Thus, the inlet valve actuating diaphragm 12 also controls the exhaust 
outlet. The inlet 20 is opened by the diaphragm upon inhalation to admit 
breathing fluid to the chamber, the outlet 22 remaining closed by the 
diaphragm. The outlet is opened by the diaphragm upon exhalation, after 
permitting the inlet to close, to vent the products of exhalation from the 
chamber. The diaphragm 12, in conjunction with the peripheral sealing 
surface 24 provides the outlet valving action. The truncated, inverted 
conical shape of surface 57 supports diaphragm portion 28, at rest and 
during inward movement of the diaphragm, and also during lifting of 
portion 28 away from surface 24 upon outward movement of the diaphragm.