Fluid cutoff device in a fluid line

A fluid cutoff device in a line, includes a first coupling having a generally cylindrically shaped outer body, and a hollow generally cylindrically shaped inner body with a first inner sealing surface. The first coupling includes a first shutter valve adapted to be normally biased closed to abut against the first sealing surface to cut off fluid flow through the first coupling. The device includes a second coupling having a generally cylindrically shaped outer body adapted to sealably translate within the inner body of said first coupling, and a hollow generally cylindrically shaped inner body with a second inner sealing surface. The second coupling includes a second shutter valve and is adapted to be normally biased closed against the second sealing surface to cut off fluid flow through the second coupling which is engagable with the second shutter valve and a second actuation means within the second coupling engagable with the first shutter valve adapted to separate the respective shutter valve from the respective sealing surface to open the couplings.

BACKGROUND OF THE INVENTION 
The invention relates to a fluid cutoff device in a fluid line; 
particularly a blood carrying line in a medical device. 
It is often necessary to seal off the fluid flow in a fluid carrying line; 
for example, that of a bypass line in a medical device. Such lines must 
normally be cut off to prevent the flow of blood or other fluid, 
temporarily, then the cutoff device must be releasable so that the fluid 
can once again flow through the line. 
Currently such lines are sealed off by using a clamp. The clamped system 
has several disadvantages, namely that it is cumbersome and requires space 
not normally available in extracorporeal systems. 
The object of the present invention is to provide a fluid cutoff device in 
a fluid line which has a low cost and minimum bulk, and allows the line 
which lead to the device to be cut off into two sealed branches, so as to 
control fluid flow and to allow the connection or disconnection of a 
component within the system. 
Another object of the invention is to provide a one-way fluid flow device. 
SUMMARY OF THE INVENTION 
The described objects are achieved by a fluid cutoff device in a line, 
according to the invention includes a first coupling which has a central 
axis, a proximal end for connection to a fluid line, a generally 
cylindrically shaped outer body, and a hollow generally cylindrically 
shaped inner body with a first inner sealing surface. The first coupling 
includes a first shutter valve enclosed within the first coupling and is 
adapted to be normally biased closed to abut against the first sealing 
surface to cut off fluid flow through the first coupling. The device 
includes a second coupling which has a central axis, a proximal end for 
connection to a fluid line, a generally cylindrically shaped outer body 
adapted to sealably translate within the inner body of said first 
coupling, a hollow generally cylindrically shaped inner body with a second 
inner sealing surface. The second coupling includes a second shutter valve 
enclosed within the second coupling and is adapted to be normally biased 
closed against the second sealing surface to cut off fluid flow through 
the second coupling. The device has a first actuation means within the 
first coupling which is engagable with the second shutter valve and 
adapted to separate the second shutter valve from the second sealing 
surface to open the second coupling upon sufficient translational 
engagement of the second coupling into said first coupling; and has means 
for controlling the translational engagement of said couplings. The device 
thereby functions as a one-way valve. 
The device functions as a full open flow device by including a second 
actuation means within the second coupling engagable with the first 
shutter valve and is adapted to separate the first shutter valve from the 
first sealing surface to open the first coupling upon sufficient 
translational engagement of the second coupling into the first coupling.

DETAILED DESCRIPTION OF THE INVENTION 
Further characteristics and advantages of the invention will become 
apparent from the followed description of some preferred but not exclusive 
embodiments of the invention, illustrated only by way of non-limitative 
example in the accompany drawings, wherein: 
FIG. 1 is a perspective view of the invention in the position in which the 
fluid flow is allowed; 
FIG. 2 is a sectional view taken along the plane II--II of FIG. 1; 
FIG. 3 is a perspective view of the invention in the fluid cutoff position; 
FIG. 4 is a sectional view taken along the plane IV--IV of FIG. 3; 
FIG. 5 is a sectional view of the invention, according to another 
embodiment with the device functioning additionally as a one-way valve; 
FIG. 6 is a sectional view of the invention according to the embodiment of 
FIG. 5 in cutoff position; 
FIG. 7 is a schematic view of some elements of the invention according to 
another embodiment; 
FIG. 8 is a schematic view of the same elements of FIG. 7 with the shutter 
valve in a different position; 
FIG. 9 is a sectional view of the invention in open position with both 
shutter valves arranged according to the embodiment illustrated in FIG. 7; 
FIG. 10 is a sectional view of another embodiment of the invention 
functioning additionally as a one-way valve. 
With reference to the above described FIGS. 1, 2, 3, 4, the reference 
numerals 1 and 2 indicate two interconnected couplings respectively 
provided with connectors 1a and 2a to two branches of a line and with grip 
elements constituted by a tab lb and by the pair of opposed tabs 2b, 2c. 
The couplings are in contact at the respective cylindrical surfaces 3a, 3b 
(see particularly FIG. 4) and a sealing gasket, 3c, which prevents any 
external contact of the fluid which flows through the device, and 
therefore ensures the seal and sterility of the device. 
The outer surface of the coupling 1 has two identical grooves in 
diametrically opposed positions. The groove generally indicated by the 
reference numeral 4 is nearly entirely visible in FIGS. 1 and 3, while the 
opposed groove indicated by the reference numeral 5 can be seen only at 
its end portion in FIG. 3. Groove 4 includes two lateral portions 4a and 
4b (perpendicularly oriented and offset relative to the longitudinal axis) 
connected by an inclined portion 4c, and the portion 4b is connected by an 
inclined portion 4d which extends to the end of the coupling and is open 
to provide access to the groove. The groove 5 has the same, but 
diametrically opposed, configuration. 
A follower pin 6 extends from the tab 2b of the coupling 2 and slides 
within the groove 4. The groove includes an obstacle constituted by small 
detent studs 4e which can be passed by elastic deformation of the pin and 
provides a slight locking action for an operator. Similarly, an opposed 
follower pin 7 extends from the tab 2c of the coupling 2 and slides in the 
groove 5. 
A shutter valve 8 is arranged within the coupling 1 and is biased by a 
spring 9 against a sealing surface 10 and a gasket 10a provided within the 
coupling 1. Similarly, the coupling 2 contains a shutter valve 11, which 
is biased by a spring 12 against a sealing surface 13 having a gasket 13a 
provided within the coupling 2. The shutter valves 8, 11 respectively have 
facing protrusions 8a and 11a to provide the operating functions of the 
cutoff device. 
As illustrated in FIGS. 1 and 2, the two couplings 1, 2 are in the position 
of maximum mutual approach, as determined by the location of the pin 6 in 
the lateral portion 4a of the groove 4 and of the pin 7 in the similar 
portion of the groove 5. In this position the two protrusions 8a and 11a 
are adapted to be in sufficient mutual contact, and overcome the bias 
forces of the springs 9 and 12, to force the respective shutter valves 8 
and 11 to be well separated from contact with their respective sealing 
surface 10 and 13. This is therefore the open position of the device, and 
the fluid can flow in both directions. 
By rotating the couplings 1 and 2 counter-clockwise until they move to the 
relatively spaced apart position of FIGS. 3 and 4, the pin 6 is within 
lateral portion 4b of the groove 4 and the protrusions 8a and 11a are 
adapted to have a slight clearance; therefore, the shutters valves 8 and 
11 are pressed by the action of the springs to make contact with their 
respective sealing surfaces 10 and 13. This is therefore the cutoff 
position of the device. It should be noted that so long as the pins remain 
in the lateral portions (4b) of the grooves (assisted to so remain by the 
detent studs 4e), the couplings continue to be engaged but each of the two 
branches of a line is cut off by an individual shutter. The branch which 
reaches the coupling 1 is sealed by the shutter valve 8, and the branch 
which reaches the coupling 2 is sealed by the shutter valve 11. 
A further counter-clockwise relative rotation of the couplings from the 
above described cutoff position, allows the follower pins 6 and 7 to 
further slide along the respective inclined portions (illustrated as 4d in 
FIG. 3) of grooves 5 and 6, then completely out of the open ends of the 
grooves to disengage the couplings and therefore to disconnect the two 
sealed branches of the line without fluid losses. 
FIGS. 5 and 6 illustrate a second embodiment and the device is arranged to 
function as a one-way valve (as shown in FIG. 5), as well as a cut-off 
device (as shown in FIG. 6). Couplings 14 and 15 of this embodiment have 
an external configuration which is identical to that of the previously 
described couplings 1 and 2, with similar grooves for the accommodation of 
similar follower pins, and therefore have identical characteristics of 
relative motion from a position of maximum approach shown in FIG. 5 to a 
relatively spaced-apart position shown in FIG. 6. 
The coupling 14 contains a shutter valve 16, biased by a spring 17 against 
a sealing surface 18 which has a gasket 18. 
The coupling 15 contains a shutter valve 19 which is pushed by a spring 29 
against the sealing surface 21 which has a gasket 21a. Shutter valve 19 
has a protrusion 19a adapted to make contact with a baffle 22 provided 
within the coupling 14. Shutter valve 16 does not have a protrusion 
element and is not actuated by contact with the baffle 22 to open the 
valve. As shown in FIG. 5, the couplings are in position of maximum mutual 
approach. The protrusion 19a of the shutter valve 19 is in contact with 
the baffle 22 of the coupling 14, and therefore the shutter valve 19 is 
pushed against spring 20 into a position of separation from its related 
sealing surface 21. Flow can occur through the coupling 15 and against the 
inner surface of shutter valve 16. Under such fluid force and the 
selection of spring 17 having the appropriate resistance, the shutter 
valve 16 is forced to compress the spring and separate from its sealing 
surface 18 to function as a one-way valve. Fluid pressure in the opposite 
direction forces shutter valve 16 against sealing surface 18 and therefore 
flow in the opposite direction is impossible. As previously discussed, 
continued relative counter-clockwise rotation of couplings 14 and 15 (due 
to the follower pins in portion 4b of the grooves) results in loss of 
contact between the protrusion 19a of the shutter valve 19 and the baffle 
22, and the spring 20, and forces shutter valve 19 against the sealing 
surface 21, to also seal this branch of the device. 
A third embodiment of the device, is illustrated in FIGS. 7, 8, 9, 10, in 
which couplings 23 and 24 have an external configuration which is similar 
to that described in reference to couplings 1 and 2 of FIGS. 1 and 2. The 
couplings include similar grooves for the accommodation of similar 
follower pins which guide the couplings from a position of maximum mutual 
approach (as shown in FIGS. 9 and 10), to relatively spaced position which 
functions to cut off the fluid, and further to completely disconnect the 
couplings. The two couplings 23 and 24 contain two shutter valves 25 and 
28. The shutter valve 25 is enclosed in the coupling 23, and is provided 
with opposite tabs 25a and 25b in the shape of portions of a cylindrical 
surface and is pushed by a spring 26 against a sealing surface 27 and 
gasket 27a within the coupling. The valve 28 is enclosed in the coupling 
24, and is also provided with tabs 28a and 28b (which are outboard of tabs 
25a and 25b) and is pushed by a spring 29 against a sealing surface 30 and 
gasket 30a within the coupling. The coupling 23 includes an internal 
cylindrical surface 23a which has a pair of opposed short axial ridges 31a 
and 31b and a pair of equally spaced opposed longer axial ridges 32a and 
32b. The ridges define two distinct relationships between the couplings 
and the opposed shutter valves. The tabs 25a and 25b may be accommodated 
in the spaces respectively between the ridges 31a, 32a and 32b, 31b or in 
the spaces respectively between the ridges 31a, 32b and 32a, 31b. 
The same relationship occurs in the coupling 24 which has an internal 
cylindrical surface 33 which has a pair of opposite short axial ridges 34 
and a pair of opposite long axial ridges 35. Similarly, the ridges define 
two distinct relationships between the coupling and the shutter valve tabs 
28a, 28b. 
FIG. 7 and 9 illustrate (in solid lines) the shutter valve 28 in the first 
relationship of mutual spacing of the couplings. When the couplings 
approach one another, shutter valve 28 moves and rotates together with the 
coupling 24 due to the force exerted by the ridges of the surface 33 on 
the tabs, and moves to the position shown in broken and dotted lines with 
the tab 28a against the long ridge 32b of the cylindrical surface 23a of 
the coupling 23. With the tab 28b against the other long ridge 32a of the 
surface, thus providing the separation of the shutter valve 28 from the 
related sealing surface 30, as is clearly shown in FIG. 9. The shutter 
valve, as shown in FIG. 9, is also arranged with its tabs between the 
ridges of the surface 23a of the coupling 23 so as to make contact with 
the tabs in the relationship of maximum mutual approach of the couplings 
against the long ridges of the surface 33 of the coupling 24. Also, with 
the tab 25a against the long ridge 35, the shutter valve 25 is separated 
from its sealing surface 27; and therefore, the device allows the flow of 
the fluid in both directions and is thus in its open position. 
FIG. 8 illustrates in solid lines the shutter valve 28 in its second 
relationship in the position of mutual spacing of the couplings. In this 
position, when the couplings approach, shutter valve 28 moves to the 
position shown in broken and dotted lines with the tab 28a at the short 
ridge 31a of the surface 23a of the coupling 23 and with the tab 28b at 
the other short ridge 31b. In this relationship, the shutter valve 28 is 
pressed by spring 29 against the sealing surface 30. In this 
configuration, the other shutter valve 25 must be caused to separate from 
its sealing surface in the position of maximum mutual approach of the 
couplings, thus providing a one-way device which allows the flow 
exclusively in one direction, from the coupling 23 towards the coupling 
24. 
If instead it is required to provide a one-way device with a single 
possible flow from the coupling 24 to the coupling 23, the elements of the 
device are arranged as illustrated in FIG. 10. The shutter valve 28 is 
positioned so that its tabs contact, in the position of maximum mutual 
approach of the coupling, with the long ridges of the coupling 23. In this 
position, shutter valve 28 is separated from its sealing surface, and the 
shutter valve 25 is positioned with its tabs facing the short ridges of 
the coupling 24, against its sealing surface but which can be separated by 
fluid pressure on the inner surface of shutter valve 25. 
The described invention is susceptible to numerous modifications and 
variations, all within the scope of the inventive concept: thus, for 
example, the cam action provided by the grooves on the outer surface of 
the couplings may differ in shape from the one described. In the practical 
embodiments of the invention, all the details may be replaced with other 
equivalent elements: