SAFETY COUPLERS FOR MEDICAL VENTILATOR SYSTEM
Distinctly keyed male-female couplers are pneumatically connected to medical ventilator by distinct lines carrying pulsatile gas or sensory signals. Ventilator-mounted female coupler has entranceway cavity and larger receiving cavity delimited by catch edge. Male fence-forming longitudinal winglets extend from sealing plate carry terminal end convexities which latch onto catch edge. Winglets move inward due to larger fence circumference than entranceway and seat on catch. Winglets placed in tension due to locking length less than entranceway span, then convert force into sealing compressive force between sealing plate and female tube end. Conjoining male tube bayoneted and sheathed by projecting female tube, resulting in another gas seal. Two compressive seals formed between male distal port and pneumatic line. Extending male key(s) on winglet insertable into matching female slots. Convexities block insertion of non-matching couplers set due to interference by convexities on female on entranceway edges.
The present invention relates to a coupling system for connecting a ventilator to a pneumatic line or tube. The ventilator generates pulsatile gas at an internal pulsatile gas outlet, which is internal to the ventilator control and monitor casing, and senses sensory gas pressure P at a pneumatic sensory input, also internal to the ventilator casing. The female coupler body is mounted on the ventilator casing and pneumatically coupled to the ventilator’s pulsatile gas outlet in one configuration, or, in a different configuration, the female coupler body, mounted on the ventilator casing, is pneumatically coupled to internal sensory gas pressure ventilator input. The made coupler is plugged into the female coupler. Pneumatic tubes or lines connect the ventilator to a breathing head via the coupler system.
BACKGROUND OF THE INVENTIONIn healthcare clinics and facilities, ventilators are used in a variety of situations. Some ventilators are used as life-saving equipment to deliver pulsatile gas to a patient’s airway to expand the patient’s lungs and enhance oxygen flow into the lungs. Expiratory air flow from the patient must also be accounted for by the ventilator and breathing head. In other situations, intermittent rather than continuous pulsatile gas flow is supplied to the patient undergoing respiratory therapy. Examples of respirator systems can be found in U.S. Pat. Nos. 5862802; 6595203; 8347883 and U.S. Pat. Publication No. 202000139076.
In both the life-saving situation and the therapeutic setting, it is critical that the operator correctly attach the pulsatile gas supply line to the pulsatile gas input on the breathing head, which breathing head is pneumatically connected to the patient’s airway. Another critical connection to be made by the operator is the pressure sensory gas line between the breathing head and the ventilator. The sensory gas line enables the ventilator to determine, as a feedback signal displayed to the clinician, the gas pressure at the breathing head. Although color-coded pneumatic connecting lines and similarly color-coded ports on the ventilator casing reduce improper gas line connection errors between the ventilator and the breathing head, a unique male-female coupling system greatly reduces the probability of operator connecting error.
SUMMARY OF THE INVENTIONIt is an object of the present invention provide an interlocking male and female coupler system wherein the pulsatile gas line male coupler can only be interlocked with the installed female pulsatile gas line fixture mounted on the ventilator casing. In a similar manner when the sensory gas line is to be coupled to the sensory gas port of the ventilator, a different unique male to female coupler is used, thereby avoiding operator error of misconnecting the supply line to the sensory line.
It is another object of the invention to provide the female coupler with an internal longitudinal gas passageway, and outboard exterior facing female port end and an interior ventilator female port which is interior to and pneumatically coupled to either the pulsatile gas outlet (if this female coupler is designated as a pulsatile gas port) or a sensory gas pressure ventilator input (if the female coupler designated a sensory gas pressure input).
It is an additional object of the present invention to form female receiving cavities in a female receiving wall. An exterior facing female edge on the female coupler includes, in one embodiment, a radially widening sloped transitional edge which forms an exposed external edge for the female receiving cavity. In a further embodiment, the female receiving wall has first and second circumferential grooves wherein a first groove forms a radially narrow circumferential cavity having an entranceway circumference and an entranceway longitudinal span. The second circumferential groove forms a radially larger circumferential cavity and the first and second circumferential cavities are defined and bounded by a delimiting edge.
In another embodiment, the male coupler has a proximal coupler end, facing the ventilator, and a distal coupler facing away from the ventilator. The male coupler body has a frustoconical primary outboard port male seal formed at the distal end of a male gas passageway. The male coupler body also has a frustoconical secondary outboard port male seal. This secondary outboard port seal is longitudinally inboard the primary outboard port male seal. These two outboard port male seals pneumatically connect the pneumatic line or to the gas carrying male passageway.
In a further enhanced embodiment, the male coupler has a projecting bayonet insertion tube terminating at the proximal male coupler end as an extension of the male gas passageway. The bayonet tube is sized to sheathe within a protecting female tube end of the female coupler. The male coupler body has radial or lateral sealing plate (lateral being normal to the bayonet tube axial centerline), sometimes identified as a sealing end plate wall of the male receiving cavity created by a coupled system. The male coupler has a plurality of spaced apart arcuate winglets which longitudinally extend from the sealing plate to the proximal male port end. The plurality of winglets form a male fence and, when coupled, form a male receiving cavity, The male fence in one embodiment is a cylindrical fence. In some situations, the winglets are circumferentially spaced apart. In other situations, the male winglets are laterally spaced from the axial centerline of the projecting bayonet insertion tube of the male coupler body. These winglets have an effective locking longitudinal winglet length which is less than the longitudinal entryway span of the female coupler. Further, the male fence formed by the winglets has a longitudinal fence depth. This longitudinal fence depth is less than the projecting female end of female coupler.
A further enhancement of the invention includes the provision wherein each winglet has a plurality or number of radially outward leading-edge convexities or catch surfaces at the winglet’s terminal end. In some situations, these winglets are arcuate. In other situations, the winglets are squared off. Sometimes, the convexities are referred to as catch surfaces and the winglets are referred to as grappling legs.
In a further embodiment, the winglets extend longitudinally from the radial or lateral sealing plate and the effective locking length of the winglets is defined between the convexities and the sealing plate. This plurality or number of winglets define a fenced circumference or simply a male fence which is greater than the entranceway circumference. The male coupler includes one or more radially extending key tabs and the key tabs extend from one or more of the winglets. The key tabs are collinear with the bayonet tube and the male fence in one embodiment. Sometimes, the winglets define a squared off or rectangular male fence, the winglets are laterally spaced from the bayonet tube and the winglets define a lateral span away from and spaced apart from the tube’s axial centerline. The key tab or tabs are complementary to the key slot or slots in the female coupler.
Operationally, the winglets move radially inward due to the male fence span being greater than the entranceway circumference (or the lateral fence span being greater than the lateral receiving channel span). Upon coaction of the fence-forming convexities on the delimiting edge boundary between the narrow female cavity and larger female cavity, the winglets are placed in tension due to the effective locking length being less than the entranceway’s span. As a result, this tension force is transmitted to the male’s sealing plate forcing the female terminus edge of the projecting female end as a compressive force applied between terminus edge and against the radial or lateral sealing plate as the compressive force.
Although the foregoing general discussion of one embodiment of the present invention focuses on a number of circumferential and radial elements configured around the projecting male bayonet tube and the sheathing portion of the projecting female end portion, which is a pipe or tube, the coupling system may be configured laterally to achieve similar results obtaining the compression seal between the male bayonet to in the sheathing projecting female tube and the winglets forming the cylindrical fence. For example, the inner female receiving wall system could be a square or a rectangular or some other multi-faceted system other than the inner female receiving wall forming cylindrical entranceways and radially larger cylindrical cavities.
As an example, if the coupler system was configured as a square, the inner female receiving wall would, in a preferred embodiment, include first, second, third and fourth grooves having a lateral entranceway span with respect to an axial centerline through the projecting female end. In the lateral square system, the first, second, third and fourth grooves for the female entranceway are located on the interior first, second, third and fourth walls of the squared-off female coupler. On the male coupler, the winglets would extend longitudinally from a laterally extending sealing plate which is normal to the bayonet. Therefore, the winglets are laterally spaced from the axial centerline of the bayonet. In order to generate tension on the winglets, the plurality of winglets move laterally inward due to the fenced lateral span being greater than the female entranceway lateral span and, upon coaction of the plurality of catch surfaces chamfers on the delimiting edge, the winglets are placed in tension due to the effective winglet locking length being less than the female entranceway longitudinal span. This tension force is converted into a compression with the female terminus edge being placed in sealing compression against the lateral sealing plate due to the longitudinal fence depth being less than the projecting female end.
Additional enhancements include forming a primary pressure seal between the sheathed bayonet end and the projecting female end. The bayonet may have a frustoconical bayonet shape with a narrow bayonet terminus end.
Other embodiments of the invention include multiple key tabs cooperating with matching key slots wherein one of the matching key-key slot combinations are used for the pulsatile gas supply line, another of the key-key slot combinations are used for the gas sensory line. In this manner, blocking elements and edges prohibit a non-matching keyed male coupler to be inserted into a female coupler.
Although the invention, as illustrated and described herein, is not intended to be limited to the details shown because various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims. Additionally, well-known elements of exemplary embodiments of the invention will not be described in detail or will be omitted so as not to obscure the relevant details of the invention.
Before the present invention is disclosed and described, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting. The terms “a” or “an,” as used herein, are defined as one or more than one. The term “plurality,” as used herein, is defined as two or more than two. The term “another,” as used herein, is defined as at least a second or more. The terms “including” and/or “having,” as used herein, are defined as comprising (i.e., open language). The term “coupled,” as used herein, is defined as connected, although not necessarily directly, and not necessarily mechanically. The term “providing” is defined herein in its broadest sense, e.g., bringing/coming into physical existence, making available, and/or supplying to someone or something, in whole or in multiple parts at once or over a period of time.
In the description of the embodiments of the present invention, unless otherwise specified, azimuth or positional relationships indicated by terms such as “up”, “down”, “left”, “right”, “inside”, “outside”, “front”, “back”, “head”, “tail” and so on, are azimuth or positional relationships based on the drawings, which are only to facilitate description of the embodiments of the present invention and simplify the description, but not to indicate or imply that the devices or components must have a specific azimuth, or be constructed or operated in the specific azimuth, which thus cannot be understood as a limitation to the embodiments of the present invention. Furthermore, terms such as “first”, “second”, “third” and so on are only used for descriptive purposes, and cannot be construed as indicating or implying relative importance.
Also, in this document, the term “longitudinal” should be understood to mean in a direction corresponding to an elongated direction of either the male bayonet tube or the female sheathing tube portion. The term “lateral” should be understood to mean in a direction normal or perpendicular to the longitudinal direction. The term “proximal” generally refers to items closer to the ventilator casing than other referenced items.
The accompanying figures, where like reference numerals refer to identical or functionally similar elements throughout the separate views and which together with the detailed description below are incorporated in and form part of the specification, serve to further illustrate various embodiments and explain various principles and advantages all in accordance with the present invention.
While the specification concludes with claims defining the features of the invention that are regarded as novel, it is believed that the invention will be better understood from a consideration of the following description in conjunction with the drawing figures, in which like reference numerals are carried forward. It is to be understood that the disclosed embodiments are merely exemplary of the invention, which can be embodied in various forms. Similar numerals designate similar items in the drawings.
To understand the unique medical environment within which the inventive male and female coupler are deployed,
Referring now to
Male coupler 1b defines an outboard port 53 (
Outboard port 53 also includes a transitory further longitudinal inboard frustoconical slope 29 in safety seal region 28 (slope 29 being longitudinally inboard of transitory compression edge element 17), which again radially expands the tube end 60 forming a secondary compression seal between the tubing and outboard end 16. This secondary compression seal is important because (a) when tube 60 carries pulsatile gas from the ventilator 80 (see
Further longitudinally inboard from seal region 28, the male coupler 1b defines a transitional radii 18 which radii defines the outboard region of stress risers 54a, 54b. These stress risers in the male coupler 1b prevent fatigue failures.
In practice as explained later, operators (primarily trained healthcare professionals) plug male coupler 1b into female coupler 1a. The female coupler is securely mounted on the ventilator control-monitor 80. See
In practice, one breathing head is used by only one patient. The breathing head is delivered to the operator with disconnected pneumatic lines and the operator assembles the system (the breathing head plus the pneumatic lines) by attaching the lines to the head and then attaching the lines to the ventilator.
The operator should attach the correct pneumatic male coupler carrying line to the correct designated female coupler. Sometimes, the operator is provided with both a new, unused breathing head and a new, unused set of connecting tubes or lines. Therefore, in some instances, for each patient, the operator must accurately attach several lines from the ventilator to the breathing head. One critical line carries pulsatile gas to the breathing head and a second critical line carries the sensory pressure signal back from the breathing head to the ventilator. It is critical that gas pressure is maintained in each of these pneumatic lines. For the pulsatile gas supply line 124 leading to the breathing head 110 (
Since the ventilator control-monitor, generating the pulsatile gas and receiving pressure sensory signals on differentiated pneumatic lines, is typically stationary and the breathing head is highly mobile or movable compared to the stationary ventilator, these pneumatic lines are tugged (longitudinally acted upon), twisted (rotated) and bent (in the y and z axis away from the x longitudinal axis of the male coupler and the laid-out gas lines). Hence, the primary and secondary compression seals represent one of the several important features of the present invention.
Due to twisting and turning of the pneumatic lines or tubes, the male coupler is effected by the movement of the pneumatic lines. For this reason, male coupler 1b includes upper and lower stress risers 54a, 54b to prevent fatigue failures. The stress risers longitudinally span the interstitial space between the radial ribs 16. These stress risers 54a, 54b define longitudinal plates which in plane B-B′ (
It should be noted that it is not necessary that primary key 34 be positioned extending outboard from the top side of the male coupler. In other words, primary key 34 could be rotated to any radial position (in the range from 0 degrees to 360 degrees) with respect to the plane defined by the risers as long as the radial position of primary key 34 is complementary to the radial position of primary slot 35 in female coupler 1a as shown by the radial coincidence of the key tab and key slot in
For example,
As shown in
One of the several important aspects of the present invention is the use of a series, more than three, radial fins having a longitudinal span extending from the outboard double compression tube connection (generally defined by seal areas 28, 29
However, some partial arcuate cut-out segments 56 on each fin do provide a mechanical function which improves the use of the male coupler as explained below.
The interstitial space 23 (
One of the several important aspects of the present invention is the multiple, one-way key system, with complementary interlocks and guide elements on the male and female couplers.
Each male coupler fitting (see
As shown in
In order to explain primary and secondary blocking features of the present invention, reference will be made to the single primary topside key tab 34 male coupler and the single primary receiving key slot 35 female coupler shown in
As explained below, one of the several important features of the present invention is the combination of the matching or complementary key sets with the pressure seals described herein below. Likewise, the secondary blocking and permissible secondary key sets can be employed with these various primary key configurations.
The secondary key subsystem, sometimes referred to as a blocking subset, is described herein. Returning to the single primary topside key tab 34 coupler and shown in
Operationally, the male coupler fits into the female coupler in the following manner. On the female coupler, the radially inboard sloped female edge 3 provides centering and guidance for male chamfer edge 12 on the terminal proximal ends of positive retention winglets 15 and 31. Winglets 15 and 31 are defined as a circumferential fence on the male coupler. The leading-edge convexity element 25 of chamfer edge 12 is slightly radially angled outboard such that radial span of all chamfer edges (the five chamfer edges 25, 25a, 25b, 25c, and 25d, on winglets 15, 31 in
Stated otherwise, the cylindrical female receiving cavity has a radially widening sloped transitional female edge 3 (a frustoconical shaped edge 3) which leads to a radially narrow first circumferential groove forming an entranceway 64, 22 and further leading longitudinally inboard to a second circumferential groove forming region 21 on the female receiving cavity. Circumferential groove cavity 21 is longitudinally inboard of first circumferential groove entranceway 22, 64. A delimiting edge 2 defines the boundary between entranceway 64, 22 and radially larger second circumferential groove cavity 21.
The female coupler 1a has a cylindrical female receiving cavity. A projecting female end tube, defined by projecting tubular wall segment 20, projects into the radially inboard female receiving cavity 22a. The projecting female end tubular segment 20 is the extension of gas female passageway 6. The projecting female end segment 20 is coaxial with respect to the female receiving cavity 22a and, in the illustrated embodiment, coaxial with female gas passageway 6. The coaxial relationship of radially inboard female receiving wall 22a and the projecting female end segment 22a is important for mating and establishing the several gas pressure seals between female coupler and the male coupler. The projecting female end segment 20 has terminus end 4, which compressively seals against male cone 10.
And shown in
When leading edge convexity element 25 of winglets 15 and 31 are inserted into female cavity 22a, 64 and when convexity 25 transitions past female receiving cavity edge 3, the stress relieving arcuate gaps 30 of winglets 15, 31, shown in
The details of radially outboard protruding chamfer edges 12, shown in
In male coupler 1b, the circumferentially spaced apart arcuate winglets longitudinally extend from the male radial sealing plate 9 towards the proximal male port end facing the female coupler. The plurality of winglets, when coupled, in the female cavity, form a male receiving cavity 68 as a cylindrical fence on the delimiting edge. When not coupled, the winglets form a male fence. The cylindrical winglet male fence is shown in
The present invention utilizes two differentiated gas sealing systems. The primary compressive gas seal is formed by the projecting male bayonet tube 94 which is inserted by the operator into projecting female tube segment 20 (defined by tubular wall 20). This sheathed inserted bayonet tube is the primary compressive gas seal. The secondary compressive gas seal results from the short length arcuate winglets captured at delimiting edge in the female receiving cavity 64, 22a, resulting in the winglets being placed under a tension force which tension force is mechanically transferred to projecting female tube end 4 which is compressed male radial sealing wall 10 forming the base of U-shaped male receiving channel 68 formed by the winglet circumferential fence.
Winglets 15, 31 are arcuately spaced apart by gaps 30 or interstitial regions between each winglet. When the winglets are inserted into female entranceway cavity 22a, 64 and then further longitudinally inserted into the inner female cavity 21, the result is the formation of male receiving cavity 68 which circumferentially locks the couplers simultaneously with male bayonet tube 94 inserted into the female projecting tube 20. The male fence convexities acting on the delimiting edge create a generally circumferentially distributed tension force about the entranceway which draws the bayonet male end into the female projecting end tube and also distributes the compressive force about the periphery of the projecting female end as the same contacts the end stop plate. In the squared-off construction, this peripherally distributed tension force is equally converted into a circumferential compressive force between the projecting female end and the end stop plate. The application of this relatively uniform circumferential compressive force establishes a better gas pressure seal. Further, the key tab in the key slot may present the weakest mechanical element in the gas sealing coupler system because the convexities are not formed on the outboard edges of the key tab. See tab 34,
The winglet fence has a radially wider fence mouth or circumference at its proximal end (near the ventilator), a continuously narrower radial throat, which throat leads to secondary compression male seal end surface 10, and a longitudinally inboard stop plate wall 9 (longitudinally inboard from the wider mouth of the to-be-formed male receiving cavity 68). The radial stop plate 9, in the squared-off system, is a lateral plate. The throat of the to-be-formed male cavity 68 terminates at inboard end plate wall 9.
In the illustrated embodiment, male receiving cavity 68 is a truncated U-shaped arcuate cavity (a truncated base stop plate wall 9 forming the conjoining base of the U-shaped channel, one leg of the U-shaped channel being the radially outer wall of the male winglet fence and the other leg being the radially inner wall 22 of female cavity 22a and 21, dependent upon the degree of insertion). The U-shaped channel mouth leads to a radially narrowing throat. The progressively radially narrowing or converging U-shaped throat walls of male receiving cavity 68 form secondary compression male seal surfaces 9, 10 which surfaces are present in all the arcuate winglets. The plate 9 acts as a stop wall for the female projecting end tube 20. The radially narrower, converging U-shaped throat walls form the secondary compression seal. The primary compression seal is formed which is sheathed within the projecting female end defined by wall 20. The projecting female tube 20 may have inboard seal edge 90.
The winglet defined male primary compression seal edge surfaces 9, 10 provide the compression sealing surface for the male receiving cavity and hence a compression seal when projecting female end wall segment 4 is longitudinally forced against throat end wall 9. The compression seal is established by the materials’ flexibility. The male and female couplers may be made of the same poly plastic material or the female coupler may be made of a harder material compared to the disposable male coupler (disposable because each patient uses a different breathing head 110 (
The main compression sealing surfaces on the inboard coupler end are defined by the sealing coaction of (a) the male bayonet projecting terminal end segment 14 being sheathed by projecting female tube 20; and (b) female cylindrical terminal end 4 acting on the radial cone 10, that is the primary seat at the projecting male bayonet insertion tube 94 in male throat 68. These two compressive systems provide a primary compression seal (the male bayonet in the female sheathing), a secondary compression seal (the female terminus edge 4 against the cone 10).
Alternatively, the female projecting cylindrical terminal end segment 4 may have a slightly continuously radially narrowing sloped exterior surface, or a slightly continuously radially narrowing sloped interior surface, wherein the projecting terminal end segment 4 of female passageway 20 is radially thinned to provide a complementary match with the U-shaped male receiving sealing channel 68.
Another alternate embodiment reverses the male end primary sealing cavity 68 and the female terminal end 4. Stated otherwise, the female outboard coupler body could define winglets and a to-be formed male receiving channel (similar to male channel 68) and the male coupler could define a projecting cylindrical sheathing tube end (similar to sheathing female end wall segment 20 and female terminus 4).
Each winglet 15, 31 defines, at a longitudinal leading location, a radially protruding arcuate convexity or bump 25. Convexity 25 has a leading chamfer edge 12 and a following chamfer edge 13. The leading edge 12 disposed at the longitudinal outboard terminal edge of winglet 15, 31, and the following chamfer edge 13 being longitudinally inboard of convexity 25.
When the operator inserts the proximal male coupler end into the exterior outboard facing female coupler end, the leading male chamfer edge 12 on convexity 25 enters entranceway 22a, 64, and seats on female delimiting edge 2 between female entranceway receiving cavity 64, 22, and the radially larger female passage 64. When convexity 25 clears edge 2 and the follow-on chamfer is seated delimiting edge 2, winglets 15 and 31 expand radially outward by cam action along the backside of the follow-on male chamfer slope 13 of convexity 25. The term “backside” being inboard of leading chamfer edge 12. The outwardly directed force applied by the male coupler longitudinally pulls the winglet further inboard into the female’s larger radial cavity area or cavity 21. The follow-on chamfer edge 13 is captured by a tension fit on delimiting edge 2. The tension fit pulls the male coupler into the female coupler.
To further explain the mechanical tension force developed by the winglet legs, is the female coupler has a transitional outboard edge 3 leading to a first circumferential groove 64 which having an entranceway circumference. The longitudinal span of entranceway 64 and the longitudinal span of transitional edge 3 establishes an entranceway longitudinal span, and in
Each winglet leg is slightly angled radially outboard and carries a terminal end convexity defining a fence which is circumferentially larger than receiving female entranceway 64. When the winglets and convexities are pushed by the operator into female entranceway 64, the winglets first move radially inward into interstitial spaces and the winglets as a group exert radially outboard forces against the entranceway walls, and, upon full insertion, seat on delimiting edge 2.
The effective locking distance eld of the winglet legs is less than entranceway longitudinal span. When the follow-on chamfer 13 of convexity 25 is seated on delimiting edge 2, the winglet leg is placed in tension by the foreshortened effective locking distance eld of the leg compared to the entranceway longitudinal span. In the illustrated embodiment, the winglet is placed in tension by the foreshortened eld compared to the entranceway plus the transitional edge longitudinal span. Since the effective locking distance or length eld is less than the projecting female end distance pfed, the tension force is transferred from chamfer 13 through the leg structure to the cone 10 which then applies a compression force between cone 10 and terminus edge 4 of projecting female tube 20. The compression force provides another gas seal.
In
Referring again to the blocking action of non-matching male and female couplers, if the operator attempted to insert a two tab male system 204,
Although the illustrated embodiments show an arcuate distribution of winglets, the winglets could be disposed in a square pattern about projecting female tube 20. The winglets would extend longitudinally from radial plate stop 9 extending towards the female coupler. The winglets would be laterally based apart from the axial centerline of male passage 11. The female coupler would have a squared-off female receiving cavity. In this construction, grooves in the outer walls of the female receiving cavity 64, 21, would have a lateral span (spaced of part from the axial centerline 6 of the female coupler) as well as a longitudinal span. The lateral span being normal to and measured from the axial centerline of the female projecting tube 20 to the outer wall defining the female receiving cavities (outer wall similar to wall 22 in
On the female coupling, terminal cylindrical edge 7 is designed to add a second mechanical stopping edge for male fin plate 24. See
The method of coupling either pulsatile gas flow or sensory gas pressure flow from or to a ventilator with a pneumatic line or tube is facilitated by providing a male coupler 1b with a female coupler 1a. The male coupler has a proximal male coupler port, proximal to the ventilator 80 shown in
Simultaneous with the insertion of the unique male extending key configuration into the unique key slot configuration, the male gas carrying tube 94 is bayoneted into the female gas carrying tube 20 by sheathing the male tube with the female tube and conjoining the male and female gas passages 11, 6. As explained earlier, male bayoneted tube 94 on the projecting female terminal end 20 provides an initial pressure seal as a first compressive gas seal. Simultaneous with insertion of the male key tab into the female key slot, the operation forces the radially larger fence-formed male grapple legs, that is, the winglets carrying the terminal convexities, into the radially narrower female entranceway 64 (see
Again, simultaneous with the grappling, the male grappling legs, are placed under tension force because the effective locking distance eld is slightly shorter than the entranceway longitudinal span. The projecting female end distance or span pfed is shorter than entranceway 64 plus the longitudinal span of transition slope 3 (
In a preferred embodiment, the male and the female couplers are made of suitable plastic. To ensure that the pneumatic lines carrying pulsatile gas and sensory pressure gas do not disengage from the ventilator control-monitor, the couplers must remain connected together such that a longitudinal “pull off” force does not decouple the pressure lines from the ventilator.
In a preferred embodiment, the longitudinal span of the male coupler is about 1 inch in length. Similarly, the female coupler is about 1 inch in length. In a preferred embodiment, the breathing head 110 is connected to the pneumatic line 60 by the manufacturer and the head plus line system is delivered to the operator. The tab longitudinal span is about 0.125 inches in length (no longer than 0.25 inches), its radial outboard extension span of the tab is about 0.125 inches (no longer than 0.25 inches), and the diameter of male fence is about 0.375 inches (no more than 0.5 inches). The dimensions of the coupler are related to the inner and out diameters of the pulsatile gas supply line and the sensory pressure line. Typical high pressures in the pulsatile gas supply line are between 0-30 psi and typical sensory gas pressures are between 0-2 psi. Typical high pressures in the nebulizer supply line 122 are between 0-55 psi.
It should be noted that the breathing head illustrated in
The claims appended hereto are meant to cover modifications and changes within the scope and spirit of the present invention.
Claims
1. In combination with a ventilator generating pulsatile gas through a pulsatile gas outlet and sensing a sensory gas pressure at a pneumatic sensory input, a coupler system adapted to be interposed between the ventilator and a pneumatic line or tube, the coupler system pneumatically coupled to either the pulsatile gas outlet or the sensory input, the coupler system comprising:
- a male coupler having male coupler body with a proximal male port end and an opposing distal male port end, the male coupler body having a longitudinal gaseous male passageway between the proximal and distal male port ends;
- a complementary female coupler removably interlockable with the male coupler;
- the female coupler having a female coupler body;
- the female coupler body having: a longitudinal gaseous female passageway from an outboard facing female port end to an interior ventilator female port opposite the female port end, the interior ventilator female port adapted to be pneumatically coupled to either the pulsatile gas outlet or the sensory input, the female port end adapted to be exteriorly outboard of the ventilator; a cylindrical female receiving cavity in the female coupler body at the female port end, the female receiving cavity defined between a radially inner female receiving wall on the female coupler body and a projecting cylindrical female end portion, the projecting female end being an extension of the gaseous female passageway and being coaxially disposed within and projecting through the female receiving cavity, the projecting female end having a female terminus edge; at least one radial primary key slot in the inner female receiving wall which at least one key slot extends from the female receiving cavity either fully or partly through the inner female receiving wall, the at least one key slot being colinear with the projecting female end; a radially widening sloped transitional female edge on inner female receiving wall at the female terminal end; first and second circumferential grooves on the inner female receiving wall, the first groove interposed between the sloped transitional female edge and the second groove, a delimiting edge at the intersection of the first and second grooves, the first groove having an entranceway circumference and an entranceway longitudinal span; the male coupler body having: a frustoconical primary outboard port male seal formed at a distal end of the gaseous male passageway; a frustoconical secondary outboard port male seal, the secondary outboard port seal being longitudinally inboard the primary outboard port male seal, the primary and secondary outboard port male seals adapted to pneumatically connect the pneumatic line or tube to the gaseous male passageway; a projecting bayonet insertion tube terminating at the proximal male end as an extension of the gaseous male passageway, the bayonet tube sized to sheathe within the projecting female end; a radial sealing plate; a plurality of circumferentially spaced apart arcuate winglets longitudinally extending from the sealing plate towards the proximal male port end, the plurality of winglets forming a male cylindrical fence, the bayonet tube coaxial in the cylindrical fence, an effective locking longitudinal winglet length being less than the entranceway span, the male cylindrical fence having a longitudinal fence depth, the longitudinal cavity depth being less than the projecting female end; each winglet of the plurality of winglets having a radially outward leading edge convexity at its terminal winglet end, a longitudinally inboard convexity surface defining an outboard end of the effective locking length and the sealing plate defining an inboard end of the effective locking length; wherein the plurality of winglets define a plurality of convexities at a plurality of terminal winglet ends, the plurality of convexities defining a fenced circumference which is greater than the entranceway circumference; at least one radially extending primary key tab on at least one winglet of the plurality of winglets, the at least one key tab collinear with the bayonet tube and the cylindrical fence, the at least one radially extending primary key tab bisecting the corresponding convexity on the at least one winglet, the at least one key tab being insertably complementary to the at least one key slot; wherein the plurality of winglets move radially inward due to the fenced circumference being greater than the entranceway circumference and, upon coaction of the plurality of convexities on the delimiting edge, the plurality of winglets placed in tension due to the effective locking length being less than the entranceway span and the female terminus edge being placed in sealing compression against the radial sealing plate due to the longitudinal cavity depth being less than the projecting female end.
2. The coupler system combination as claimed in claim 1 wherein the bayonet tube receivable in the projecting female end and the sheathed bayonet tube in the projecting female end forms a primary pressure seal for the coupler system and the sealing compression between the female terminus edge and the radial sealing plate forms a secondary pressure seal for the coupler system.
3. The coupler system combination as claimed in claim 2 wherein the bayonet tube has a frustoconical bayonet shape with a radially narrow bayonet terminus end wherein application of either pulsatile gas or the sensory gas pressure in the gaseous male passageway increases the primary pressure seal due to the frustoconical bayonet shape sheathed in the projecting female end.
4. The coupler system combination as claimed in claim 1 wherein the radial span of the delimiting edge is greater than the fenced circumference.
5. The coupler system combination as claimed in claim 1 wherein the sloped transitional female edge is chamfered to accept the fenced circumference, the sloped transitional female edge having a transitional female edge longitudinal span, the entranceway span defined both by the transitional female edge longitudinal span and the entranceway longitudinal span of the first groove.
6. The coupler system combination as claimed in claim 1 wherein the male coupler body is an elongated male coupler body with a plurality of radial fins protruding radially outboard from the male gaseous passageway, the plurality of radial fins being intermediate the secondary outboard port male seal and the proximal male end.
7. The coupler system combination as claimed in claim 6 wherein the radial sealing plate has a plate face which is placed in sealing compression with the female terminus edge, the radial sealing plate has a longitudinal outboard plate face, the plurality of radial fins has a proximal-most radial fin which is longitudinally spaced apart from the outboard plate face.
8. The coupler system combination as claimed in claim 7 the female receiving cavity having a radially outer wall, the female receiving cavity having a longitudinal female receiving cavity span encompassing the transitional female edge and the first and second grooves, the longitudinal female receiving cavity span being substantially equivalent to or nominally longer than a male longitudinal span from the proximal-most radial fin to a proximal male port terminus, thereby forming a tertiary pressure seal for the coupler system due to the longitudinal female receiving cavity span being longer than the male longitudinal span when the plurality of winglets are placed in tension due to the effective locking length being less than the entranceway span.
9. The coupler system combination as claimed in claim 1 wherein the at least one radial primary key slot is a first key slot and the at least one radial primary key tab on the at least one winglet is a first key tab on a first winglet, the inner female receiving wall having a second key slot, the plurality of winglets having a second winglet, the second winglet having a second key tab collinear with the axial centerline through the bayonet tube and the cylindrical fence and the second key tab being insertably complementary to the second key slot.
10. In combination with a ventilator generating pulsatile gas through a pulsatile gas outlet and sensing a sensory gas pressure at a pneumatic sensory input, a coupler system adapted to be interposed between the ventilator and a pneumatic line or tube, the coupler system pneumatically coupled to either the pulsatile gas outlet or the sensory input, the coupler system comprising:
- a male coupler having male coupler body with a proximal male port end and an opposing distal male port end, the male coupler body having a gaseous male passageway between the proximal and distal male port ends; a complementary female coupler removably interlockable with the male coupler; the female coupler having a female coupler body; the female coupler body having: a gaseous female passageway from an outboard exterior female port to an interior ventilator port opposite the female port, the ventilator port adapted to accept pulsatile gas or sensory gas pressure; a female receiving cavity at the female port defined between a laterally inner female receiving wall system and a projecting cylindrical female end, the projecting female end an extension of the gaseous female passageway and projecting through the female receiving cavity and having a female terminus edge; at least one primary key slot in the inner female receiving wall system which extends either fully or partly from the female receiving cavity, the at least one key slot being colinear with the projecting female end; a transitional female edge on the inner female receiving wall system; first and second grooves on the inner female receiving wall system, the first groove interposed between the transitional female edge and the second groove, a delimiting edge between the first and second grooves, the first groove having an entranceway lateral span and an entranceway longitudinal span; the male coupler body having: a frustoconical primary outboard port male seal formed at a distal end of the gaseous male passageway; a frustoconical secondary outboard port male seal, the secondary outboard port seal being longitudinally inboard the primary outboard port male seal, the primary and secondary outboard port male seals adapted to pneumatically connect the pneumatic line or tube to the gaseous male passageway; a projecting bayonet cylindrical insertion tube as an extension of the gaseous male passageway, the bayonet tube removably sheathed within the projecting female end; a laterally extending sealing plate normal to the bayonet tube; a plurality of spaced apart winglets spaced apart from and disposed about the bayonet tube, the plurality of winglets longitudinally extending from the sealing plate towards the proximal male port end, the plurality of winglets forming a male fence about the bayonet tube, an effective locking longitudinal winglet length being less than the entranceway longitudinal span, the male fence having a longitudinal fence depth being less than the projecting female end; each winglet having one or more terminal end outward leading edge catch surfaces, the one or more catch surfaces defining an outboard end of the effective locking length and the sealing plate defining an inboard end of the effective locking length; the plurality of catch surfaces of the male fence defining a fenced lateral span which is greater than the entranceway lateral span; at least one laterally extending primary key tab on at least one winglet collinear with the bayonet tube, the at least one key tab being insertably complementary to the at least one key slot; wherein the plurality of winglets move laterally inward due to the fenced lateral span being greater than the entranceway lateral span and upon coaction of the plurality of catch surfaces on the delimiting edge the plurality of winglets placed in tension due to the effective locking length being less than the entranceway longitudinal span and the female terminus edge being placed in sealing compression against the lateral sealing plate due to the longitudinal cavity depth being less than the projecting female end.
11. The coupler system combination as claimed in claim 10 wherein the at least one primary key slot is a first key slot and the at least one primary key tab on the at least one winglet is a first key tab on a first winglet, the inner female receiving wall having a second key slot, the plurality of winglets having a second winglet, the second winglet having a second key tab collinear with the axial centerline through the bayonet tube and the second key tab being insertably complementary to the second key slot.
12. The coupler system combination as claimed in claim 10 wherein the bayonet tube has a frustoconical bayonet shape with a radially narrow bayonet terminus end wherein application of either pulsatile gas or the sensory gas pressure in the gaseous male passageway increases the primary pressure seal due to the frustoconical bayonet shape sheathed in the projecting female end.
13. The coupler system combination as claimed in claim 10 wherein the transitional female edge is either chamfered or sloped to accept the male fence, the chamfered or sloped transitional female edge having a transitional female edge longitudinal span, the entranceway span defined both by the transitional female edge longitudinal span and the entranceway longitudinal span of the first groove.
14. The coupler system combination as claimed in claim 10 wherein the male coupler body is an elongated male coupler body with a plurality of radial fins protruding radially outboard from the male gaseous passageway, the plurality of radial fins being intermediate the secondary outboard port male seal and the proximal male end.
15. The coupler system combination as claimed in claim 14 wherein the radial fins has at least one longitudinal plate support disposed in at least one interstitial space between at least two adjacent radial fins, the longitudinal plate support being collinear with an axial centerline through the gaseous male passageway.
16. A method of coupling either a pulsatile gas flow or a sensory gas pressure from or to a ventilator with a pneumatic line or tube comprising:
- providing a male coupler interlockable with a female coupler, the male coupler having a proximal male coupler port proximal to the ventilator and a distal male coupler port distal to the ventilator, the female coupler having an external outboard female port external to the ventilator;
- providing a key on the proximal male port and providing a matching key slot in the outboard female port;
- providing the male coupler with a male gas carrying tube, fence-formed male grapple legs, a male sealing plate, and a unique extending key configuration;
- providing the female coupler with female gas carrying tube, a radially or laterally narrow female entranceway, a radially or laterally larger female coupling chamber, a female catch surface delimiting the female entranceway and the female coupling chamber, a female gas carrying tube terminal end, and a unique key slot configuration;
- wherein the fence-formed male grapple legs have a greater radial or lateral span than the narrow female entranceway;
- installing the female coupler on the ventilator and passing the pulsatile gas flow or sensory gas pressure from or to the ventilator via the outboard female port;
- establishing spaced apart primary and secondary compressive conically forced seals between the distal male coupler port and the pneumatic line or tube, both conically forced seals acting on the pneumatic line or tube;
- simultaneous with inserting the unique male extending key into the unique key slot:
- bayoneting portions of the male gas carrying tube into the female gas carrying tube by sheathing the male tube with the female tube and conjoining the male and female gas passages; establishing a first compressive gas seal by bayoneting and sheathing the male coupler to the female coupler;
- forcing the fence-formed male grapple legs with the greater radial or lateral span into the radially or laterally narrow female entranceway;
- grappling the male legs onto the female catch surface;
- simultaneous with grappling the male legs onto the catch surface, placing the male legs under constant tension force;
- converting the tension force to a compressive force applied between the male sealing plate and the female tube terminal end and thereby establishing a second gas compressive seal between the male coupler and the female coupler; and
- removably coupling and decoupling the proximal male port to the outboard female port thereby coupling and decoupling of the pneumatic line or tube to the ventilator and, when coupled, passing the pulsatile gas flow or sensory gas pressure from or to the ventilator, through the female coupler and the male coupler.
17. The method as claimed in claim 16 including establishing the constant tension force by longitudinally foreshortening the fence-forming male legs compared to a sheathed portion of the female tube.
18. The method as claimed in claim 16 wherein the female coupler is a first female coupler have a first key slot configuration, the male extending key configuration is a male extending key configuration which can be inserted into the first key slot configuration;
- providing a second female coupler have a second key slot configuration which is positionally different than the first key slot configuration;
- blocking bayonetting and sheathing of the male extending key into the second key slot by male grapple legs impacting the radially narrow female entranceway.
Type: Application
Filed: Mar 17, 2022
Publication Date: Sep 21, 2023
Inventors: Mark John Baillie (Dover, ID), Shawn Adam Goughnour (Bonners Ferry, ID), Chad Thomas Nuxoll (Sandpoint, ID)
Application Number: 17/697,518