Technical Field

The field of this invention relates to mounting structures utilized in properly positioning and sealably mounting a cylindrical window section of a pressure vessel.

Background Art

Pressure vessels capable of withstanding elevated pressures have long been constructed of high strength, readily available materials such as stainless steel and the like. However, with the advent of expanded uses for pressure vessels, for example as in hyperbaric medicine, the desirability of having pressure vessels made of materials other than steel has increased. As in the case of hyperbaric medicine, and more particularly with hyperbaric chambers, it is desirable to have a hyperbaric chamber constructed in such a fashion that the patient attendant has good visual monitoring of the activities of the patient undergoing hyperbaric treatment. As such, it is desirable to have windows or view ports to accommodate such constant monitoring of the patient's progress during hyperbaric treatments.

Some prior art hyperbaric pressure vessels have utilized a basic stainless steel, tubular body section

having a plurality of view ports to permit attendant visual contact with a patient within such a chamber, such as those units manufactured by Reneau, Inc. of Stafford, Texas and known as "The Reneau Unit". On the other hand, other manufacturers of hyperbaric pressure vessels have chosen to manufacture hyperbaric pressure vessels utilizing cylindrical window sections that extend along the entire length of the pressure vessel, with such window sections being tightly secured between the end portions of the pressure vessel. Pressure vessels of this type are manufactured by Sechrist Industries, Inc. of Anaheim, California.

With the advent of the use of polymeric materials that are adapted to be formed into cylindrical window sections useful in hyperbaric chambers, it is desirable that such window sections be capable of being maintained in a sealable relation with the various components of the pressure vessel when at elevated pressures, while also being able to accommodate not only variations due to pressure differential but also variations to thermal gradients. Furthermore, with pressure vessels of the type that are formed of an entirely cylindrical window section, such as the Sechrist unit mentioned above, all connectible chamber utilities must of necessity be plumbed through the end portions of the chamber, as the structural integrity

(and the related various pressure vessel code requirements) of the polymeric cylindrical window sections is not such that connections and utilities are capable of being plumbed through the cylindrical window section itself. Also, in view of the inability to form any types of openings through the walls of the cylindrical window section, there are no internal chamber mounting surfaces for mounting chamber utilities, such as patient handrails, supports for fluids (i.e., I.V.'s), mounting of electrical leads for electronic monitoring equipment and like medical apparatus. Furthermore, support for prior art cylindrical window section pressure vessels must come principally through the end portions of the pressure vessel rather than directly engaging the exterior surface of cylindrical window section itself; such engagement may cause localized stress concentrations and/or localized deformation, either of which may compromise the integrity of the pressure vessel.

Thus, so far as known, no pressure vessel mounting structure is available for sealably mounting a cylindrical window section so as to accommodate variations in pressure and temperature while permitting connection to all chamber utilities through a non-end portion mounting structure, while also providing internal mounting surfaces for securing internal chamber utilities therewith and while

further providing a structure for supporting the pressure vessel separate and apart from the end portions thereof.

Disclosure of the Invention

The present invention relates to a new and improved mounting structure for a cylindrical window section of a pressure vessel, the mounting structure having a cylindrical outer band, a mounting block within the outer band, structure for securing the outer band and mounting block with the pressure vessel, and a seal member positioned within the outer band and adjacent to the mounting block, with the seal member being axially movable with respect to the outer band for maintaining a sealable engagement of the cylindrical window section between the seal member and the end portion of the pressure vessel.

Brief Description of the Drawings

FIGURE 1 is an isometric, perspective view of a pressure vessel, notably a hyperbaric chamber, of the type adapted to use the mounting structure of the present invention; FIGURE 2 is a top, sectional view of the pressure vessel, showing the mounting structure of the present invention;

FIGURE 3 is an elevational view of the mounting structure of the present invention, as taken along the lines 3-3 of FIGURE 2;

FIGURE 4 is an elevational, enlarged, sectional view of the securing means of the mounting structure of the present invention;

FIGURE 5 is a sectional view of the mounting structure of the present invention, as taken along the lines 5-5 of FIGURE 3; FIGURE 5A is a sectional detail of the seal member of the mounting structure of the present invention, as illustrated in an elevated, pressured condition as compared with that as shown in FIGURE 5; and,

FIGURE 6 is a sectional view of the mounting structure of the present invention, similar to FIGURE 5, showing an alternative embodiment of the seal member and outer band of the mounting structure of the present invention.

Best Mode for Carrying Out the Invention The mounting structure of the present invention is generally designated with the letter M. The mounting structure M is adapted to be used with a pressure vessel V. Pressure vessel V generally includes cylindrical window sections W and end portions E. The mounting structure M includes generally a cylindrical outer band O, a mounting

block B mountable within the outer band O, securing means G for securing the outer band O and mounting block B with the pressure vessel V, and a seal member S mounted within the outer band O adjacent the mounting block B for engaging the cylindrical window section W to maintain a sealable relationship between the seal member S and the end portion E of the pressure vessel V.

The mounting structure M of the present invention is to be used with the pressure vessel V. As shown in FIGURE 1, the pressure vessel V includes cylindrical window sections W which includes windows 10, 12 having an outer annular surfaces 10a, 12a, inner annular surfaces 10b, 12b, a first radial surface 10c, 12c, and a second radial surface lOd, 12d. Preferably, the windows 10, 12 of the cylindrical window section W are formed of a suitable, high strength polymeric material capable of withstanding the high internal pressures within pressure vessels V of the type that are typically used as hyperbaric chambers. For example, many hyperbaric chambers routinely operate at three atmospheres of internal pressure and for safety considerations are pressure tested to 4% atmospheres. The pressure vessel V may be constructed having a single window 10, or utilizing dual windows 10, 12 as shown in the figures. Additional, multiple window sections (not shown) may be used if desired.

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The pressure vessel V further includes end portions E which may include a closure member 14 and an end plate 16. The closure member 14 may be of the type described in my pending application serial number , filed , entitled "CLOSURE MEMBER FOR

PRESSURE VESSEL" and includes generally a pressure vessel door 14a and a ring assembly 14b. The ring assembly 14a interacts with the pressure vessel door 14a to permit a locked or unlocked condition as may be desired. In typical operation, the pressure vessel door 14a may be opened to allow access into the chamber 18 (FIGURE 3) within the pressure vessel V, with the pressure vessel door 14a thereafter being adapted to be closed. The ring assembly 14b is rotatable from an unlocked position to a locked position so that the closed pressure vessel door 14a is maintained in a lockable, sealable relationship therewith so as to permit pressurizing the pressure vessel V. The end plate 16 of the end portion E may be formed of stainless steel or any other suitable high strength material as may be desired.

As discussed more fully hereinbelow, the pressure vessel V, including the cylindrical window section W, end portions E and mounting structure M are adapted to be supported by base structure 20 which may include a floor platform 20a, a central support 20b and pressure vessel

platfor 20c. The floor platform 20a may be permanently secured to the floor or, in the alternative, may be mounted on rollers or other suitable means for moving the pressure vessel V as may be desired. The central support 20b is sized so as to elevate the pressure vessel V to a proper working height so that ease of access is provided to the attendant for manipulation of control knobs 22a of the control panel 22, for monitoring the various gauges 22b, for utilizing the communications equipment 22c and also enhancing ease of access to the patient bed 24. Preferably, the control panel 22 is mounted with the pressure vessel platform 20c, with the pressure vessel platform 20c also supporting the pressure vessel V. The patient bed 24 is preferably positioned on rollers (not shown) and supported on rails (not shown) mounted with the pressure vessel V. The patient bed 24 may be fully extended outwardly from within the chamber 18 of the pressure vessel V when the pressure vessel door 14a of the closure member 14 is in a fully open position so as to permit attendant access to the patient either on, to be placed upon or removed from the patient bed 24. The patient bed 24 may thereafter be re-positioned within chamber 18 of the pressure vessel V and the pressure vessel door 14a thereafter properly secured for hyperbaric treatment of the patient. The control panel 22 contains

all the various attendant controls necessary for monitoring and safely operating the pressure vessel V.

The mounting structure M of the present invention includes an outer band 30 which is preferably of a cylindrical configuration, having an outer annular band surface 30a, and an inner annular band surface 30b, and radial end surfaces 30c, 30d formed at the extremities of and joining the inner and outer annular band surfaces 30a, 30b. Preferably suitable openings 30e, 3Of (FIGURE 5, FIGURE 6) are formed extending between the inner and outer annular band surfaces 30a, 30b. As best seen in FIGURE 5, annular surfaces 30g, 3Oh and adjacent radial surfaces 30i, 30j, respectively, are formed adjacent radial end surfaces 30c, 30d, respectively. The mounting structure M of the present invention may preferably further include a mounting block B which includes mounting block 40. The mounting block 40 includes an outer annular block surface 40a, an inner block surface 40b and radial end surfaces 40c, 40d. Stepped openings 40e, 4Of are formed in the block 40 and adapted to be sized and aligned with openings 30e, 3Of, respectively formed in outer band 30. The outer annular block surface 40a is adapted to be positioned adjacent to inner annular band surface 30b of the outer band 30. As shown in FIGURE 3, the mounting block 40 may be of a substantially continuous

cylindrical configuration as viewed in a plane substantially perpendicular to the axial length of the pressure vessel V. As shown in FIGURE 4, the mounting block 40 may alternatively be of a segmented circular cross-sectional configuration, with such arcuate block sections 40s having radial surfaces 40g, 40h.

The mounting structure M of the present invention further includes securing means G for securing the outer band O and the mounting block B at predetermined fixed axial distance from the end portions E of the pressure vessel V. The securing means G is mounted with the pressure vessel V and includes securing fasteners 50 and tie rods 52, 54, 56, 58 (FIGURE 3). Preferably, each of the tie rods 52, 54, 56, 58 are formed alike. For example, tie rod 52 is formed having an outer annular surface 52a, with an intermediate engaging surface 52b (FIGURE 4) formed adjacent to the area of engagement of the outer annular band surface 30a of the outer band 30 of the outer band 0. Preferably, the tie rods 52, 54, 56, 58 are secured with the end portions E of the pressure vessel V by tie rod fasteners 60 such as fastener 60a (FIGURE 5) . The fastener 60a extends through opening 16o formed in end plate 16 of the end portion E to be received in compatibly formed threaded portion 52c formed adjacent end 52d of tie rod 52. The end 52d of tie rod 52 is received in a suitably formed

tie rod detent, such as tie rod detent 16a formed in end plate 16. Like tie rod fasteners are used for fastening each of the ends of the tie rods 52, 54, 56, 58 with the end plate 16 and the other ends (such as tie rod end 54e) with the closure member 14 (FIGURE 1) , with each of such tie rod fasteners (not shown) being threadedly received in compatibly formed threaded portions (not shown) . As such, each of the tie rods 52, 54, 56, 58 are secured with the end portions E of the pressure vessel V, including at one end with the closure member 14 and at the other, with end plate 16. Securing fasteners 50, such as fasteners 50a, 50b having respective threaded portions 50c, 50d are mountable within stepped openings 40e, 4Of formed in mounting block 40, through aligned openings 30e, 3Of in outer band 30 and thereafter threadedly received in threaded openings 52f, 52g formed adjacent engaging surface 52b in the tie rod 52 for affixing the mounting block 40 and outer band 30 securely with the tie rod 52 of the securing means G. As a result of the securing fasteners 50 and tie rod .fasteners 60, the mounting block 40 of the mounting block B and the outer band 30 of the outer band 0 are fixed at a predetermined axial distance from the end portions E of the pressure vessel V.

The mounting structure M of the present invention may preferably further include a cover plate 70 having an

outer plate surface 70a, inner plate surface 70b and end surfaces 70c, 70d. The cover plate 70 is adapted to be positioned so that the outer plate surface 70a engages the inner block surface 40b of the mounting block 40 and is sized so that the end surfaces 70c, 70d are in alignment with end surfaces 40c, 40d of the mounting block 40 of the mounting block B. In the event that the mounting block 40 is of a continuous cylindrical configuration as shown in FIGURE 3, then the outer plate surface 70a of the cover plate 70 engages the inner block surface 40b of the mounting block adjacent the entire extent thereof. On the other hand, if the mounting block 40 is an arcuate block section 40s as shown in FIGURE 4, then a cavity 72 is formed between the inner annular band surface 30b, the outer plate surface 70a of the cover plate 70 and end surfaces 40g, 4Oh of adjacent arcuate block sections 40s. Alternatively, an annular detent (not shown) may be formed in either the outer annular block surface 40a or the inner block surface 40b for forming a cylindrical cavity as may be desired. Such a cavity 72 may be useful for mounting various pressure vessel utilities (wiring, fluids, etc.) for utilization of the pressure vessel V of the present invention. Furthermore, the cover plate 70, or in the absence thereof the mounting block 40, provides suitable structure for mounting pressure vessel apparatus 73, such

as handrails 74, 76 (FIGURE 3) within the chamber 18, and a variety of hooks, such as hook 78, for supporting fluid bags 80 or any number of other monitoring/life support devices connected to or for the patient within such a pressure vessel V. As best seen in FIGURE 3, it is preferred that the cover plate 70 be formed so as to be less than 360° in cross section in a plane perpendicular to the axial length of the pressure vessel V. Thus, an opening is formed between surface portions 70r, 70s for ease of providing appropriate connections for the various pressure vessel apparatus 73, such as fluid bags 80 and/or monitoring/life support devices.

The mounting structure M of the present invention further includes a seal member S which includes a seal member 90. The seal member 90 includes an outer annular seal surface 90a, an inner seal surface 90b, radial end surface 90c and window engaging surface 90d. A tapered surface 90e may be formed between the window engaging surface 90d and inner seal surface 90b. The window engaging surface 90d may be formed having an annular surface 90f and radial surface 90g. Seal detents 90h, 90i receive outer band seal means 92, including band seals 94, such as seals 94a, 94b, respectively, for sealably engaging the seal member 90 with the inner annular band surface 30b of outer band 30.

The mounting structure M of the present invention further includes window seal means designated generally 96 disposed between the window engaging surface 90d of the seal member 90 and the cylindrical window sections W for establishing a sealable relationship therebetween. The window seal means 96 may include compressible packing 96a, such as that formed of neoprene, an o-ring 96b, such as those formed of Buna-N, and a cylindrical seal 96c, preferably formed of neoprene. Preferably, the compressible packing 96a is disposed between radial surface 90g, annular surface 90f of the window engaging surface 90d, the annular surface 3Oh and adjacent radial surface 30i of the outer band 30 and the second radial surface lOd of the window 10 (FIGURE 5) . The o-ring 96b of the seal means 96 preferably is disposed between the inner annular surface 10b of the window 10 and the annular surface 9Of of the window seal member 90, with the cylindrical seal 96c likewise positioned adjacent thereto (FIGURES 5, 5A) . Seal member 98 is a mirror image of the seal member 90, with seal member parts, 98a through 98i, denominating like parts with seal member 90. Seals 94c, 94d of the band seals 94 of the outer band seal means 92 sealably engage the seal member 98 with the inner annular band surface 30b of the outer band 30. Preferably, seal member 90 engages window 10 which abuts the closure member 14 of the end portion E.

Seal member 98 having window seal means 100, with like parts denominating like elements for seal means 100 as with window seal means 96, engages window 14, which abuts end plate 16 of the end portion E. Thus, window seal means 96, 100 establish a sealable relationship between the window engaging surfaces 90g, 98g of seal members 90, 98 of the seal member S of the present invention with the windows 10, 12 of the cylindrical window sections W.

As best seen in FIGURE 5, the end plate 16 is formed having annular surfaces 16b, 16c and an adjoining radial surface 16d for receiving the window 12, with suitable end seal means 102 disposed therebetween. The end seal means 102 includes compressible packing 102a, o-ring 102b, and cylindrical seal 102c, much like window seal means 96, 100. As such, the compressible packing 102a is disposed between the first radial surface 12c of window 12 and radial surface 16d of end plate 16 of the end portion E, as located between annular surfaces 16b, 16c formed at end plate 16. The o-ring 102b is preferably disposed between the inner annular surface 12b of window 12 and the annular surface 16c of end plate 16, with cylindrical seal 102c being likewise disposed between inner annular surface 12b and annular surface 16c and adjacent to o-ring 102b. As such, the window 12 is located between the end plate 16 of end portion E and seal member 98, while window 10 is

disposed between closure member 14 of the end portion E and seal member 90.

As best seen in FIGURE 6, the outer band 30 and seal members 90, 98 may be of an alternate configuration. In this alternative configuration the outer band 30 has no annular surfaces 30g, 30h nor radial surfaces 30i, 30j, but rather has a continuous inner annular band surface 30b that spans between radial end surfaces 30c, 30d. With respect to the seal members 90, 98, the outer annular seal surfaces 90a, 98a extend between radial end surfaces 90c, 98c and window engaging surfaces 90d, 98d, with the seal members 90, 98 being sized so as to form annular surface 90j, 98j adjacent to radial surfaces 90g, 98g and annular surfaces 90f, 98f, for forming the respective window engaging surfaces 90d, 98d, respectively.

In the use or operation of the mounting structure M of the present invention, it is preferred that in the makeup of the pressure vessel V that the cylindrical window sections W be secured between the mounting structure M and the end portions E of the pressure vessel V. The seal members 90, 98 permit the windows 10, 12 to be snugly, but not necessarily in a sealably fluid-tight relationship, positioned between other pressure vessel V components that are securely affixed together, noting that the mounting block B, outer band O, tie rods and fasteners of the

securing means G are all securely affixed with the end portions E of the pressure vessel V. When the pressure vessel V is pressurized, that is the closure member 14 is closed and locked and the pressure within the pressure vessel V is greater than that of the outside pressure, the internal pressure within the chamber 18 acts on radial end surfaces 90c, 98c of the seal members 90, 98, thus urging each of the seal members 90, 98 towards the respective closure member 14, end plate 16 of the end portions E. This action results in the windows 10, 12 being sealably engaged with the seal members 90, 98 via window seal means 96, 100 as the seal members 90, 98 are urged axially away from the mounting block B and towards their respective end portions E. Indeed, under pressure, the gap 110 (FIGURES 5, 6) increases to a greater gap 112 (FIGURE 5A) as a result of the pressure acting on radial end surfaces 90c, 98c. In FIGURE 5A, the pressure is depicted by the arrows 114 as such acts on radial end surface 90c. Under such a circumstance, the compressible packing 96a may move away from radial surface 30j, as shown in FIGURE 5A, in accommodating the axial movement of the seal member 90. The ability for the seal members 90, 98 to move axially permits a sealable relationship to be maintained with the windows 10, 12, despite variations in pressure and temperature which can affect the overall dimension and/or

sizing of such windows 10, 12 of the cylindrical window sections W. This axial movement also permits less critical axial sizing of the various component parts of the pressure vessel V in the makeup/assembly of the windows 10, 12, closure member 14, end plate 16, and tie rods 52, 54, 56, 58, respectively. Furthermore, as shown in FIGURE 5, when the seal member 98 moves axially away from the mounting block B towards end plate 16 of the end portion E, the window 12 is further forced into a sealable relationship with the end seal means 102 including the compressible packing 102a, o-ring 102b and cylindrical seal 102c, recognizing that pressure within the chamber 18 also acts upon cylindrical seals 102c, 100c and o-rings 102b, 100b to force such seals into a sealable relationship with the inner annular surface 12b of window 12 and respective annular surfaces 98f, 16c.

It will be appreciated that utilization of the mounting structure M of the present invention may be used with a pressure vessel V having a single cylindrical window section W or a pressure vessel V having two windows 10, 12 as depicted in the drawings. Additional cylindrical window sections W may also be used by interposing an additional mounting structure M between adjacent window sections W of the pressure vessel V, as may be desired. Alternatively, the mounting structure M may be positioned adjacent one or

both of the end portions E of the pressure vessel V, if so desired.

As a result of the mounting structure M of the present invention, pressure vessel apparatus 73 such as handrails 74, 76, hooks 78, and other useful devices typically needed within hyperbaric chambers, may be easily mounted and secured within the chamber 18 of the pressure vessel V. To the extent prior art pressure vessels use a continuous cylindrical window along the entire length of the pressure vessel V, because structural weakening and/or stress concentrations, no such items are mountable on the interior surface of a continuously formed cylindrical window.

Furthermore, the structural arrangement of the mounting block B, outer band O and tie rod/fasteners of the securing means G affixation with the end portions E of the pressure vessel V, permits the mounting structure M of the presen ^t invention to become a support point for the entire pressure vessel V. Prior art pressure vessels utilizing a singular continuous cylindrical window rely upon pressure vessel support adjacent the end portions, with any portion of the cylindrical window being prohibited from supporting the pressure vessel V because of structural strength considerations. By use of the mounting structure M of the present invention, the pressure vessel V may be supported

entirely by the mounting structure M by use of a base structure mount 20m (FIGURE 3) of the base structure 20 or, in the alternative, the entire pressure vessel V may be suspended by suitable vertical support (not shown) that connects with the mounting structure M of the present invention via vertical support members 116. The vertical support members 116 may each include a support 116a that is affixed to the outer annular band surface 30a of the outer band 30 by fastener 116b. By supporting the pressure vessel V with support members 116, the floor areas proximate the pressure vessel V are made available for other uses, thus avoiding the need and requirement of end portion E support. All hyperbaric chamber utilities are capable of being routed into the chamber 18 via the mounting structure M with all of the various components capable of being routed through cavities, such as the cavity 72 (FIGURE 4) . Furthermore, a pressurizing line 120 may be affixed with the mounting structure M by a suitable pressure connector 122 which communicates with the chamber 18 within the pressure vessel V. Such a connection would not be possible in a pressure vessel V formed solely of a cylindrical window W, as any opening penetrating the wall thickness of such a window compromises the strength and integrity of such a window.

Thus, the mounting structure M of the present invention provides a new and improved structure for securing a cylindrical window W with a pressure vessel V, permitting ease of assembly, increased internal mounting surfaces for chamber utilities and for centralizing the support and strength of the overall pressure vessel V.

The foregoing disclosure and description of the invention are illustrative and explanatory thereof, and various changes in the size, shape and materials, as well as the details of the illustrated construction may be made without departing from the spirit of this invention.

Industrial Applicability

The mounting structure for a cylindrical window section of a pressure vessel of the present invention provides significant technical advantages for those in the pressure vessel industry. In the context of hyperbaric chambers, such of the type used for treating medical illnesses and/or injuries, the ability to use a "see through" pressure vessel has distinct advantages in the sense of allowing ease of monitoring of activities within the chamber. On the other hand, the present invention is not solely limited to hyperbaric (medical) chamber operations but rather may be used for any pressure vessel situation where external attention to the internal vessel operations is required. By utilizing the mounting

structure of the present invention which includes a cylindrical outer band, a mounting block mountable within the cylindrical outer band, securing members for securing the outer band and mounting block at a predetermined fixed axial distance from the end portion of the pressure vessel, and a seal member for axial movement with respect to the outer band for maintaining sealable engagement of the cylindrical window section between the seal member and the end portion of the pressure vessel, the ability to provide window sections in pressure vessel assemblies is accomplished, while maintaining significant strength capabilities in a wide variety of chamber operations. Because of the cylindrical outer band structure, a pressure vessel utilizing the mounting structure of the present invention is capable of being mountable not only by a supporting base but being suspended in any desired orientation to accomplish the desired purpose for the particular pressure vessel involved, all while allowing user viewing of the internal portion of the pressure vessel as may be required by the particulars of any given situation. Thus, the mounting structure of the present invention permits centralized multi-directional support along with overall pressure vessel strength.