Tank lining system with neck seal

Description

BACKGROUND OF THE INVENTION

[0001] Various water tanks and the like are desirably lined with a flexible plastic barrier to prevent corrosion of the tank, or the leaching of undesirable substances. This is especially the case when the tank body is made of steel which, apart from the corrosion problem, can exhibit significant advantages over other materials.

[0002] As described in US-A-4,537,329, a system is provided for connecting a plastic tank lining to a penetration fitting which forms an opening through a tank wall. By this present invention, an improved structure for a tank is provided which is easier to assemble, and which provides an air and water tight seal between the liner and the tank wall without the use of sealants or direct compression gaskets. A direct compression gasket is a gasket which is under constant compression. A disadvantage of such a gasket is that, over a period of time it can take a compression set due to the constant pressure and can lose effectiveness.

[0003] Likewise, the time and effort required to place the tank lining system into a tank is reduced in this invention over prior art systems, while excellent results of sealing and durability are achieved.

[0004] Additionally, The Culligan International Company has sold a tank lining system where a yoke is required. By this invention such a yoke is eliminated.

[0005] The pre-characterising part of claim 1 is based on US-A-4 537 329, and the distinguishing features of the present invention are set out in claim 1.

[0006] According to a preferred embodiment, a tank lining system comprises a tank having a wall defining a first opening. A flexible sheet lining abuts the interior surface of the wall and defines a second opening that is aligned with the first opening of the tank wall. A first collar surrounds the first opening, the first collar being attached to the tank, typically by welding when the tank is metal and the first collar is made of a metal which is compatible to the metal of the tank. For example, both the tank and the first collar may be made of steel.

[0007] According to the preferred embodiment, a second collar surrounds the second opening, and is attached by an appropriate sealing to the flexible sheet, for example radio frequency (RF) heat sealing, solvent welding, spin welding, ultrasonic welding, contact heating, or any other desired process. Typically, the flexible sheet may be made of vinyl plastic or polyurethane sheeting, with the second collar being made of a corresponding, but typically rigid, plastic which is sealingly compatible with the plastic of the sheet.

[0008] Means are provided for retaining the first and second collars together, while providing a seal of the junction area that is defined between them.

[0009] There is provided an O-ring for sealing the junction area, with the O-ring being of the non-direct compression type, as is the case with respect to O-rings, for an improved lifetime of the seal.

[0010] It is preferred for the second collar to be surrounded by the first collar in retained-together relation. This retained-together relation can be accomplished simply by attaching with bolts if desired. However, preferably, the first collar may define spaced, inwardly projecting first locking flange means, while the second collar defines spaced, outwardly projecting second locking flange means which are proportioned to pass axially through and to rotationally interlock with the first locking flange means. Thus, relative rotation of the first and second collars with their respective locking flange means positioned for interlocking can cause the two collars to enter into rotationally interlocking relation with each other through the respective locking flanges, to cause axial locking together.

[0011] Also, it may be desired to provide nut means threadedly connected to the second collar and abutting the first collar to force, upon rotation of the nut means, the first and second locking flange means into axially loaded relation together.

[0012] It is preferred at some time of the assembly process to pressurize with air or liquid the emplaced, flexible liner in the tank, so that air bubbles between the inner wall of the tank and the flexible liner are forced out of the system, through the junction area between the first and second collars prior to applying a seal of that junction area. Then, upon applying the seal, the space between the tank and the sheet lining is essentially sealed and stays that way since, after sealing of the system, air cannot migrate back into the space between the tank wall and the flexible plastic liner.

DESCRIPTION OF THE DRAWINGS

[0013] 

Fig. 1 is a fragmentary, longitudinal sectional view of a water tank having a tank lining system;

Fig. 2 is a sectional view taken along line 2-2 of Fig. 1, showing the system in the process of assembly; and Fig. 3 is a fragmentary, sectional view similar to Fig. 2, showing the system in its assembled form; and

DESCRIPTION OF SPECIFIC EMBODIMENTS

[0014] Referring to Figs. 1 through 3, a steel water tank 10 is disclosed comprising a tank wall 12, to which there is attached a steel first collar 14 which defines a first opening 16. First collar 14 is welded by annular weld line 18 to the remainder of tank wall 12.

[0015] Tank 10 carries an inner plastic liner 20 made of polyvinyl chloride plastic or the like. At the upper end of said plastic liner 20 there is an aperture 21, with an annular section 22 of plastic liner 20 being firmly sealed to second collar 24 by R.F. sealing or the like. Second collar 24 may be made of rigid polyvinyl chloride, as is desirable in such a circumstance to promote sealing compatibility. Second collar 24 fits within first collar 14 in telescoping relation so that a portion of second collar 24 is surrounded by first collar 14.

[0016] Second collar 24 defines, in this embodiment, three outwardly projecting locking flanges 26. As shown in Fig. 2, locking flanges 26 are spaced from each other by spaces that are of typically slightly larger circumferential angle than the circumferential angle of each locking flange 26.

[0017] First collar 14, in turn, defines three inwardly projecting, spaced locking flanges 28. Each of the locking flanges 26, 28 are proportioned and spaced so that they can fit between each other, as particularly shown in Fig. 2, when the first and second collars 14, 24 are moved axially with respect to each other. Thus, the respective collars can be placed into a position as illustrated in Fig. 1 and also Fig. 3 by passing through the configuration of Fig. 2, and then relatively rotating first and second collars 14, 24 to the position of Figs. 1 and 3 where the respective locking flanges 26, 28 are placed in rotationally interlocking relation, to retain the respective collars 14, 24 together in axially locked relation.

[0018] Second collar 24 also defines an annular, outwardly projecting flange 30, which carries an O-ring 32. Thus, the junction area between the respective collars 14, 24 is sealed by the presence of O-ring 32. However, prior to the insertion of O-ring 32 into the system, it is typically possible to inflate flexible liner 20 to press it tightly against wall 12 of the tank, to force virtually all air out of the junction area between liner 20 and wall 12, with the air migrating through the junction area between first and second collars 14, 24. Then, O-ring 32 may be inserted, to prevent migration of air back into the junction area between wall 12 and liner 20.

[0019] Following this, threaded nut 34 may be applied to external threads 36 of collar 24. The nut member is rotated downwardly until its flange 38 abuts an annular shoulder 40 of first collar 14, generating upward pressure on second collar 24 relative to first collar 14. This causes a load to be developed between the respective locking flanges 26, 28 for improved sealing and retention of the system.

[0020] Nut 34 may abut the shoulder 40 of first collar 14 through a shroud or cover 42, which may be made of sheet steel or the like, to protect the upper portion of the tank, as shown in Fig. 1. Shroud 42 also carries a lower annular seal member 44, which seals against the tank wall 12.

[0021] Thus, the tank lining system is provided with relatively simple construction, with the flexible tank liner carrying second collar 24 in sealed relation, so that the respective first and second collars are easily locked together and sealed without the complexities required in the prior art.

[0022] Second collar 24 also defines internal threads 46 in aperture 21, for attachment to a conventional adaptor.

[0023] If it is desired to further facilitate the draining of air from between wall 12 and flexible liner 20, one or more ports 46' may be formed in the wall 12 of the tank, to facilitate the bleeding of air bubbles from between the respective members 12, 20. Then, when the process is finished, port or ports 46' may be closed with a sealant or the like, as shown in Fig. 1. This may be used in conjunction with draining air through the junction area between first and second collars 14, 24, or it may be used as a substitute for that technique.

[0024] Shroud 58 provides external protection and provides the system with an aesthetic look.

[0025] Thus, a simplified tank liner system is provided, which is easier to install and which exhibits excellent durability and useful life. The flexible liner 20 is simply inserted into the mouth of the tank. The respective collars are secured together. The tank system is pressurized, or filled with water, to force the liner into intimate relation with the tank wall, and the system can be closed up and ready for years of useful life.

Claims

1. A tank (10) comprising a wall (12) defining a first opening (16); a flexible sheet lining (20) abutting the interior surface of said wall (12) and defining a second opening (21) aligned with the first opening (16); a first collar (14) surrounding said first opening (16); a second collar (24) surrounding said second opening (21) and attached to said flexible sheet lining (20); and means (26,28) for retaining said first and second collars together, characterised in that the first collar (14) is attached to the tank wall (12) and surrounds and is spaced from at least a portion of the second collar (24), and a separate O-ring of the non-direct compression type is provided, the O-ring (32) being insertable in the space between the collars (14,24) to form a seal in the junction area between the collars (14,24).

2. The tank of Claim 1 in which said first collar (14) and tank wall (12) are each made of metal, the flexible sheet lining (20) and second collar (24) being each made of plastic materials which are sealingly compatible with each other.

3. The tank of Claim 1 or 2 in which said means for retaining comprises a part of the first collar (14) which defines spaced, inwardly projecting first locking flange means (28), and a part of said second collar (24) which defines spaced, outwardly projecting second locking flange means (26) which are proportioned to pass through and to rotationally interlock with said first locking flange means (28) to cause axial locking together of said first and second collars (14,24).

4. The tank of Claim 3 having a nut (34) threadedly connected to said second collar (24) and abutting said first collar (14) to force, upon rotation of said nut (34), said first and second locking flange means (26,28) into axially loaded relation.

5. The tank of any one of Claims 1 to 4 in which said first and second collars are bolted together.

6. A tank according to any preceding claim, wherein the second collar (24) defines a carrying flange (30) which carries the O-ring.

7. A method of sealing the tank of Claim 1 using the O-ring (32) of Claim 1, comprising (a) evacuating air from the space between the interior surface of said tank wall (12) and said flexible sheet lining (20) to cause the flexible sheet lining (20) to intimately contact the interior surface of the wall (12) with air being evacuated from said space and between the first collar (14) and the second collar (24), and (b) placing said O-ring (32) of the non-direct compression type at the junction between said first and second collars (14,24) to produce a seal between said collars (14,24), thereby preventing the passage of air into the space between the tank wall (12) and the sheet lining (20).

8. The method of Claim 7 further comprising the step of placing (c) a nut (34) over said first and second collars (14,24) and O-ring (32).

Ansprüche

1. Behälter (10), umfassend eine eine erste Öffnung (16) definierende Wand (12), eine an die Innenfläche der genannten Wand (12) anliegende und eine an der ersten Öffnung (16) ausgerichtete zweite Öffnung (21) definierende flexible Folienauskleidung (20), einen genannte erste Öffnung (16) umgebenden ersten Ring (14), einen genannte zweite Öffnung (21) umgebenden und an genannter flexibler Folienauskleidung (20) angebrachten zweiten Ring (24) und Mittel (26, 28) zum Zusammenhalten von besagtem ersten und zweiten Ring, dadurch gekennzeichnet, daß der erste Ring (14) an der Behälterwand (12) angebracht ist und den zweiten Ring (24) umgibt und mit Zwischenraum zu zumindest einem Teil von ihm angeordnet ist und ein separater O-Ring des direktdruckfreien Typs vorgesehen ist, wobei der O-Ring (32) in den Raum zwischen den Ringen (14, 24) einsetzbar ist, um eine Dichtung in der Verbindungszone zwischen den Ringen (14, 24) zu bilden.

2. Behälter nach Anspruch 1, in dem genannter erster Ring (14) und Behälterwand (12) jeweils aus Metall hergestellt sind, wobei die flexible Folienauskleidung (20) und zweiter Ring (24) jeweils aus Kunststoffen hergestellt sind, die schweißungsmäßig miteinander verträglich sind.

3. Behälter nach Anspruch 1 oder 2, in dem genanntes Mittel zum Halten einen Teil des ersten Rings (14), der mit Zwischenraum angeordnete, nach innen vorstehende erste Verschlußflanschmittel (28) definiert, und einen Teil von genanntem zweiten Ring (24) umfaßt, der mit Zwischenraum angeordnete, nach außen vorstehende zweite Verschlußflanschmittel (26) definiert, die bemessen sind, um durch die ersten Verschlußflanschmittel (28) zu passieren und damit drehend in Eingriff gebracht zu werden, um axiales Verriegeln von genanntem ersten und zweiten Ring (14, 24) miteinander zu verursachen.

4. Behälter nach Anspruch 3 mit einer gewindemäßig mit dem genannten zweiten Ring (24) verbundene und am genannten ersten Ring (14) anstoßende Mutter (34) vorzusehen, um beim Drehen der genannten Mutter (34) genanntes erstes und zweites Verschlußflanschmittel (26, 28) in ein axialbelastetes Verhältnis zu zwingen.

5. Behälter nach einem der Ansprüche 1 bis 4, in dem genannter erster und zweiter Ring miteinander verschraubt sind.

6. Behälter nach einem der vorangehenden Ansprüche, wobei der zweite Ring (24) einen Tragflansch (30) definiert, der den O-Ring trägt.

7. Verfahren zum Abdichten des Behälters von Anspruch 1 unter Verwendung des O-Rings (32) von Anspruch 1, umfassend (a) ein Evakuieren von Luft aus dem Raum zwischen der Innenfläche der genannten Behälterwand (12) und genannter flexibler Folienauskleidung (20), um zu bewirken, daß die flexible Folienauskleidung (20) die Innenfläche der Wand (12) eng berührt, wenn die Luft aus dem genannten Raum evakuiert wird, und zwischen dem ersten Ring (14) und dem zweiten Ring (24) und (b) ein Einlegen des genannten O-Rings (32) des direktdruckfreien Typs an der Verbindung zwischen genanntem ersten und zweiten Ring (14, 24), um zwischen den genannten Ringen (14, 24) eine Dichtung herzustellen, wodurch das Strömen von Luft in den Raum zwischen Behälterwand (12) und Folienauskleidung (20) verhindert wird.

8. Verfahren nach Anspruch 7, weiter umfassend den Schritt des Anordnens (c) einer Mutter (34) über genanntem ersten und zweiten Ring (14, 24) und O-Ring (32).

Revendications

1. Réservoir (10) comprenant une paroi (12) définissant une première ouverture (16); un chemisage en feuille souple (20) aboutant la surface intérieure de ladite paroi (12) et définissant une seconde ouverture (21) alignée avec la première ouverture (16); un premier collier (14) entourant ladite première ouverture (16); un second collier (24) entourant ladite seconde ouverture (21) et fixé audit chemisage en feuille souple (20); et un moyen (26.28) pour maintenir ensemble lesdits premier et second colliers, caractérisé en ce que le premier collier (14) est fixé à la paroi de réservoir (12) et entoure et est espacé d'au moins une partie du second collier (24) et un joint torique séparé du type à compression non directe est fourni, le joint torique (32) étant insérable dans l'espace entre les colliers (14,24) pour former un joint étanche dans la zone de jonction entre les colliers (14,24)

2. Réservoir selon la revendication 1, dans lequel lesdits premier collier (14) et paroi de réservoir (12) sont chacun en métal, le chemisage en feuille souple (20) et le second collier (24) étant chacun en matériaux plastiques qui sont compatibles au niveau de l'étanchéité l'un avec l'autre.

3. Réservoir selon la revendication 1 ou 2, dans lequel ledit moyen de maintien comprend une partie du premier collier (14) qui définit des premiers moyens de brides de verrouillage espacées, avancant vers l'intérieur (28), et une partie dudit second collier (24) qui définit des moyens de brides de verrouillage espacées, avançant vers l'extérieur (26) qui sont proportionnées pour passer à travers et s'interverrouiller rotativement avec lesdits premiers moyens de brides de verrouillage (28) pour entraîner le verrouillage axial desdits premier et second colliers (14,24) ensemble.

4. Réservoir selon la revendication 3, ayant un écrou (34) connecté par filetage audit second collier (24) et aboutant ledit premier collier (14) pour forcer, à la rotation dudit écrou (34), lesdits premier et second moyens de brides de verrouillage (26,28) en une relation chargée axialement.

5. Réservoir selon l'une quelconque des revendications 1 à 4, dans lequel lesdits premier et second colliers sont boulonnés ensemble.

6. Réservoir selon l'une quelconque des revendications précédentes, dans lequel ledit second collier (24) définit une bride de support (30) qui porte le joint torique.

7. Procédé d'étanchéification du réservoir selon la revendication 1 en utilisant le joint torique (32) de la revendication 1, comprenant (a) l'évacuation d'air de l'espace entre la surface intérieure de ladite paroi de réservoir (12) et ledit chemisage en feuille souple (20) pour forcer le chemisage en feuille souple (20) à entrer en contact intime avec la surface intérieure de la paroi (12), l'air étant évacué dudit espace et entre le premier collier (14) et le second collier (24), et (b) le placement dudit joint torique (32) du type à compression non directe à la jonction entre lesdits premier et second colliers (14,24) de manière à produire un joint étanche entre lesdits colliers (14,24), empêchant ainsi le passage d'air dans l'espace entre la paroi de réservoir (12) et le chemisage en feuille (20).

8. Procédé selon la revendication 7, comprenant en outre l'opération de placement (c) d'un écrou (34) par dessus lesdits premier et second colliers (14,24) et le joint torique (32).

Drawing