Method for the production of a plastic tank comprising an anti-slosh device

Abstract

A process is disclosed for manufacturing at least one wall of a tank and comprises at least a first layer of thermoplastic and a second foam-based layer. The second foam-based layer forms at least part of an anti-slosh device, and the process is characterized in that the first layer and the second layer are molded in the same mold.

Claims

1. A process for manufacturing at least one wall of a tank comprising at least a first layer of thermoplastic and a second foam-based layer, said second foam-based layer forming at least part of an anti-slosh device, the first layer and the second layer being molded in the same mold, comprising: a thermoplastic preform comprising at least the first layer and the second layer is inserted into said same open mold; said same mold is closed; and once said same mold is closed, the preform is blow-molded by means of a fluid under pressure to press the preform against said same mold, wherein said second layer is a layer formed from a blend of a thermoplastic polymer and of a chemical foaming agent, and in that, once said same mold is closed, a gas or a liquid containing a reagent is injected into the closed mold, so as to trigger a foaming reaction of the foaming agent of the second layer.

2. The process according to claim 1, wherein, to obtain the thermoplastic preform comprising at least the first layer and the second layer, the first layer and the second layer are simultaneously extruded.

3. The process according to claim 1, wherein the preform further comprises an intermediate layer comprising at least one adhesive.

4. The process according to claim 1, wherein the preform further comprises at least one of a barrier layer against hydrocarbons or a layer comprising recycled plastic, being located between said first layer and said second layer.

5. The process according to claim 1, wherein the chemical foaming agent is azodicarbonamide.

6. A process for manufacturing at least one wall of a tank comprising at least a first layer of thermoplastic and a second foam-based layer, said second foam-based layer forming at least part of an anti-slosh device, the first layer and the second layer being molded in the same mold, comprising: said same mold is placed in a first closing position so as to form a first injection-molding cavity; said first layer is injection-molded; said same mold is placed in a second closing position so as to form a second injection-molding cavity; said second layer is injection-molded; and a gas is injected into said same closed mold, so as to trigger a foam expansion reaction.

7. The process according to claim 6, wherein said first injection-molded layer comprises at least one attachment cavity into which said second layer can penetrate during its injection into the second injection-molding cavity.

8. The process according to claim 6, wherein said same mold comprises several points for injecting said second layer.

9. The process according to claim 6, wherein said second layer is a layer of polyurethane foam.

10. The process according to claim 6, wherein said second layer is a layer of polymer foam.

11. The process according to claim 1, wherein the reagent injected is based on nitrogen or carbon dioxide.

12. The process according to claim 6, wherein the gas injected is nitrogen.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) FIGS. 1a to 1c serve to illustrate, as an indicative and nonlimiting example, the principle of an extrusion blow-molding manufacturing process according to the first particular embodiment of the invention.

(2) FIGS. 2a to 2d serve to illustrate, as an indicative and nonlimiting example, the principle of an injection-molding manufacturing process according to the second particular embodiment of the invention.

(3) FIGS. 3a to 3d serve to illustrate, as an indicative and nonlimiting example, the principle of a second injection-molding manufacturing process according to the second particular embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

(4) According to a first embodiment of the invention, and as illustrated in FIG. 1a, a plastic parison (1) is introduced between two mold cavities of a mold (2) in the open position. The parison (1) is introduced into the mold (2) while being held open/separated. The mold (2) comprises mold cavities (3, 4). The mold cavities (3, 4) of the mold have an inner surface (3′, 4′) corresponding to the outer surface of the tank to be molded.

(5) In this exemplary embodiment, the parison (1) comprises a multilayer structure. It thus comprises an inner layer, which is itself composed of a first layer of HDPE (high-density polyethylene) and a second layer of a chemical foaming agent, an intermediate layer comprising an adhesive, and an HDPE-based outer layer. It will be noted that the intermediate adhesive layer is optional.

(6) The inner layer of the parison is in a viscous state at the temperatures for forming the parison (1), and its viscosity, at the time of its introduction into the mold, is similar to that of the high-density polyethylene used in a standard tank-forming process.

(7) Moreover, at the time of its introduction into the mold (2), i.e. before the blow-molding operation, the second layer of foaming agent, which is reactive but not yet foamed, is integrally attached to the HDPE first layer. To this end, the layer of foaming agent is preferably produced simultaneously therewith by extrusion.

(8) A reagent for engaging a foaming reaction (or activation of the foaming agent) is, in the first embodiment illustrated in FIGS. 1a to 1c, introduced during the phase of blow-molding of the tank, once the tank mold has been reclosed on the parison (1). Preferably, this introduction of the reagent into the mold (2) is performed by introducing a specific gas, comprising the reagent, during the blow-molding phase.

(9) Advantageously, the concentration of foaming agent, and also the thickness of the inner layer, must make it possible to produce, after the foaming reaction, a layer constituted mainly of open cells. The thickness of this said layer in the final state is advantageously between 5 mm and 200 mm.

(10) FIG. 1b illustrates the step of blow-molding of the parison. During this step, the mold is completely closed. It may be seen that the mold cavities of the mold are adjoined via their periphery. During this blow-molding step, the outer wall (5) of the tank and a foam-based inner anti-slosh device (6) will be formed.

(11) Specifically, during the blow-molding step, the gas containing the reagent for triggering the foaming reaction in the mold (2) is introduced, so as to totally or partially replace the air or the dinitrogen usually used in the blow-molding process. Expansion of the foam is controlled by varying the temperature, the pressure, the concentration of reagent in the blow-molding gas, and the times of exposure of the inner layer of the tank with the reagent. Preferably, the gas comprising the reagent is nitrogen and the reagent is based on nitrogen or carbon dioxide (CO.sub.2).

(12) In the case of a tank made from a parison, the joint plane of the tank is exposed to the reagent only during the pre-inflation phase. This pre-inflation phase may proceed using a blow-molding gas not containing any reagent, the reagent being introduced after the end of the pre-inflation phase.

(13) In the context of a tank made from two sheets, the joint plane is not exposed to the reagent.

(14) Moreover, still in the context of a tank made from two sheets, the expansion of the foam may be mechanically constrained by elements supported by the core of the mold (2), such as counterforms mounted on a core of the blow-molding mold. These counterforms are mobile or immobile parts of the mold (2) for mechanically controlling the expansion of the foam by blocking it, if necessary.

(15) It will be noted that the phase of activation of the foaming agent has very little impact on the blow-molding time of conventional tanks. Nevertheless, it may be necessary to purge the gas containing the reagent before terminating the blow-molding process.

(16) When the assembly is cooled, the mold is opened (i.e. the mold cavities are separated from each other) and the tank may be stripped from the mold. This is illustrated in FIG. 1c. A tank having, in its slosh zones, an open-cell foam coating, the presence of which makes it possible to limit the structure-borne noise or slosh noise in the tank, is thus obtained. The tank thus manufactured thus advantageously comprises an anti-slosh device fixed onto its inner periphery.

(17) According to a second embodiment of the invention, the tank is manufactured by injection-molding.

(18) A mold (10) may be seen in a first closing position in FIG. 2a. The mold is connected to an injection screw (20). In this first closing position, a first injection-molding cavity (30) is formed between the mold cavities (11, 12) of the mold.

(19) Next, as may be seen in FIG. 2b, the injection screw (20) injects a thermoplastic polymer into the first injection-molding cavity, so as to mold a first wall element (i.e. said first injection-molded layer) (40).

(20) Advantageously, the mold cavity (12) of the mold comprises a mobile part (120) configured so as to move relative to the mold cavity (12).

(21) The mold (10) may be seen in a second closing position in FIG. 2c. As illustrated, the mold passes from the first closing position to the second closing position by moving the mobile part (120) in a direction indicated by the arrow (50). In this second closing position, a second injection-molding cavity (60) is formed between the mold cavities of the mold.

(22) As illustrated in FIG. 2d, the mold (10) is connected to an injection nozzle (80) configured to inject a polymer foam into the second injection-molding cavity (60). The polymer foam may be, for example and in a nonlimiting manner, a polyurethane foam.

(23) This polyurethane foam is preferably derived from a blend of several liquid components. These components are, for example, blended under temperature and pressure conditions chosen so as to form a liquid that is injectable by means of a high-pressure blending machine, which is known per se, of which the injection nozzle (80) forms part.

(24) Preferably, a gas, such as nitrogen, is added to the blend to engage a foam expansion reaction. Thus, a liquid foam supplemented with such a gas is preferably injected directly into the second injection-molding cavity (60). This also makes it possible to optimize the size of the porosities of the foam. It will be noted that the expansion reaction is due both to the blending of the products and to the conditions for injecting the blend and the gas.

(25) By this means, a second wall element (i.e. the second injection-molded layer) (70) is molded onto the first wall element (40).

(26) Advantageously, the second wall element (70) may form all or part of an anti-slosh device that is inside the tank.

(27) FIGS. 3a to 3d serve to illustrate, as an indicative and nonlimiting example, the principle of a second injection-molding manufacturing process according to the second particular embodiment of the invention.

(28) FIGS. 3a and 3b represent steps similar to those illustrated in FIGS. 2a and 2b, in which may be seen a mold (110) in a first closing position, the joint plane P joining the mold cavities (111, 112) of the mold of the mold being closed.

(29) The mold may be seen in a second closing position in FIG. 3c, the joint plane P being open. As illustrated, the mold passes from the first closing position to the second closing position by moving, for example, the mold cavity (112) in a direction indicated by the arrow (150), the mold cavity (111), or alternatively by moving the two mold cavities of the mold (110). In this second closing position, a second injection-molding cavity (160) is formed between the mold cavities of the mold. Advantageously, the mold cavity (112) may be comprise a mobile part (220) configured to move relative to the mold cavity (112) and thus better control the size of the second injection-molding cavity (160).

(30) As illustrated in FIG. 3d, the mold is connected to an injection nozzle (180) configured to inject a polymer foam into the second injection-molding cavity (160). The polymer foam may be, for example and in a nonlimiting manner, a polyurethane foam.

(31) This polyurethane foam is preferably derived from a blend of several liquid components. These components are, for example, blended under temperature and pressure conditions chosen so as to form a liquid that is injectable by means of a high-pressure blending machine, which is known per se, from which is derived the injection nozzle (180).

(32) Preferably, a gas, such as nitrogen, is added to the blend to engage a foam expansion reaction. Thus, a liquid foam supplemented with such a gas is preferably injected directly into the second injection-molding cavity (60). This also makes it possible to optimize the size of the porosities of the foam. It will be noted that the expansion reaction is due both to the blending of the products and to the conditions for injecting the blend and the gas.

(33) By this means, a second wall element (i.e. said second injection-molded layer) (70) is molded onto the first wall element (140).

(34) This step of injection-molding of the foam is performed with a joint plane P of the open mold which allows easy control of the expansion of the injected mold due to the depressurization created within the mold by opening the joint plane P. This opening also makes it possible to obtain an easier injection path for the injection nozzle (180).

(35) After injecting the foam, it catalyzes and optimizes its expansion by means of the addition of gas and brings about an exothermic reaction. The free space of the cavity of the tool will thus be gradually completely filled with the foam. This expansion will be able to be controlled by the system for regulating the injection-molding tool. To this end, the injection-molding cycle time will be adapted to obtain a flexible foam.

(36) After expansion, the mold is opened at high speed so as to create a decompression allowing perforation of the thin walls of the closed foam. Thus, at the end of the manufacturing cycle, a tank half-shell is obtained, having, in its slosh zones, an open-cell foam coating, the presence of which makes it possible to limit the structure-borne noise or slosh noise in the tank. Thus, advantageously, the second wall element (170) may form all or part of an anti-slosh device that is inside the tank.

(37) In an advantageous embodiment, the first wall element (formed by the first injection-molded layer) may comprise one or more attachment cavities into which the polymer foam may penetrate during its injection into the second injection-molding cavity. In this way, solid mechanical fixing is obtained between the first and second wall elements. The attachment cavities form, for example, a network of ribs on the portion of the first wall element (140) which is facing the second wall element (70), or a back-draft.

(38) In an alternative, the mold may comprise several foam injection points and also several thicknesses depending on the need.

(39) The invention is not limited to the embodiments presented, and other embodiments will emerge clearly to a person skilled in the art. In particular, in another particular embodiment of the injection-molding process described with reference to FIGS. 2 and 3 above, the injection nozzle is adapted to inject any type of polymer foam. In a particular embodiment, the injection nozzle is capable of injecting at least two distinct types of polymer foams at different moments in the process.