NO20130258A1 - Blowing cans and process for making scrap-free lines - Google Patents

Abstract

A method of blow molding a container from a blow blank of a thermoplastic material comprising at least one opening, the method comprising: - disposing the at least one opening of the blow blank on a blow sheet, - arranging a mold space enclosing the blow blank, - simultaneously blowing the pressure set. gas from the blower into the blower and expand the outer cross-sectional diameter of the blower; and a blowtorch for carrying out the method is disclosed.

Description

Blåsedor and method for producing scratch-free liner

The present invention relates to a scratch-free liner (insert) for a composite pressure vessel, a method for producing such a liner as well as equipment adapted to carry out the method.

Background

A common type of composite pressure vessel consists of an internal gas-tight liner, at least one boss connected thereto for the installation of a valve or similar connection device for filling and emptying the vessel. On the outside of the liner, one or more reinforcement layers are arranged to give the container sufficient strength to store fluid under a desired pressure. This type of container is, among other things, indicated in WO00/66939 and WO98/34063.

Known technique

The liner for pressure vessels has traditionally been produced by blow molding. The method of blow molding is well known in the field. The material to form a hollow or partially hollow object is provided in the form of a blow blank. A blow mandrel is inserted into the blow blank which is placed in a cavity in a mould. Pressurized gas is fed into the blow blank through the blow door which forces the blow blank to expand until it reaches the walls of the cavity in the mold/mold space.

For blow molding of generally bottle-shaped containers with an elongated shape and an opening for filling and emptying arranged at one of the ends, the blow blank is normally shaped as a tube which is open at both ends. This blow blank is placed over the blow door and the cavity in the mold is closed around the blow blank so that the blow blank is closed gas-tight at both ends when the cavity in the mold is closed. The blow blank is consequently pressed or pinched by the closing edges of the cavity of the mold. This area of the blown object will, after the molding process is completed, result in a cold scratch line/squeeze line in the molded object. The material properties such as material thickness will vary in the scratch line area compared to remote from the scratch line.

For blow molding of generally bottle-shaped containers with an elongated shape and an opening for filling and emptying arranged at one end thereof, the blow blank is normally shaped as a tube which is open at both ends. The blow blank is placed over the blow door and the mold is closed around the blow blank so that the blow blank is sealed gas-tight at both ends when the mold is closed. The blown blank is consequently squeezed or pinched by the closing edges of the mould. This area of the blown blank will, after the blow molding process is completed, result in a so-called pinchline in the molded blank. The material properties such as the thickness of the material will vary in the area of the scratch line compared to areas remote from the scratch line. This uneven thickness can affect the reliability of the container to store fluid under pressure. Furthermore, the scratch line in the area around the opening means that the outer surface is uneven and not smooth, often with indentations at the end of the scratch line.

In blow-molded liners for composite gas containers, the boss is normally arranged around the opening that remains in the liner where the blower was introduced. Accordingly, the boss is attached to the liner by welding or gluing in the area comprising the scratch line. The roughness of the scratch line makes it difficult to attach the boss to the liner and providing a smoother outer surface surrounding the opening would be desirable to make the installation of the boss more efficient.

US4,578,028 describes a radially expandable core mandrel for blow molding a container. Here, the core mandrel is radially expandable to press-mold internal fastening devices in the neck area of the container which includes an outlet opening. The main part of the container is blow molded by applying a gas pressure through the core mandrel.

Purpose of the invention

The purpose of the present invention is to provide a method for blowing a liner which reduces or eliminates the presence of one or more scratch lines.

A further object is to provide a method and system which reduces or eliminates the line of sag at both ends of a cylindrical liner.

A further purpose is to provide a blowtorch adapted to carry out the method according to the present invention.

This and other purposes are achieved by a method for blow molding a container from a blow blank of a thermoplastic material comprising at least one opening, where the method comprises

placing the at least one opening of the blow blank on a blow mandrel,

to arrange a mold space that encloses the blow blank,

simultaneously blowing pressurized gas from the blower into the blow blank and expanding the outer cross-sectional diameter of the blower.

In one aspect of the method according to the present invention, the blown blank is pinched between a contact area of the mold space and the blowing die when the outer diameter of the blowing die is expanded. The blown blank will consequently be clamped in a circular line or cross-section of the blown blank, where the blown blank has a generally equal thickness along the circular line and in the areas on either side of the circular line. The remaining part of the blow blank which protrudes from the mold space during the molding process can be removed from the container by cutting along the circular line to thereby form an opening in the container. The thus obtained container will comprise no or very limited scratch lines across the area which encloses the opening.

In a further aspect of the method, the blow blank is cylindrical and comprises a first and a second opening which are internally connected, where the mold space comprises a first and a second opening comprising respective first and second contact areas, where the blow mold comprises first and second surface areas and where the method simultaneously comprises expanding the outer cross-sectional diameter of the first and second surface areas so that the blow blank is sandwiched between the first contact area and the first surface area and the second contact area and the second surface area. This aspect of the method provides a container with two openings both produced without the formation of scratch lines or areas of variation in material thickness of the ice in the area around the openings. The smooth surface and uniform thickness improve the ability to securely attach a boss to each of the openings.

In a preferred embodiment, the container is a liner for a composite pressure vessel.

In another aspect, the present invention provides a blow molder comprising an outer surface arranged for engagement with an opening in a blow blank, the blow molder comprising controllable and reversible expansion means for expanding the outer cross-sectional diameter of the outer surface of the blow molder.

In a further aspect, the outer surface is arranged for engagement with an opening in a blow blank cylindrical or conical with a circular cross-section before and after the expansion.

The blow door may be adapted to receive the opening of a tubular blow blank.

Furthermore, the expansion devices can preferably be controlled expanded at the same time that gas is supplied to the interior of the blowing object from one or more gas supplying openings in the blowing door.

The blower may further comprise a shaft (shaft) which separates the controllable and reversible expansion devices for expansion of the outer cross-sectional diameter of the outer surface of the blower into first and second expansion devices for simultaneous expansion of the tubular blow blank at a first and second end thereof. This aspect of the blower is useful for providing a container with two openings arranged along the central axis of the blower at either end of the container.

The expansion of the cross-sectional diameter of the blow molding tool is, in one aspect of the present invention, between 25 and 150%, preferably between 50 and 100%.

The present invention further provides application of the method according to the present invention for obtaining a liner for a composite pressure vessel, where the liner does not comprise a scratch line in the area near the at least one opening.

The present invention also provides for the use of the blower according to the present invention for the production of a liner for a composite pressure vessel, where the liner does not comprise a scratch line in the area near the at least one opening.

Brief description of the drawings

The present invention will be described in further detail with reference to the attached figures which illustrate embodiments thereof. Figure la illustrates a first embodiment of the blower according to the present invention.

Figure 1b illustrates the blower of Figure 1a in an expanded position.

Figure 2a illustrates the situation before the blow molding starts, with half of the mold space removed for illustration purposes. Figure 2b illustrates the situation during the blow molding process, with half of the mold space removed for illustration purposes. Figure 3a is a cross-sectional view of the position and condition of the blower before the blow molding process starts. Figure 3b is a cross-sectional view of the position and condition of the blower during the blow molding process. Figure 3c is a sketch of the blow molder and the mold seen from above before the blow molding process starts. Figure 4 is a schematic cross-sectional view of the position and condition of the liner during the blow molding process. Figure 5a is a cross-sectional view which schematically illustrates a second embodiment of the present invention comprising an elongated blowing mandrel for obtaining a line-free liner at both ends of a cylindrical liner. Figure 5b is a detailed sketch of the extended end of the blower door and the mold space that encloses it. Figure 6a is a cross-sectional view schematically illustrating the second embodiment of the present invention during the blow molding process. Figure 6b is a detailed sketch of the extended end of the blow door and the mold space that encloses it during the blow molding process.

One skilled in the art will appreciate that the expandable inflator illustrated herein can be constructed in various ways, including various systems for providing the expansion, such as various mechanical expansion devices including a flexible balloon that can be inflated and deflated by controlling the flow of gas into and out of the balloon.

Principle description of the invention

The present invention is explained in further detail with reference to the attached figures which illustrate an embodiment of the invention. Figures la and lb show an outline of a first embodiment of a blow dryer 10 according to the present invention. The blower 10 comprises adaptation devices 20 comprising a controllable shaft 22 in connection with an internal blowing needle 18 comprising openings 12 for the supply of gas to inflate the object to be blown. The adaptation devices are arranged to regulate the movement of the shaft 22 in and out of the adaptation devices. The movement is transferred to the blowing needle 18. Figure 1a illustrates the blowing needle 18 and the shaft 22 in a retracted position, while Figure 1b illustrates the blowing needle and the shaft in an extended position. The blower needle 18 comprises a conical section and the diameter of the free end of the blower needle is narrower than the diameter at the end connected to the shaft 22. The blower door further comprises a number of hinged surface elements 15. The surface elements define the circumference of the blower needle and when the blower needle 18 is in the extended position the diameter defined by the surface elements 15 is expanded compared to the diameter defined by the surface elements 15 when the blow needle is in the retracted position. In use, a blow blank is placed on the blow door in the retracted position. During the casting process, the inner diameter of the blow blank is expanded by extending the shaft 22, expanding the blow needle 18 and thus expanding the diameter defined by the surface elements 15.

Figures 2a and 2b illustrate this process. In Figure 2a, a blowing blank 50 is arranged on the surface of the elements 15 of the blowing door. The adjustment devices 20 hold the shaft 22 in a retracted position. A portion of the mold space 30 adapted to provide the shape of the finished blow molded container is also shown. The front part of the mold room has been removed for illustration reasons, as the blow blank would otherwise not be visible. The mold space comprises a contact area 32 adapted to rest against the outside of the blow blank at the entrance to the mold space after the blow molding process has been initiated. Figure 2b illustrates the situation after the blow molding process has been initiated. The partially reshaped blow blank 52 here achieved a larger inner diameter. In the lower part 54 in contact with the surface elements 15 of the blowing door, the inner diameter of the blowing object has been increased due to the increased diameter of the surface elements 15. This has brought the partially reshaped blow blank 52 into direct contact with the contact area 32. The upper part of the blow blank 56 above the contact area 32 has the diameter of the partially reshaped blow blank 52 increased due to gas blown into the interior of the blow blank through openings in the blow needle. After the contact in the contact area between the edge of the mold space and the outer surface of the blow blank part 54 expanded by the expansion of the diameter of the blow door has been established, no further expansion in the contact area is possible. The upper part of the blow blank 56 will continue to increase in diameter as gas is supplied through the blow needle until the blow blank part 56 rests against the surface 30 of the mold space.

A mold applicable to a blow molding process consists of at least two parts which can be joined to form the mold space and separated to remove the molded blank, after which the parts are joined again to recreate the mold space to cast a further blank and so on.

In the conventional process, the closing of the mold and connection of the mold parts is combined with clamping of the blow blank so that at least one connection line between two mold parts is arranged in direct contact with an opening in the mold space arranged to receive the blow needle and the blow blank. This structure is chosen to facilitate removal of the molded blank once the forming process has been completed. The two or more parts forming the mold can be removed and the molded part can then be lifted from the blow mold.

When the mold is closed around the blowing door and the blown blank placed on it, the blowing blank is clamped along at least part of the closing line between the two mold parts which are brought together in the area that encloses the blowing door. The material thickness of the blown blank is necessarily greater than the desired material thickness of the finished blow-molded blank. At the pinch line/shrink line, the blow molding will, to a limited extent, result in a reduction in material thickness, which results in an uneven thickness distribution over the blown workpiece with a shrink line of increased thickness but also possible areas of less thickness.

According to the present invention, the closing of the mold chamber, which normally consists of at least two elements that can be connected, does not result in clamping of the blow blank, as the at least one opening in the mold chamber adapted to receive the blower has a diameter that is larger than the blower in the retracted position and larger than the diameter to the blow piece to be reshaped. Before the blow molding begins, the mold space will include at least one connecting line but without any material clamped in it. Figures 3a and 3b respectively illustrate a cross-sectional view of the blower door in retracted (not extended) and extended state. The blow blank is not included in these illustrations. The figures illustrate how expanding the outer diameter of the blower 10 by extending the shaft 22 and the at least partially conical blower needle 18 connected thereto results in the surface elements 15 being brought into contact with or almost into contact with the contact area 32 of the mold space 30.

According to the present invention, the diameter of the blowing door and thus the diameter of the blow blank in direct contact is thus increased when the blow molding is started after the mold space has been closed. The diameter of the cylindrical blowing blank is increased uniformly over the circumference in the area in contact with the blowing door as the diameter defined by the surface elements is increased uniformly. The expanded blow blank is brought into contact with the mold space in the circular contact area 32 and clamping will consequently take place in this circular area.

Figure 3c is a top view sketch of the blower with the needle 18 and surface elements 15 in a retracted state and the closed mold space 30. The figure illustrates the circular contact area 32 and the contact line 35 where the at least two parts of the mold are brought into contact to form the mold space

In Figure 4, the partially inflated blow blank 52 is illustrated during the blow molding process. In Figure 4, the blowing needle 18 has expanded the surface elements 15 to a maximum thereby squeezing the blown blank 52 in the contact area 32. The blank 52 has not yet been completely blown up so that further blowing will take place to force the blown blank into full contact with the surface 30 of the mold space. The part of the blown blank which remains outside the mold space is marked 50. Figures 5a, 5b, 6a and 6b illustrate a second embodiment of the present invention where the equipment is adapted to produce a blown cylindrical object such as a liner for a pressure vessel comprising two openings, one at each end of this. A boss is intended to be attached to each end of the cylinder in connection with each of the openings and to increase and improve the process of attaching each boss to the liner the presence of scratch lines in the areas for mounting the bosses is preferably reduced. The embodiment illustrated in these figures is provided to achieve this goal. The configuration of the blower door and the blower needle at the lower end corresponds to the configurations of Figures 1a, 1b, 3a and 3b. The blower comprises a blower needle 118 with a partially conical shape surrounded by surface elements 115; a cylindrical blowing blank 150 is arranged on this. Contact area 132 is also shown in the figures. The embodiment further comprises an elongated shaft 119 arranged centrally and which extends from the blowing needle 118 to the top of the mold 130. The free end of the shaft 119 comprises other surface elements 116. Details of the device in the top section are indicated in Figure 5b. The other surface elements 116 are similarly arranged with a possibility of controlled increase of the cross-sectional diameter of the free end of the shaft. In Figures 5a and 5b, the other surface elements are in the retracted state. The blow blank 150 is in the shape of a cylinder arranged coaxially with the shaft 119 so that it extends over the entire length of the mold space 130. The other surface elements 116 are arranged in the top opening of the mold space so that when the other surface elements expand wildly the blow blank placed thereon is squeezed between the other surface elements and a second contact area 133 to the mold space. This is illustrated in Figure 6a. Figure 6a and the details thereof illustrated in Figure 6b show the situation after the cross-sectional diameter of the first and second surface elements has been increased and the blow molding has been initiated. One or more openings (not shown) are provided in the shaft

119 or the needle 118 to supply gas to the inside of the inflator 152 which causes it to be inflated. In a preferred embodiment of the present invention, the expansion of the first and second surface areas takes place simultaneously with the initiation of the blow molding. In the figure, the expansion is complete but the blow molding will continue until the expansion of the blow blank 152 is stopped by the surface of the mold space 130.

A person skilled in the art will appreciate that the present invention as defined by the accompanying patent claims can be utilized on a number of different mats without deviating from the inventive concept.

Claims (12)

1. Method for blow molding a container from a blow blank of a thermoplastic material comprising at least one opening, where the method comprises - placing the at least one opening of the blow blank on a blow mandrel - arranging a mold space that encloses the blow blank, - simultaneously blowing pressurized gas from the blower into the blow blank and expand the outer cross-sectional diameter of the blower. 2. Method according to claim 1, where the blow mold is clamped between a contact area of the mold space and the blow molder when the outer diameter of the mold blow molder is expanded. 3. Method according to claim 1 or 2, where the blow blank is cylindrical and comprises a first and a second opening which are internally connected, where the mold space comprises a first and a second opening and respectively first and second contact areas, where the blow molder comprises first and second surface areas and wherein the method comprises simultaneously expanding the outer cross-sectional diameter of the first and second surface areas, so that the blow blank is sandwiched between the first contact area and the first surface area and the second contact area and the second surface area. 4. Method according to claim 1, 2 or 3, where the container is a liner for a composite pressure vessel. 5. Blow molder comprising an outer surface arranged for engagement with an opening in a blow blank, wherein the blow molder comprises controllable and reversibly expandable means for expanding the outer cross-sectional diameter of the outer surface of the blow molder. 6. Blow molder according to claim 5, where the outer surface is cylindrical or conical with a circular cross-section before and after the expansion. 7. A blow molder according to claim 5 or 6, where the blow molder is arranged to receive the opening of a tubular blow blank. 8. A blow molding machine according to any one of claims 5-7, where the devices for expansion can be controllably expanded at the same time as gas is supplied to the interior of the blow mold from one or more gas supply openings in the blow molding machine. 9. A blow molder according to any one of claims 7 to 8, wherein the blow molder further comprises a shaft which separates the controllable and reversibly expandable means for expansion of the outer cross-sectional diameter of the outer surface of the blow molder in first and second means for expansion for simultaneous expansion of a tubular blow blank at a first and second end thereof. 10. A blow mold according to any one of claims 5 to 9, wherein the expansion of the cross-sectional diameter is between 25 and 150%, preferably between 50 and 100%. 11. Application of the method according to any one of claims 1-4 for obtaining a liner for a composite pressure vessel, where the liner does not comprise a scratch line in the area adjacent to the at least one opening. 12. Use of a blow molding machine according to any one of claims 5-8 for the production of a liner for a composite pressure vessel, where the liner does not comprise a crease line in the area adjacent to the at least one opening.