WO2003018413A1 - Container with a handle for receiving liquids - Google Patents

Abstract

The invention relates to a container for receiving liquids, which comprises an interior space delimited by side walls, a bottom and a pouring section. The container is also provided with a handle that is retained in the area of the pouring section with a handle base. The handle (61), in the area of the handle end (64) facing away from the handle base (62), has a retaining profile (65) that is received by a counter-profile (66) of the side walls (67). The counter-profile is formed by blow-molding in the area of the side walls, and the retaining profile is inserted in the already molded counter-profile.

Description

 CONTAINER WITH A HANDLE FOR RECEIVING LIQUIDS

The invention relates to a device for absorbing liquids, which has an interior delimited by a side wall, a floor and a mouth section and which is provided with a handle which is held with a handle asis in the region of the mouth section.

Such devices are typically manufactured by blow molding from pre-tempered preforms. The attachment of a handle facilitates manual handling and transport, particularly in the case of larger devices.

In the case of container molding by the action of blowing pressure, preforms are made of a thermoplastic material, for example preforms made of PET (Polyethylene terephthalate), fed to different processing stations within a blow module. Typically, such a blowing module has a heating device and a blowing device, in the area of which the pre-tempered preform is expanded into a container by biaxial orientation. The expansion takes place with the aid of compressed air which is introduced into the preform to be expanded. The procedural sequence for such an expansion of the preform is explained in DE-OS 43 40 291.

The preforms and the blown containers can be transported within the blowing module with the aid of different handling devices. For example, the use of transport mandrels onto which the preforms are attached is known. The moldings can also be handled with other support devices. The use of gripping tongs for handling preforms is described, for example, in FR-OS 27 20 679. An expanding mandrel that can be inserted into a mouth area of the preform for holding purposes is explained in WO 95 33 616.

The shaping of preforms into containers, which has already been explained, takes place, on the one hand, in the so-called two-stage process, in which the preforms are first produced in an injection molding process, then stored temporarily and only later conditioned in terms of their temperature and inflated to form a container. On the other hand, such a transformation takes place in the so-called One-step process in which the preforms are suitably tempered immediately after their injection molding manufacture and sufficient solidification and then inflated.

Common to all methods is that the preform has a significantly smaller shape than the container to be produced. Compressed air is therefore applied to the preform within the blowing station in order to convert it into the container to be produced. In this inflation process, in addition to reducing the wall thickness by increasing the surface area, the material is oriented. This means that the thin wall of the container has a very high dimensional stability, which makes the container suitable for a variety of uses.

Different methods are known for carrying out the blowing process. On the one hand, it is possible to use a uniform blowing pressure, which is introduced into the preform to be inflated and, after sufficient molding, is released from the finished container against an ambient pressure. It is also already known to first carry out a pre-expansion of the preform, which already approximates this relatively closely to the shape of the container to be produced, with a lower pressure, and only to express the finer contour of the container with a higher pressure. In this process, too, the blown air is vented against an ambient pressure after the container has been manufactured. The handles currently used for containers for holding liquids and in particular for blown bottles cannot yet meet all the requirements which are placed on both simple and inexpensive manufacture, simple handling when used by the end user and high load capacity at the same time.

The object of the present invention is to construct a device of the type mentioned in the introduction in such a way that a high level of functionality is achieved while at the same time being easy to manufacture.

This object is achieved in that the handle in the region of a handle end facing away from the handle base has a mounting profile which is received by a counter profile of the side wall, that the counter profile is formed by blow molding in the area of the side wall and that the mounting profile in the already formed counter profile can be introduced.

The combination of the handle base held in the area of the mouth section with the mounting profile accommodated in the area of the counter-profile provides a mounting of the handle that can withstand even greater loads. The possibility of introducing the mounting profile into the counter profile after a blow molding manufacture of the device makes it possible to relate both a previous production step of an injection molding manufacture of a preform and the subsequent production step of blow molding low effort and therefore inexpensive and with a high throughput rate per unit time.

For the reliable absorption of weight forces, it is proposed that the mounting profile be positively received by the counter profile in the direction of a longitudinal axis of the handle.

A typical realization is that the

Positive locking by changing the cross section of the

Handle and a corresponding contour of the counter profile is realized.

In particular, it is contemplated that the positive connection is realized by profiling a width of the handle transverse to the longitudinal axis of the handle.

To ensure a load-resistant fixation of the handle relative to the side wall, it is proposed that the handle be positively held in a radial direction by the counter profile.

A simple implementation possibility is that the positive connection is realized by a cross-sectional profile of the handle and an adapted contour profile of the counter profile.

Easy handling in a blow molding manufacture of the device from an injection molded preform is achieved in that the handle base is fixed by a mounting ring in the region of the mouth section. A transfer of forces between the handle and the mouth section is supported in that the mounting ring is fixed in a form-fitting manner in the region of the mouth section.

In particular, it is contemplated that the positive connection is realized by a profile similar to a bayonet lock.

A compact embodiment is provided in that the handle base is formed in one piece with the mouth section.

In particular, it is contemplated that the handle base is formed in the vicinity of a support ring.

To avoid disabilities in a blow molding manufacture of the device, it is proposed that the handle end be arranged pivotable relative to the handle base via a joint. Due to the pivotable arrangement, it is possible that the handle end can assume any positions relative to the handle base during the execution of the manufacturing process, thereby simplifying handling.

In terms of manufacturing technology, it proves particularly advantageous that the joint is designed as a film hinge.

A transfer of forces from the end of the handle to the handle base is supported in that the handle base extends in the area of its extension facing the joint Has boundary surface which is inclined to a preform longitudinal axis.

A further possibility for realizing a form fit between the mounting profile and the counter profile is that the end of the handle is designed like a hook in the region of its extension facing away from the base of the handle.

An aesthetic external appearance is supported by the fact that an outer surface of the handle end in the area of the mounting profile runs essentially flat with a surface of the side wall.

To enable a combination of different material properties, it is proposed that the handle be made of a different material than the side wall.

In particular, it is also contemplated that the material in the region of the handle base is encapsulated with the material of the mouth section.

Performing separate manufacturing steps in the injection molding manufacture of the preform is avoided in that the handle and the mouth section are produced in a common injection molding process.

A disadvantageously high heat absorption of a prefabricated handle in the injection molding of the rest of the preform is avoided in that the handle as an insert at least when carrying out the injection molding process is picked up in areas and at least temporarily by a cooling cassette.

In the drawings, embodiments of the invention are shown schematically. Show it:

1 is a schematic diagram of a top view of a device for container formation using the one-step process,

2 shows a basic illustration of a side view of a transfer device which is arranged between an injection molding module and a blowing module,

3 shows a side view of a blowing station in which preforms are inflated with their mouths pointing upwards into containers,

4 shows a longitudinal section through a blow mold in which a preform is stretched and expanded,

5 shows a side view of a container with a handle, in which a handle base is held over an annular element in the region of a mouth section of the container,

6 is an enlarged partial representation of a cross section along section line VI-VI in Fig. 5,

7 shows a further perspective partial illustration of the device according to FIG. 5, 8 is an illustration similar to FIG. 7 with a modified handle,

9 is a perspective side view of a preform with a handle which is injection molded in the area of a handle base in the vicinity of a support ring of the preform,

10 is a partial perspective view of a container made from the preform of FIG. 9.

11 shows a further perspective illustration of the preform according to FIG. 9,

FIG. 12 shows the preform according to FIG. 11 after pivoting one end of the handle facing away from the handle base around a film hinge and

13 shows a further perspective partial illustration of the device according to FIG. 10.

The device for absorbing liquids can be produced, for example, when the one-step process is implemented. The basic structure of such a single-stage device using an injection molding module (1) and a blowing module (2) is shown in Fig. 1.

The embodiment of a one-stage device for container forming shown in FIG. 1 has an injection molding module (1) and a blowing module (2), which are connected to one another by a transfer device (3) are. The injection molding module (1) is equipped with an extruder (4) and an injection mold (5), in the area of which a plurality of cavities (6) for the production of preforms (7), not shown in FIG. 1, are arranged.

The blow module (2) is provided with a plurality of holding elements (8) which can be transported along a closed circulation path (9). The holding elements (8) are fed to a blowing station (10), in the area of which the preforms (7) are deformed relative to one another into containers (11), not shown. A distance from the longitudinal axes (12) of the preforms (7) relative to one another is greater in the area of the blowing station (10) than in at least one other area of the circulation path (9).

In order to carry out the change in the distance between the longitudinal axes (12) of the preforms (7), a distance between the holding elements (8) is changed relative to one another. This change in distance can take place with the aid of a distance modifier (13) which, according to the embodiment in FIG. 1, is provided with a spiral-like profile (14). In the embodiment shown, the spiral-like profile (14) is designed as a groove in a shaft (15) which is connected to a drive (16) for specifying a rotational movement. The drive (16) can be coupled to the shaft (15) via a gear (17).

When using a shaft (15) with a groove-like profile (14), the holding elements (8) are advantageously provided with guide elements (18) which engage in the profile (14). The leadership elements (18) can be formed, for example, from laterally projecting bolts which carry cam rollers (19).

The combination of the injection molding module (1), the blowing module (2) and the transfer device (3) provides a so-called one-step device for blow molding containers (11), in which the preforms (7) from the injection molding module (1) to the blowing module (2) transferred at a temperature that is above the ambient temperature. It is therefore not necessary in the area of the blowing module to heat the preforms (7) from an ambient temperature to the blowing temperature, but in the area of a temperature control section (20) only needs a suitable temperature modification or

Temperature profiling takes place. For this purpose, the temperature control section (20) has heating devices (21) which can be equipped, for example, with infrared radiators. To improve the utilization of the applied heating energy, reflectors (22) are used. In the embodiment shown, the reflectors (22) have a reflector profile (23) which is adapted to the external design of the preforms (7). The reflectors (22) can be positioned transversely to the circulation path (9) in order to support the closest possible arrangement on the preforms (7).

The support elements (8) are transported along the circulation route (9) in cycles with successive standstill phases and transport phases. The function of the transfer device (3), the positioning of the reflectors (22) and the rotational movement of the distance modifier (13) are adapted to the respective movement cycle. Transporting the mounting elements (8) along the circulation path (9) can be done, for example, with the aid of a driven transport wheel (24) which has a profile (25) for acting on the holding elements (8) and is preferably arranged in the region of a deflection of the circulation path (9).

The cycle operation of the blow module (2) is controlled in such a way that a larger number of preforms (7) can be produced in the area of the injection molding module (1) than are subsequently simultaneously formed into containers (11) in the area of the blow module (2). For example, in the variant shown, the idea is to produce ten preforms (7) simultaneously in the area of the injection molding module (1) and to produce two containers (11) in the area of the blowing station (10) at the same time.

Another variant consists in producing five preforms (7) simultaneously in the area of the injection molding module (1) and simultaneously producing a container (11) in the area of the blowing station (10).

Fig. 2 illustrates in a side view the structure of the transfer device (3). In particular, it can also be seen that the injection mold (5) is formed from a cavity block (26) and from injection mold cores (27) which can be positioned relative to the cavity block (26) by a lifting device (28). After a sufficient thermal solidification of the preforms (7) within the injection mold (5), the preforms (7) are raised together with the injection molding cores (27) and a support element (29) of the transfer device (2) can be moved into the area of the injection molding module (1) retract. Then the preforms (7) in the transport recesses (30) of the Carrying element (29) used. If necessary, this is done after opening the muzzle forms

(31) and to facilitate stripping of the injection molding cores (27) with compressed air support or using suitable stripping or ejection devices.

The supporting element (29) is operated by an adjusting device

(32) worn, which is arranged displaceably along a guide (33). After the support element (29) has been displaced, the support element (29) is raised by the adjusting device (32), so that the preforms (7) can be acted upon by the mounting elements (8).

The mounting elements (8) are guided along the circulation path (9) by rails (34). In the area of the blowing station (10), a connecting piston (35) can be lowered, through which a pressurized medium for expanding the preforms (7) can be passed through the holding element (8) into the preforms (7).

To illustrate the manufacture of preforms (7) which are provided with a prefabricated handle (61) during the execution of the injection molding process, a handling device (83) is shown in FIG. 2 which is used to insert such prefabricated handles (61) into the injection mold (5) can be used.

Fig. 3 shows a side view of the blowing station (10). The blow station (10) is provided with mold carriers (36, 37), which each hold blow mold segments (38, 39). The mold carriers (36, 37) are together with the Blow mold segments (38, 39) adjustable transversely to the circulation path (9) in order to be able to perform opening and closing movements. In the embodiment shown, the mold carriers (36, 37) are positioned with the aid of pivoting levers (40) which are pivotably mounted in the region of a base plate (41). The pivot levers (40) have main bearings (42) for connection to the base plate (41). A connection to the mold carriers (36, 37) takes place via swivel joints (43), a connection to a positioning element (44) takes place via swivel joints (45).

The positioning element (44) is adjustable in the vertical direction along a guide (46). The adjustment can take place, for example, with the aid of a threaded rod (47) which is set in rotation by a drive (48). When the positioning element (44) is raised, the blowing station (10) is opened, and when the positioning element (44) is lowered, the blowing station closes.

From Fig. 3 it can also be seen that a lifting device (49) is used for positioning the connecting piston (35), which has a drive (50). The lifting device (49) has guide elements (51) for a transport carriage (52) which holds the connecting piston (35). The adjustment movement can be transmitted, for example, via a drive belt (53).

Fig. 4 shows schematically within the blowing station (10) in addition to the blown container (11) in dashed lines Preform (7) and a developing container bladder (54). The preform (7) or the container (11) can be held within the blowing station (10) by a threaded insert (55) and a stretching rod (56) is used to stretch the preform (7). The threaded insert (55) holds a mouth section (57) of the preform (7) and the stretching rod (56) exerts pressure on a bottom (58) of the preform (7) while the stretching process is being carried out during the feed movement. The blow mold (10) can be provided with a base insert (60) in order to enable a container bottom (59) to be shaped with contour undercuts.

Different plastics can be used as the thermoplastic material. For example, PET, PEN or PP can be used.

The preform (7) expands during the orientation process

Compressed air supply. The compressed air supply is divided into a pre-blowing phase, in which gas, for example compressed air, is supplied at a low pressure level and into a subsequent main blowing phase, in which gas is supplied at a higher pressure level. Compressed air with a pressure in the interval from 10 bar to 25 bar is typically used during the pre-blowing phase and compressed air with a pressure in the interval from 25 bar to 40 bar is fed in during the main blowing phase.

Fig. 5 shows a blown container (11) which is provided with a handle (61). The handle (61) has a handle base (62) which is held in the region of the mouth section (57) of the container (11). In the embodiment shown, the handle asis (62) is held by means of a holding ring (63) which surrounds the mouth section (57). In particular, it is contemplated to fit the retaining ring (63) in a form-fitting manner in the region of the mouth section (57). This can be done, for example, by screwing on an internal thread of the mounting ring

(63) on an external thread of the mouth section (57) or by profiling according to a bayonet lock.

In the area of a handle end (64) facing away from the handle base (62), the handle (61) has a mounting profile (65) which is formed by a counter profile

(66) of the container (11) is added. The counter profile (66) is in the area of a side wall

(67) of the container (11) arranged. In the illustrated embodiment, the handle end

(64) from a grip cap (68) and a grip bar (69) which is slimmer relative to the grip cap (68). This provides a positive connection between the mounting profile (65) and the counter profile (66) in the direction of a longitudinal handle direction (70) running from the handle end (64) to the handle base (62), which prevents the handle (61) from moving in the direction of the handle longitudinal axis ( 70) is pulled out of the counter profile (66). The handle (61) is thereby both in the area of

Bracket ring (63) and in the region of the handle end (64) positively connected to the container (11) so that a filled container (11) can be carried using the handle (61). Fig. 6 shows an enlarged cross-sectional view in the region of the holder of the handle bar (69) by the counter profile (66). In particular, it can be seen that the counter profile (66) widens in the direction of an interior (71) of the container (11) and that the handle web (69) also has a cross-sectional profile that widens in the direction of the interior (71). This also provides a positive connection in a radial direction of the container (11), which prevents the handle (61) from being unintentionally pulled out of the counter-profile (66) in a radial direction.

FIG. 7 illustrates the arrangement according to FIG. 5 in a perspective illustration. In particular, it can be seen that an outer surface (72) of the handle (61) runs essentially flat to a surface (73) of the side wall (67). In addition, it can be seen how the form fit between the handle end (64) and the side wall (67) is realized by the engagement of the mounting profile (65) in the counter profile (66).

Fig. 8 shows an embodiment with a modified design of the handle end (64). In this embodiment, there is a modified design of the mounting profile (65) and the counter profile (66). The modified design means that no change in cross section of the handle (61) can be seen from the outside. The profiling is rather realized in an area that is not visible from the outside. This design means that a very harmonious transition between the outer surface (72) of the handle (61) and the surface (73) of the side wall (67) is realized. Fig. 9 shows a preform (7) for producing a container (11). The handle (61) of the preform (7) has a design in the region of a handle end (64) that corresponds to that shown in FIG. 8 corresponds to the not recognizable design of the handle end (64). Compared to the embodiment in Fig. 8, however, the handle base (62) is held differently. From Fig. 9 it can be seen in particular that the preform (7) has a support ring (74) which is located in a region of the mouth section (57) which is arranged facing a neck (75) of the preform (7). The handle base (62) is preferably injection molded onto the support ring (74) or at least part of the mouth section (57) in the vicinity of the support ring (74). It is also possible to produce the handle base (62) together with the preform (7) in a common injection molding process.

The handle end (64) has a radial web (76) which is transferred into a hook web (77). The hook web (77) extends essentially parallel and at a distance from a main segment (78) of the handle end (64). Due to the contour of the main segment (78) of the radial web (76) and the hook web (77), the handle (61) is provided with a mounting profile (65), which has both a radial fixation and a fixation in a longitudinal direction of the blown container (11 ) enables.

Fig. 9 also illustrates that the handle base (62) is pivotally connected to the handle end (64) via a joint (79). In particular, the joint (79) is thought of as a film hinge form, which is injection molded in one piece with the handle base (62) and the handle end (64). Injection molding, temperature control for carrying out the blowing process and the actual blow molding are carried out with the spatial orientation of the handle (61) shown in FIG. 9. This avoids, in particular, complex and therefore expensive special handling devices.

FIG. 10 shows a container (11) which was produced from the preform (7) according to FIG. 9. After the container (11) had been blown, the handle end (64) was pivoted around the joint (79) so that the mounting profile (65) could be inserted into the counter profile (66). Due to the respective contour profiles, the handle end (64) is fixed in the area of the counter-profile (66), so that a load-bearing arrangement of the handle (61) is realized.

FIG. 11 illustrates another perspective illustration of the preform (7) according to FIG. 9. Here, in particular, the design of the handle (61) can be seen in the vicinity of the joint (79). A boundary surface (81) of the handle base (62) is inclined relative to a preform longitudinal axis (80). A boundary surface (82) of the handle end (64) facing the boundary surface (81) has an inclination corresponding to the boundary surface (81). The corresponding inclinations of the boundary surfaces (81, 82) mean that, in the pivoted position shown in FIG. 12, the handle end (64) is supported vertically over the boundary surface (82) in the region of the boundary surface (81) in a working position. hereby weight forces can be better absorbed via the film hinge.

FIG. 13 illustrates in a perspective view modified from FIG. 10 again the design of a container (11) which is produced from the preforms according to FIGS. 11 and 12. It can be seen in particular that the contour of the handle (61) is integrated very harmoniously into the contour of the rest of the container (11).

Claims

Patent claims 1. Device for receiving liquids, which has an inner space delimited by a side wall, a bottom and a mouth section and which is provided with a handle which is held with a handle base in the region of the mouth section, characterized in that the handle (61) in the area of a handle end (64) facing away from the handle base (62) has a mounting profile (65) which is received by a counter profile (66) of the side wall (67), that the counter profile (66) by blow molding in the area of the side wall (67) is formed and that the mounting profile (65) can be inserted into the already formed counter profile (66). 2. Apparatus according to claim 1, characterized in that the mounting profile (65) in the direction of a handle longitudinal axis (70) is positively received by the counter profile (66). 3. Apparatus according to claim 1 or 2, characterized in that the positive connection is realized by changing the cross section of the handle (61) and a corresponding contour of the counter profile (66). 4. Device according to one of claims 1 to 3, characterized in that the positive connection is realized by profiling a width of the handle (61) transverse to the longitudinal axis of the handle (70). 5. Device according to one of claims 1 to 4, characterized in that the handle (61) is positively held in a radial direction from the counter profile (66). 6. The device according to claim 5, characterized in that the positive connection is realized by a cross-sectional profile of the handle (61) and an adapted contour profile of the counter profile (66). 7. Device according to one of claims 1 to 6, characterized in that the handle base (62) is fixed by a mounting ring (63) in the region of the mouth section (57). 8. The device according to claim 7, characterized in that the mounting ring (63) is positively fixed in the region of the mouth section (57). 9. Apparatus according to claim 7 or 8, characterized in that the positive connection is realized by a profile similar to a bayonet lock. 10. Device according to one of claims 1 to 6, characterized in that the handle base (62) is integrally formed with the mouth portion (57). 11. The device according to claim (10), characterized in that the handle base (61) in an environment of a support ring (74) is integrally formed. 12. Device according to one of claims 1 to 11, characterized in that the handle end (64) via a joint (79) is arranged pivotably relative to the handle base (62). 13. The apparatus according to claim 12, characterized in that the joint (79) is designed as a film hinge. 14. The device according to one of claims 1 to 13, characterized in that the handle base (62) in the region of its joint (79) facing expansion has a boundary surface (81) which is inclined to a preform longitudinal axis (80). 15. The device according to one of claims 1 to 14, characterized in that the handle end (64) in Area of its extension facing away from the handle base (62) is designed like a hook. 16. The device according to one of claims 1 to 15, characterized in that an outer surface (72) of the handle end (64) in the region of the mounting profile (65) is substantially flat with a surface (73) of the side wall (67). 17. Device according to one of claims 1 to 16, characterized in that the handle (61) is made of a different material than the side wall (67). 18. The apparatus according to claim 17, characterized in that the handle (61) in the region of the handle asis (62) with the material of the mouth portion (57) is molded. 19. Device according to one of claims 1 to 18, characterized in that the handle (61) and the mouth portion (57) are made in a common injection molding process. 20. Device according to one of claims 1 to 19, characterized in that the handle (61) as an insert when carrying out the injection molding process is at least partially and at least temporarily received by a cooling cassette.