BLOW MOLDING TOOL AND METHOD FOR THERMALLY PROCESSING A SUBREGION OF A SURFACE OF A PLASTIC CONTAINER

Abstract

A blow molding tool (1) for a blow molding machine (1). The blow molding tool (1) comprises at least one first blow mold half (2) and one second blow mold half (3). The first blow mold half (2) has a baseplate (4) and a molding body (5). At least one mold cavity (6) with an inner wall (51) is arranged in the molding body (5). At least one region (511) of the inner wall (51) of the mold cavity (6) comprises, in the associated section of the molding body (5), separate temperature control channels (54) for controlling the temperature of the region (54).

Claims

1-21. (canceled)

22. A blow molding tool (1) for a blow molding machine (1), comprising at least one first blow mold half (2) and one second blow mold half (3), wherein the first blow mold half (2) comprises a baseplate (4) and a molding body (5), at least one mold cavity (6) with an inner wall (51) is arranged in the molding body (5), at least one region (511) of the inner wall (51) of the mold cavity (6) comprises, in its associated section of the molding body (5), separate temperature control channels (54) for controlling a temperature of the region (511).

23. The blow molding tool (1) according to claim 22, wherein the at least one region (511), with its associated section, is formed on a molding part (20) which is formed separately from the molding body (5).

24. The blow molding tool (1) according to claim 23, wherein the molding part (20) is made of aluminum or an alloy thereof.

25. The blow molding tool (1) according to claim 23, wherein an insulating element (16), made of a thermally insulating material, is arranged between the molding part (20) and the molding body (5).

26. The blow molding tool (1) according to claim 25, wherein the insulating element (16) consists of a thermosetting, high-temperature-resistant plastic with low thermal conductivity.

27. The blow molding tool (1) according to claim 22, wherein a distributor block (21), for supplying the temperature control channels (54), is arranged between the baseplate (4) and the molding body (5).

28. The blow molding tool (1) according to claim 27, wherein the distributor block (21) is made of aluminum or an alloy thereof.

29. The blow molding tool (1) according to claim 27, wherein the distributor block (21) has connections for supply and discharge of a heating/cooling medium to the temperature control channels (54).

30. The blow molding tool (1) according to claim 22, wherein the molding body (5) is formed in a plurality of parts and comprises a neck insert (18) and/or a bottom part (10).

31. The blow molding tool (1) according to claim 22, wherein the baseplate (4) is made of stainless steel.

32. The blow molding tool (1) according to claim 22, wherein the molding body (5) is made of aluminum or an alloy thereof.

33. The blow molding tool (1) according to claim 22, wherein the temperature control channels (54) are formed as a hole (541), and a concentrically arranged tube (542) is arranged within the hole (541) so that an annular gap forms as a temperature control channel (54) between the tube (541) and the hole (542).

34. The blow molding tool (1) according to claim 22, wherein a wall thickness between the temperature control channel (54) and the at least one region (511) is at least 0.059 inches (1.5 mm) and at most 0.472 inches (12 mm).

35. The blow molding tool (1) according to claim 22, wherein the at least one region (511) has a structured surface.

36. An extrusion blow-molding machine comprising a blow molding tool (1) according to claim 22.

37. A method for thermally processing a subregion of a surface of a plastic container with the blow molding tool (1) according to claim 22, comprising the steps of heating the at least one region (511) of the mold cavity (13) of the molding body (5) of the first blow mold half (2) of the blow molding tool (1) by supplying a heating medium through separate temperature control channels (54), introducing a preform into the mold cavity (6), closing the blow molding tool (1), shaping the plastic container by inflating the preform and abutting the preform against the inner wall of the mold cavity (6), cooling the at least one region (511) by supplying a cooling medium through the temperature control channels (54), and demolding the plastic container.

38. The method according to claim 37, wherein during the shaping of the plastic container, the at least one region (511) has a temperature which is higher than a temperature of the remaining inner wall of the mold cavity (6).

39. The method according to claim 37, wherein the at least one region (511) is cooled, during cooling, at an average cooling rate of at least 5 K/s.

40. The method according to claim 37, wherein the molding body (5) is also cooled during the cooling of the at least one region (511).

41. The method according to claim 37, wherein correspondingly temperature-controlled water is used as a heating medium and as a cooling medium.

42. The method according to claim 37, wherein the preform consists substantially of a polyolefin, the heating medium is supplied at a temperature of 248° F. to 392° F. (120° C. to 200° C.) and the cooling medium is supplied at a temperature of 41° F. to 104° F. (5 to 40° C.).

Description

[0077] An exemplary embodiment of a blow molding tool is explained in more detail below with reference to schematic figures. These show:

[0078] FIG. 1: a prior-art blow molding tool having two blow mold halves;

[0079] FIG. 2: a first blow mold half;

[0080] FIG. 3: a vertical sectional view through the blow mold half of FIG. 2.

[0081] FIG. 1 shows a blow molding tool 1 from the prior art for explaining the basic structure of such a tool. The blow molding tool, which as a whole is provided with reference sign 1, comprises a first blow mold half 2 and a second blow mold half 3. In the present case, said blow mold halves are laterally displaceable relative to one another in order to open and close the blow molding tool 1 periodically. Each blow mold half 2, 3 comprises a baseplate 4, which forms part of a closing unit of a blow molding machine. Mounted on the baseplate 4 is a molding body 5 in which one or more mold cavities 6 are formed. According to the exemplary embodiment shown, the molding body 5 has two mold cavities 6, each defining one half of the shape of a body of a plastic container. Since the mold cavities correspond to one another, for better clarity the two mold cavities are not provided with all reference signs, although the explanations apply in each case to both mold cavities.

[0082] A head plate 7 is provided with a cavity 8 for defining a neck section of the plastic container. In the case of a blow molding tool for an extrusion blow-molding machine, a neck blade 9 for separating an extruded plastic parison inserted into the blow molding tool 1 can also be provided on the head plate 7. A bottom part 10 closes the mold cavities 6 at the other end of the blow molding tool 1. On the mutually facing surfaces 11, 12 of the blow mold halves 2, 3, which define a separating plane of the blow molding tool 1, venting slots 13 can be formed. On one of the blow mold halves 3, guide pins 14 are formed, which slide into guide bushes 15 of the other blow mold half 2 when the blow mold halves 2, 3 are closed. The molding body 5 has a wall surface, i.e., an inner wall 51, which forms a part of the mold cavity 6.

[0083] FIG. 2 shows a first blow mold half 2 of a blow molding tool according to the invention. The blow mold half 2 has a baseplate 4. Arranged on the baseplate 4 is a distributor block 21 with two connections 211 and 212 for supplying a temperature control medium. A molding body 5 and a bottom part 10, which adjoins the molding body 5, are arranged on the base body 4. A head plate 7 is embedded in the molding body 5. The entirety consisting of molding body 5, bottom part 10 and head plate 7 provides a mold cavity 6. As part of the mold cavity 6, the molding body 5 has an inner wall 51. The inner wall 51 has two regions 511, wherein an associated section with separate temperature control channels 54 (see FIG. 3 in this respect) is assigned to each region 511. The temperature control channels 54 are connected to the connections 211 and 212 via the distributor block 21.

[0084] FIG. 3 shows a vertical sectional view through one of the regions 511 of FIG. 2. From this sectional view, it can be seen that the region 511 is formed as part of the inner wall 51. The region 511 has an associated section, on which a molding part 20 formed separately from the molding body 5 is formed. At its end facing the mold cavity 6, the molding part 20 is embedded in the molding body 5 and subsequently. in the direction of the baseplate 4, spaced apart from the molding body 5 with an insulating element 16. For better insulation, the insulating element 16 is additionally spaced apart from the molding body 5 by two O rings.

[0085] The temperature control channels 54 are formed within the molding part 20. To this end, a hole 541 is provided in the molding part 20 and a tube 542 opens into or penetrates through this hole 541 lengthwise so that an annular gap is formed between the tube 542 under the inner wall of the hole 541 through which the temperature control medium can be conducted into the vicinity of the region 511 or can be discharged therefrom. The tube 542 opens into a corresponding channel on the distributor block 521 and accordingly, the annular gap opens into a further channel on the distributor block 21. These channels open correspondingly into the connections 211 and 212 (see FIG. 2).

[0086] The cooling channel 54 has an extension at its end adjacent to the region 511 so that the cooling channel 54 forms a chamber. This chamber connects the ring gap and the tube so that a cooling circuit can be provided. The chamber is spaced from the mold cavity 6 with a wall thickness, which in the present case is 3 mm. This ensures that the heat that this wall thickness has, for example, after blow molding, can be dissipated quickly, or that the wall thickness can be rapidly heated with a suitable heating medium so that its temperature substantially corresponds to that of the preform that is introduced into the mold cavity 6 for blow molding.

[0087] In the method for producing a plastic container and for thermally treating a subregion of a plastic container, which is described across all figures, the region 511 of the mold cavity 6 of the molding body 5 of a first blow mold half 2 of the blow molding tool 1 is first heated by supplying a temperature control medium through separate temperature control channels 54. The preform is then introduced into the mold cavity 6. Subsequently, the blow molding tool 1 is closed and the plastic container is shaped by inflating the preform and by abutting the preform against the inner wall 51 of the mold cavity 6. After the shaping, the region is cooled by supplying a cooling medium through the temperature control channels 54 and the plastic container is demolded when a specific cooling temperature is reached.