Method for producing a syringe with an integrated closure element

The invention claimed is: 1. Injection moulding process for producing a syringe ( 100 ) with an integrated closure element ( 101 ) comprising the following process steps: a) providing an injection moulding tool ( 1 ) which comprises a first ( 2 ), a second ( 3 ) and a third tool portion ( 4 ), wherein the first tool portion ( 2 ) has a mould cavity ( 5 ) open at both sides and extending along an axial direction (X), and wherein the second tool portion ( 3 ) has a first injection moulding core ( 6 ) and the third tool portion ( 4 ) has a second injection moulding core ( 7 ); b) closing the injection moulding tool ( 1 ) such that the first tool portion ( 2 ) contacts the second ( 3 ) and third tool portion ( 4 ), and the first ( 6 ) and second injection moulding core ( 7 ) each enter the mould cavity ( 5 ) of the first tool portion ( 2 ) through an opening ( 5 a , 5 b ) and finally contact each other, as a result of which these tool portions ( 2 , 3 , 4 ) form a first cavity ( 8 ); c) injecting a first plastic material into the first cavity ( 8 ), as a result of which a hollow cylindrical syringe body ( 102 ) is formed with an end region ( 103 ) at its distal end ( 102 a ), wherein the end region ( 103 ) has an attachment element ( 105 ), provided with an inner thread ( 104 ), and a hollow cylindrical end piece ( 106 ) which is at least partially bordered by the attachment element ( 105 ); d) cooling the tool portions ( 2 , 3 , 4 ), as a result of which the syringe body ( 102 ) cools and hardens; e) bringing the first tool portion ( 2 ) into contact with a fourth tool portion provided with a mould cavity ( 9 ) closed at one end, as a result of which a second cavity ( 11 ) is formed at the distal end ( 102 a ) of the syringe body ( 102 ); f) injecting a second plastic material into the second cavity ( 11 ), as a result of which the closure element ( 101 ) is integrally formed on the attachment element ( 105 ), wherein the first and the second plastic material do not enter into a cohesive connection; wherein the first ( 6 ) and the second injection moulding core ( 7 ) extend along the axial direction (X), wherein the first injection moulding core ( 6 ) comprises a first cylindrical portion ( 12 ) with a first diameter ( 12 a ) and a second cylindrical portion ( 13 ) with a second, smaller diameter ( 13 a ), said first ( 12 ) and said second cylindrical portion ( 13 ) being adjacent in the axial direction (X), and wherein the second injection moulding core ( 7 ) has an additional mould cavity ( 14 ) open on one side in the axial direction (X) and a recess ( 15 ) on an inner wall ( 14 a ) bordering the additional mould cavity ( 14 ) in the axial direction (X); wherein, with the contacting of the two injection moulding cores ( 6 , 7 ) in process step b), the second cylindrical portion ( 13 ) of the first injection moulding core ( 6 ) is received in part in the recess ( 15 ) of the second injection moulding core ( 7 ); wherein, between process steps d) and e), the second cylindrical portion ( 13 ) is displaced in the axial direction (X) away from the third tool portion ( 4 ), wherein, in the following process step f), the second plastic material enters the channel ( 108 ) of the end piece ( 106 ), as a result of which a sealing of the channel ( 108 ) is created, wherein the first injection moulding core ( 6 ) is telescopically designed, wherein the second cylindrical portion ( 13 ) of the first injection moulding core ( 6 ) is displaced relative to the first portion ( 12 ) during process steps b) to d), wherein the second cylindrical portion ( 13 ) in process steps b) to d) is in a maximum axial position ( 21 ) such that the second cylindrical portion ( 13 ) contacts the second injection moulding core ( 7 ). 2. Method according to claim 1 , characterised in that the end region ( 103 ) has an attachment element ( 105 ) provided with an inner thread ( 104 ) and at least one recess ( 112 ). 3. Method according to claim 2 , characterised in that by injecting the second plastic material into the second cavity ( 11 ), the closure element ( 101 ) is integrally formed on the attachment element ( 105 ), as a result of which a protrusion ( 111 ) is formed in the at least one recess ( 112 ). 4. Method according to claim 1 , characterised in that in process step b), an inner wall ( 5 c ) of the mould cavity ( 5 ) of the first tool portion ( 2 ) and an outer wall ( 12 b ) of the first cylindrical portion ( 12 ) of the first injection moulding core ( 6 ) form a first portion ( 8 a ) of the first cavity ( 8 ), by means of which the hollow cylindrical syringe body ( 102 ) is formed, wherein a third cavity ( 16 ) is formed by the additional mould cavity ( 14 ) of the second injection moulding core of ( 7 ) and the second cylindrical portion ( 13 ) of the first injection moulding core ( 6 ), by means of which the end piece ( 106 ) is formed, wherein the attachment element ( 105 ) provided with the inner thread ( 104 ) is formed by means of a fourth cavity ( 17 ), which is formed by an outer region ( 7 a ) of the second injection moulding core ( 7 ) and the inner wall ( 5 c ) of the mould cavity ( 5 ) of the first tool portion ( 2 ). 5. Method according to claim 1 , characterised in that between process steps d) and e), the second injection moulding core ( 7 ) is demoulded from the attachment element ( 105 ) of the syringe body ( 102 ) and the third tool portion ( 4 ) is removed from the first tool portion ( 2 ), wherein the second injection moulding core ( 7 ) is demoulded by a rotational movement of the inner thread ( 104 ) of the attachment element ( 105 ). 6. Method according to claim 1 , characterised in that the first plastic material is injected through a first injection nozzle ( 18 ) arranged in the second tool portion ( 3 ), and the second plastic material is injected through a second injection nozzle ( 19 ) arranged in the fourth tool portion ( 9 ). 7. Method according to claim 6 , characterised in that the mould cavity ( 5 ) of the first tool portion ( 2 ) has a first opening ( 5 a ) into which the first injection mould core ( 6 ) enters in process step b), wherein the second tool portion ( 3 ) has a recess ( 20 ) that is open to the first cavity ( 8 ) and by means of which a finger rest ( 107 ) is formed at the proximal end ( 102 b ) of the syringe body ( 102 ), wherein the first injection nozzle ( 18 ) is connected to this recess ( 20 ). 8. Method according to claim 1 , characterised in that the first ( 2 ), second ( 3 ), third ( 4 ) and fourth tool portions ( 9 ) are individually heated and cooled, wherein the heating takes place by means of a laser and the cooling by means of a coolant, wherein the coolant contains water and/or nitrogen and/or CO 2 . 9. Method according to claim 1 , characterised in that the first and the second plastic material are different materials, wherein the first plastic material is a polymer plastic material, wherein the first plastic material is a polyolefin, wherein the first plastic material is a cyclic olefin polymer (COP) or a cyclic olefin copolymer (COC), and the second plastic material is a thermoplastic elastomer. 10. Method according to claim 1 , characterised in that the first and the second plastic material are the same materials, wherein these plastic materials are a polymer plastic material. 11. Method according to claim 2 , characterised in that the at least one recess ( 112 ) is surrounded by an outer ( 112 a ) and an inner ( 112 b ) wall portion, wherein the outer wall portion ( 112 a ) forms a part of the outer surface ( 105 a ) of the attachment element ( 105 ). 12. Method according