WO2018041912A1

WO2018041912A1 - Method for producing a shell-like plastics moulding, shell-like plastics moulding, and container made of thermoplastic

Info

Publication number: WO2018041912A1
Application number: PCT/EP2017/071801
Authority: WO
Inventors: Hartmut Wolf
Original assignee: Kautex Textron Gmbh & Co. Kg
Priority date: 2016-08-31
Filing date: 2017-08-30
Publication date: 2018-03-08
Also published as: DE102016216447B4; DE102016216447A1

Abstract

The invention relates to a method for producing a shell-like plastics moulding (1) made of thermoplastic, having at least one wall and at least one fluid channel (5) extending in a meandering manner in the wall, said fluid channel (5) being formed integrally in the wall. The method comprises the forming of the integral fluid channel (5) by means of a fluid injection technique. The invention also relates to a shell-like plastics moulding (1) which has been obtained by the method and to a container made of shell-like plastics mouldings (1) made of thermoplastic for storing an aqeuous additive or an aqueous liquid, which comprises a container wall with a fluid channel (5), extending in a meandering manner in the container wall, with a feed port (6) and a return port (7).

Description

Process for producing a cup-shaped plastic molded part, cup-shaped plastic molded part and container made of thermoplastic material

The invention relates to a method for producing a cup-shaped plastic molded part made of thermoplastic material by injection molding using fluid injection technique.

The invention further relates to a cup-shaped art ^¬ resin molded of thermoplastic material having at least one wall which is designed as a heating wall for limiting a liquid ^¬ keitsvolumens, wherein the wall has at least one meander over the heating wall extending fluid channel for guiding a heat transfer medium.

Finally, the invention relates to a container made of cup-shaped plastic moldings, in particular a container comprising at least one cup-shaped plastic molded part of the type described above, for storing an aqueous additive or an aqueous liquid ^containing a first volume for storing the liquid and a second one Having heat transfer medium through-flow volume, which is separated from the first volume, wherein the second volume is formed as extending on a container wall meandering extending fluid channel with a flow connection and a return port for the heat transfer medium. A generic container is known for example from DE 10 2012 020 040 B4. This publication relates to a device for storing and conveying an aqueous additive, in particular for the catalytic exhaust gas nitification of a motor vehicle, comprising a reservoir, the

Reservoir volume encloses, at least one feed pump for the additive and means for heating at least parts of the storage volume or a separate Abschmelzvolumens, the reservoir is at least partially doppelwandig ^¬ det, and wherein a durchströmba ^¬ with the heat transfer medium volume of the reservoir comprises a plurality of channels, which can optionally be flowed through individually or together with the heat transfer medium and define different heating zones in the bottom and / or in the wall of the storage container.

The preparation of a double-walled reservoir is relatively expensive. In DE 10 2012 020 040 B4, it is proposed for the production of such a double-walled storage container to place a plurality of container trays or entire containers into one another with the interposition of spacers.

The heat transfer from the heat transfer medium to the area enclosed by the reservoir volume is quite in need of improvement, as the heat transfer medium initially has to heat the pre ^¬ Board medium directly limiting container wall.

Another liquid container for motor vehicles is known for example from EP 1 473 447 AI. This publication relates to a liquid container for

Motor vehicles, particularly for an aqueous Harnstofflö ^¬ solution, in which a heater for the urea solution is integrated in the container wall, and such that in the

Container interior, in which the liquid is located, no heating parts protrude. The heater consists of heating ^¬ pipes, which are connected to a cooling circuit of the internal combustion engine. As an alternative to the heating pipes through which the heat transfer medium of the cooling circuit flows, the publication proposes the use of an electric heater. The heater should preferably be installed so that no parts of the heating and of the heating tubes protruding into the Behäl ^¬ terinnenraum. By such an embodiment of the heating, the heat transfer from the heat transfer medium to the liquid present in the storage container or to ice there is not optimal. The invention is therefore based on the object to provide a method for producing a cup-shaped plastic molded part with an integrated heating wall that is relatively simple. The invention further has for its object to provide a cup-shaped plastics molding for the manufacture lung of a container and a container made of shell-like plastic molded parts, which are suitable for storage and heating of an aqueous additive using a liquid heat transfer medium, wherein the plastic ^¬ plastic part and the container preferably are formed so that an optimal heat transfer is ensured by the heat transfer medium to the stored liquid.

The object is firstly achieved by a method having the features of claim 1. According to the invention further comprises a cup-shaped plastic molded part having the features of at ^¬ entitlement 7 provided. Finally, the object is achieved by a container of cup-shaped plastic moldings with the features of claim 11. Advantageous embodiments of the invention are covered by the respective subclaims.

One aspect of the invention relates to a method for producing a cup-shaped plastic molded part from ei ^¬ nem thermoplastic material by injection molding using fluid Inj ektionstechnik with at least one wall and at least one meandering in or on the wall meandering fluid channel, the one piece is formed with the wall, the method comprising the method steps ^¬ comprising:

Providing an injection molding device with a tool having an article cavity which defines the outer contour of the plastic molded part, wherein at least one meandering first groove channel is provided in a wall of the article cavity,

Filling the article cavity with a plasticized molding compound of thermoplastic material,

Injecting a fluid into the article cavity filled by the groove channel with displacement of a liquid core of the molding material into at least a first overflow cavity of the tool, so that an integrated fluid channel is formed in the plastic molded ^¬ part, and

- Mold removal of the plastic molding. The fluid inj ekti ^¬ onstechnik is basically known for the production of injection molded tubes made of thermoplastic material.

Injection molding using fluid injection technology as such is mainly for the production of pipes known to extend in a straight line. The fluid inj ektions ^¬ technique comprises injecting a jet of water under high pressure into a column filled with plasticized plastic article cavity of an injection mold, wherein a liquid core of the thermoplastic material is displaced by means of water in an overflow cavity or secondary cavity, which according to the polymer fill Slider is released.

The invention relates to a method for producing a cup-shaped plastic molding with a meandering in the wall of the plastic molding extending fluid idkanal, which is integrally formed with the wall or is integrally formed on the wall, wherein for the preparation of the Fluidka- nals According to the invention, the fluid injection technique is used.

For injection molding, at least one extrusion device for plasticizing thermoplastic material and a tool having an article cavity which predetermines the outer shape of the cup-shaped plastic molded part are used.

In the method according to the invention, the article cavity is expediently first filled in a single closure with a corresponding amount of thermoplastic and plasticized molding compound. By means of an injection device, a fluid is then injected under high pressure into the filled article cavity, displacing a liquid core of the molding compound into at least one overflow cavity of the tool. The length of the groove channel and the amount of displaced ^¬ th molding compound are chosen so that this process is completed before the complete crystallization of the plasticized molding material.

In this way, an integrated fluid channel can be formed, which is integrally formed in a wall of the cup-shaped plastic molded part or molded onto it. In the wall of the article cavity, a meandering groove channel is preferably provided, which defines the contour of a meandering rib or a meandering bead. Meandering in the sense of the present application means as much as looped or serpentine running. The groove channel can extend over parts of the cup-shaped plastic molded part. As the thermoplastic molding composition according to the invention may be any depending on the thermoplastic polymer ^¬ provided in ^¬ play can be used as a thermoplastic molding composition

thermoplastic material can be provided which is selected from a group comprising polyethylene, high density Po ^¬ lyamid, polyamide 6, polyamide 12, polyurethane, polycarbonate, acrylonitrile-butadiene-styrene copolymer, polyketones, poly ^¬ styrene, polypropylene, thermoplastic elastomers based on Olefinic base, crosslinked olefin-based thermoplastic elastomers, urethane-based thermoplastic elastomers, thermoplastic polyester elastomers, and thermoplastic copolymers.

The aforementioned process steps are preferably carried out in the order of their enumeration. In a variant of the method according to the invention, it is provided that a subset of the molding compound is displaced into a second overflow cavity. This basically carries the

Recognizing that the formation of a relatively long meandering fluid channel could possibly take a time that would be greater than the crystallization ^¬ time of the plasticized molding composition. If an overflow cavity is already provided on a section of the groove channel, overall the displaceable volume flow of plasticized molding compound can be increased, so that the injection time for the fluid can be shortened. For example, a first subset of the form ^¬ mass can be displaced into the first overflow cavity first, followed by a second subset of the molding material can be displaced into the second overflow cavity. The first overflow cavity may, for example, be connected to the groove channel after a first partial length of the groove channel. A displacement of the liquid soul of the molding compound then takes place in the first overflow cavity until it is completely filled. The displaced material is then displaced into the second overflow cavity expediently provided at the end of the groove channel. The volume of the first overflow cavity is dimensioned such that it absorbs only the first subset of the molding compound. A slide valve or a valve for closing the first overflow cavity is not required in this variant.

The first overflow cavity may alternatively be closed after receiving a partial filling, preferably half the filling by means of a valve.

In another variant of the method according to the invention, it is additionally or alternatively provided that in the wall of the article cavity a first and a second groove channel or a first and a second groove channel section are provided in which a fluid is injected at the same time, so that two sections of an integrated fluid channel be formed. The sections formed in this way can be connected to one another, for example, after solidification of the thermoplastic molding compound, preferably using a prefabricated conductor bridge, which is connected to the sections of the so-called

welded fluid channel are welded.

It is preferably provided that a flow connection and a return connection for the fluid channel are made in one piece with the damage. lenförmige plastic molding are molded. The An ^¬ conclusions can be formed, for example in the form of connecting nipples with a profile for choking a connection line.

Preferably, the fluid used is water. In the context of the invention, however, the use of a gaseous injection medium is useful and possible. Another aspect of the invention relates to a cup-shaped plastic molded part made of thermoplastic material with at least one wall, which is designed as a heating wall for limiting ei ^¬ nes liquid volume, wherein the wall we ^¬ least one meandering over the heating wall

extending fluid channel for guiding a heat transfer medium, the fluid channel has a flow connection and a return port and the fluid channel is integrally formed in the wall of the plastic molded part and is formed on this ^¬ .

Preferably, the cup-shaped plastic molding was obtained using the method described above. The fluid channel of the cup-shaped plastic molding according to the invention is formed from the thermoplastic material of the wall, d h. integrally formed or integrally formed or integral in the context of the present invention excludes the application of separate components in the form of pipes, heating coils or heating coils or heating wires. In a preferred variant of the plastic molding according to the invention it is provided that the fluid passage extends in a direction extending on the wall of the plastic molded part forth ^¬ projecting bead. In this manner is open ^¬ ensured that the fluid channel is at least partially flows around the liquid volume to be limited, so that a optimum heat transfer is ensured by the circulating through the fluid channel heat transfer medium to the stored and to be heated liquid. In a preferred variant of the cup-shaped plastic molded part according to the invention, it is provided that the bead is connected to the wall of the plastic molded part by means of at least one web forming a material bridge. In this way, a most extensive enclosure of the fluid channel can be accomplished with the liquid to be stored. Thanks to the bridge, the bead protrudes relatively far into the volume to be stored.

In order to prevent the bead impedes distribution of the liquid to before rate in the container, vorgese ^¬ hen may be that the web has window-like openings. Alternatively, the bead can be provided by means of several material bridges or webs with the wall of the molded part to bind ^¬ ver.

A variant of the invention relates to a container of scha ^¬ lenförmigen plastic molded parts made of thermoplastic material for storing an aqueous additive or an aqueous liquid having a first volume for storing the liquid and a second volume of a heat transfer medium through which volume is separated from the first volume wherein the second volume forms excluded at a be ^¬ container wall extending meandered fluid channel having a flow connection and a return connection as is, wherein the container is characterized in that the fluid passage an integral part of the container wall and is integrally formed on the container wall or in the Container wall is ^{¬ formed} . The container according to the invention may for example be formed as Addi ^¬ tivbehälter for holding a urea solution for selective catalytic oxide from waste gases. Such an additive container is intended for fixed installation in a motor vehicle. At least one container wall of the container is designed as a heating wall for limiting the volume of liquid, wherein preferably the heating wall extending in the meander-shaped fluid channel having a flow connection and a return flow connection ^¬ to the heat carrier circuit of the

Internal combustion engine is connected. For example, a container wall forming the bottom of the container may be formed with a meandering fluid channel. Additionally or alternatively, the side walls of the container may be formed entspre ^¬ accordingly. The container is expediently composed of exactly two shell-shaped plastic molded parts, wherein a lower shell-shaped plastic molded part is formed with a meandering fluid channel extending in a container wall forming the bottom of the container. An upper part of the container may for example be formed from a conventional cup-shaped plastic molded part.

The shell-shaped plastic molded parts are expediently injection-molded from thermoplastic material, using the previously described fluid injection technique or water injection technique. As a fluid can of course also find a gas application. The fluid channel according to the invention can also be made using the so-called projectile injection technique.

Preferably, the fluid channel extends on a side facing the ers ^¬ th volume of the container wall, wherein the Flu ^¬ idkanal runs in a bead-shaped profile on the container wall. In this way, it is possible that the fluid channel over parts of its circumference of the vorratsenden Liquid is flowed around, so that the heat transfer to the liquid is optimal.

Preferably, the container according to the invention comprises at least one of the cup-shaped plastic moldings of the type described above, which was preferably obtained by the method according to the invention.

The invention will be explained below with reference to an embodiment shown in the drawings.

Show it:

1 shows a perspective view of a cup-shaped plastic molded part according to the invention,

2 shows a further perspective view of the cups ^¬ shaped plastic molding according to Figure 1,

3 shows a cross section through the cup-shaped art ^¬ resin molded product according to the invention,

Figure 4 is an enlarged fragmentary section through a fluid passage of the cup-shaped plastic molding according to the invention It ^¬,

FIG. 5 shows a schematic cross-sectional view through parts of the filled article cavity,

6 is a sectional view through a connection of the fluid channel as a flow connection or return connection for a heat transfer medium, 7 shows a cross-section through a cup-shaped art ^¬ plastic part according to a second embodiment of the invention,

8 is a plan view of the scha ^¬ lenförmige plastic molded part shown in Figure 7,

Figure 9 is a view of the cup-shaped plastic molding according to the invention, illustrating the connections for water injection and the overflow cavities and

Figure 10 is a of Figure 9 corresponding view illustrating What ^¬ serinjektion into first and second Nutkanalabschnitte the article cavity.

Figure 1 shows a cup-shaped plastic molded part 1 according to the invention, which forms the lower shell of a not ^{dargestell ¬} th container for storing an aqueous additive in a motor vehicle. The container can be provided, for example, as a urea container for selective catalytic exhaust gas removal on these motor vehicles.

The cup-shaped plastics molding 1 is formed as spritzgegos ^¬ sene half-shell made of thermoplastic material, example ^¬, of HDPE. The bowl-shaped

Plastic molding 1 comprises side walls 2 and a umlau ^¬ fenden mounting flange 3 for joining with another cup-shaped plastic molded part to a closed container which encloses a storage volume for the additive.

A bottom wall 4 of the cup-shaped plastic molded part 1 is designed as a heating wall with an integrated fluid channel 5. The fluid channel 5 extends from a flow connection 6 to a return connection 7, via which the fluid channel 5 abuts a heat transfer circuit of an internal combustion engine is subsequently ^¬ bar. The fluid channel 5 extends in the manner of a heating ^coil serpentine on the bottom wall of the

cup-shaped plastic molded part 1, wherein the fluid channel 5 projecting bead-shaped in the limited volume of the cup-shaped plastic molded part 1.

The cup-shaped plastic molded part 1 according to Figures 1 and 2 was obtained by injection molding of thermoplastic material, preferably by injection molding of HDPE using the so-called fluid Inj ektionstechnik. FIGS. 1 and 2 show the position of a sprue 8 and an inlet 9 and an outlet 10 for the injection of water. With 11 an overflow cavity is shown schematically in the injection molding tool.

The cup-shaped plastic molded part 1 is made for example from a shot, ie with a filling of not ^{dargestell ¬} th tool. For example, Lupolen GX 5038 can be used as HDPE. This is a trade name.

A schematic sectional view of a filled with a thermoplastic resin molding material ^¬ injection mold in the region of an article cavity 12 of the injection mold is shown in FIG. 5 In the article cavity 12 bounding wall 13, a groove channel 14 is formed, which determines the outer contour of the fluid channel 5. The inlet 9 for the injection of water opens at one end of the groove channel 14 in the article cavity 12, the outlet 10 is closed at the other end of the groove channel 14 in the article cavity 12 ^¬ . After filling the article cavity 12 with the plasticized molding compound, water is injected at a pressure of .gtoreq. By means of an injection device of the injection molding tool about 200 megapascals (MPa) pressed into the groove channel 14. Within the groove channel 14, the water displaces a liquid core of the molding compound into the overflow cavity 11, which in a variant of the method according to the invention is dimensioned such that it can absorb the entire displaced molding compound. Since ^¬ at arises a training of the fluid channel 5, as shown for example in FIG. 4 The fluid channel 5 forms a bulge 15 projecting toward one side of the shell-shaped plastic molded part 1. This side of the shell-shaped plastic molded part 1 forms the side facing the storage volume of the container to be produced, as can also be seen from the sectional view in FIG.

In the injection molding tool, in the process according to the invention, in the region of the inlet 9 and in the region of the outlet 10 of the hot channel (fluid channel 5), connection nipples 16 are formed which form a flow connection and a return connection of the fluid channel 5. The shape of the connection ^¬ nipple 16 is shown in the sectional view shown in FIG. 6

Reference is now made to FIGS. 9 and 10, which respectively schematically illustrate the course of the groove channel 14 in the article cavity 12 and the position of the inlet 9 and a first and second overflow cavity IIa, IIb.

Different from the explained with reference to Figure 1 ^¬ process variant is, in another process variant, the OF INVENTION ^¬ dung, which will be explained with reference to FIG 9, a first and a second overflow cavity IIa, IIb provided, wherein the first

Overflow cavity IIa on half the flow path length of the groove channel 14 opens into the groove channel 14 and the second overflow cavity IIb is connected to the end of the groove channel 14. In this process variant, a partial amount of the plasticized molding compound is first displaced into the first overflow cavity IIa. As soon as the water injected under high pressure has covered half the flow path within the groove channel 14, the further molding compound, ie a second subset of the molding compound, is displaced into the second overflow cavity IIb until the fluid channel 5 is completely formed. This makes it possible to displace a hö ^¬ heren volume flow of plasticized molding material out of the groove channel 14, so that for example a

Flow path length of the fluid channel 5 of more than 1.9 m can be achieved. The achievable flow path length depends on the crystallization time of the polymer melt. As long as the polymer melt (plasticized molding compound) is not yet crystalline, plastic molding compound can be displaced via the water injection.

Another method is illustrated by means of FIG. 10. In this variant of the tool, it is provided that the groove channel 14 is subdivided into a first and a second groove channel section 14a, 14b. The first and second Nutkanalabschnitt 14a, 14b will strike parallel beauf ^¬ with water. As in the previously described embodiment of the method, the tool comprises a first overflow cavity IIa and a second overflow cavity IIb. To the first Nutka ^¬ nalabschnitt 14a, a first inlet 9a is connected to the second Nutkanalabschnitt 14b a second inlet 9b is connected. Water under high injection pressure of, as already mentioned about 200 MPa, is the first inlet 9a and the second inlet 9b parallel, ie at the same time abandoned, so that two fluid channel sections are formed in parallel, whereby also the flow path length of the fluid channel 5 significantly ^¬ Lich extended becomes. The two sections of the fluid channel 5 are connected by means of a connecting bridge 17 to a single fluid channel 5.

FIGS. 7 and 8 show a variant of the embodiment of the shell-shaped plastic molded part 1 according to the invention, wherein the fluid channel 5 is formed by webs 18, the material bridges form, is connected to a wall of the cup-shaped plastic molded part 1. In this way, it is ensured that the meandering bead 15, which encloses the fluid channel 5, protrudes relatively far from the bottom wall 4 of the cup-shaped plastic molded part 1 and thus immerses ver ^¬ relatively deep in the stored and to be heated liquid ^¬ sigkeit ,

Thus, the bead 15 forming an obstacle to the reservoired liquid in the formed of the shell-shaped synthetic ^¬ plastic molded parts 1 tank, a plurality of lands 18 is provided, as is schematically illustrated in FIG. 8 Instead of a plurality of webs 18 and window-like openings can be provided in a continuous web.

In the variant shown in Figure 7, the webs 18 and the turf 15 are formed symmetrically, they may also be formed asymymetric ^¬ to allow better demoldability of the cup-shaped plastic molded part 1 from the injection mold.

LIST OF REFERENCE NUMBERS

1 cup-shaped plastic molding

2 side walls

3 mounting flange

4 bottom wall

5 fluid channel

6 flow connection

7 return connection

8 sprue

9 enema

9a first enema

9b second enema

10 spout

10a first outlet

10b second outlet

11 overflow battery

IIa first overflow cavern

IIb second overflow cavity

12 article catalog

13 wall of the tool

14 groove channel

14a first groove channel section

14b second groove channel section

15 bead

16 connection nipples

17 connecting bridge

18 bars

Claims

claims

1. A process for producing a cup-shaped plastic molded part (1) made of thermoplastic material by injection molding using fluid Inj ektionstechnik with

at least one wall and at least one in or on the wall meandering extending fluid channel (5), which is integral with the wall, the method fol ^¬ constricting process steps:

Providing an injection molding device with a tool having an article cavity (12) which defines the outer contour of the plastic molded part (1), wherein at least one meandering first groove channel (14) is provided in a wall of the article cavity (12),

Filling the article cavity (12) with a plasticized molding compound of thermoplastic material,

Out injecting a fluid into the filled article cavity (12) through the groove channel (14) with displacement of a liquid core of the molding material into at least a first overflow cavity (IIa) of the tool, so that in the art ^¬ plastic part (1), an integrated fluid channel (5) ^¬ is formed, and

- Mold removal of the plastic molding (1).

2. Method nor claim 1, characterized in that a subset of the molding material in a second overflow cavity (IIb) is displaced.

3. The method according to claim 2, characterized in that first a first subset of the molding material in the first overflow cavity (IIa) is displaced and that thereafter a second subset of the molding material in the second overflow cavity (IIb) is displaced.

4. The method according to any one of claims 1 to 3, characterized in that in the wall of the article cavity (12) a first and a second groove channel portion (14a, 14b) are provided, in which a fluid is injected at the same time, such that two sections of an integrated fluid channel (5) are formed ^¬ who.

5. The method according to claim 4, characterized in that the two sections of the integrated fluid channel (5) after a

Solidification of the thermoplastic molding compound are joined together, preferably using a prefabricated connecting bridge (17).

6. The method according to any one of claims 1 to 4, characterized in that water is used as the fluid.

7. cup-shaped plastic molded part (1) of thermoplasti ^¬ sch plastic with at least one wall, which is designed as a heating wall for limiting a liquid volume, where ^¬ at the wall at least one meandering over the heating wall extending fluid channel (5) for guiding a heat ^¬ carrier medium , the fluid channel (5) has a flow connection (6) and a return connection (7) for the

Having heat transfer medium and the fluid channel (5) integrally molded into the wall of the plastic molded part (1) or is formed on this.

8. cup-shaped plastic molding (1) according to claim 7, characterized in that the fluid channel (5) in a on the wall of the plastic molded part (1) extending forth ^¬ standing bead (15) extends.

9. cup-shaped plastic molded part (1) according to claim 8, characterized in that the bead (15) by means of at least one material bridge forming a web (18) is connected to the wall of the plastic molded part.

10. cup-shaped plastic molding according to claim 9, characterized in that the web (18) window-like

Has breakthroughs.

11. Container made of shell-shaped plastic molded parts (1) made of thermoplastic material for storing an aqueous additive or an aqueous liquid having a first volume for storing the liquid and a second volume which can be flowed through by a heat transfer medium, which volume is separated from the first volume second volume as extending on a container wall meander-shaped extending fluid channel (5) with a flow connection (6) and a return port (6), characterized marked ^¬ characterized in that the fluid channel (5) is an integral part of the container wall and in one piece to the container wall molded or molded.

12. A container according to claim 11, characterized in that the fluid channel (5) extends on a side facing the first volume side of the container wall and that the fluid channel (5) in a bead-shaped profile on the container wall ver ^¬ runs.

13. Container according to one of claims 11 or 12 with at least one cup-shaped plastic molded part (1) having the features of one of claims 7 to 10.