DE112010003508T5 - Multicolour vehicle lens with mutually connected TIR reflection prisms - Google Patents

Abstract

A multicolor vehicle lens with interconnected TIR reflective prisms is molded using a first molten material to make a substrate and a second material to form clusters of TIR prisms connected by connector elements. The TIR prisms and the connector elements are molded simultaneously using the mold cavities for the connector elements as flow paths to the mold cavities formed to form the TIR reflector prisms.

Description

Background of the invention

Field of the invention

The invention relates to a method for injection molding, an injection molding apparatus and an injection-molded product. More particularly, the invention relates to a method and apparatus for casting vehicle lenses formed using two or more different materials and including TIR reflection prisms.

Description of the Prior Art

It is known to produce injection-molded products using at least two different materials, in this connection to the documents US 4,874,654 . US 4,935,184 . US 5,045,268 . US 5,413,743 . US 5,882,553 and EP 0 783 948 is referenced.

It is also known to produce TIR reflective prism-containing retroreflective components for a variety of applications using a variety of injection molding methods and a variety of molds, cold runner equipment, and hot runner equipment. These retroreflectors are useful for example in motor vehicles.

Reference is made in this connection to the publications US 3,363,875 . U.S. Patent 5,657,169 . US D514,718 . US 5,759,468 . US 6,171,095 . US 6,257,860 . US 6,540,202 . US 2007/170608 and US 2008/0088926 US Pat. Nos. '169 and' 202 and both US '608 and' 926 have been assigned to the present assignee.

According to the publication US 2008/0088926 which now transfers this to the present user U.S. Patent 7,722,196 is, several TIR prisms are arranged on a common substrate. The TIR prisms of US '196, also called corner cubes, are separated from each other, therefore, each TIR prism during the injection molding process with molten material via an independent cold or hot runner for each cavity, the part forms a single TIR prism , is supplied. US-196 'TIR prisms must have and also exhibit perfect surface finish and perfect edges to behave optimally from the standpoint of optical reflection, due to the fact that each TIR prism is made using a separate and individual cold or hot runner device and a corresponding method is poured. The final cast part of US '196 includes separate TIR reflection prisms on a common support of different orientation and size to reflect more or less light under the same illumination conditions.

There is a need to improve the reflectivity of the molded parts with a plurality of TIR reflection prisms of different sizes and orientations.

Brief summary of the invention

The present invention provides an injection molding method and an injection molding apparatus capable of producing total retroreflective automobile lenses or other type lenses including a substrate or a substrate molded using a first material, as well as a plurality of accumulations of TIR particles. Total internal reflection (TIR) prisms cast using a second material or a second and a third material. The TIR prisms are connected by a network of connectors cast simultaneously with the TIR prisms using the same second material.

The TIR prisms (or corner cubes) according to this invention may have a different size within a cluster as well as different orientations within the cluster.

An injection molding apparatus according to the present invention utilizes a novel casting and a new hot runner design in which the molten material for the TIR prisms is injected using a single mold inlet to form each individual collection of TIR prisms. This means that an aggregate of TIR prisms is poured over a sprue while casting, and another collection of TIR prisms is poured over a separate and remote sprue.

In accordance with the present invention, at least two adjacent TIR prisms belonging to each cluster of TIR prisms are connected by a visible connector element providing a channel casting path which allows filling with molded plastic material of all TIR prisms belonging to a cluster , In other words, the number of pouring runs is equal to the number of accumulations of TIR prisms required by each application. In addition, each cast infeed is used to form a single network of visible connectors, which combine a specific collection of TIR prisms.

According to the present invention, a support of the lens is cast in a first step using a first material, and in a second step, the accumulations of TIR prisms and the connector elements are cast using a second material.

According to the present invention, the carriers and the TIR prisms and the connector elements may be cast in two separate steps, but using the same materials. This is done to improve the quality of the TIR prisms and to improve the cooling and shrinking properties of the casting process.

Brief description of the views of the drawing

1 shows an embodiment of the injection molding apparatus according to the present invention.

2 FIG. 12 shows a lens including a support element, accumulations of TIR prisms, and networks of interconnects, according to one embodiment of the present invention.

3a and 3b show accumulations of TIR prisms and networks of connectors according to another embodiment of the present invention.

4a and 4b show a lens that includes a support member, accumulations of TIR prisms, and networks of interconnects according to another embodiment of the present invention.

5 Figure 11 shows accumulations of TIR prisms and networks of interconnects according to another embodiment of the present invention.

6 Figure 11 shows accumulations of TIR prisms and networks of interconnects according to another embodiment of the present invention.

7 Figure 11 shows accumulations of TIR prisms and networks of interconnects according to another embodiment of the present invention.

Detailed description of the invention

1a and 1b show an injection molding apparatus ( 2 ) according to an embodiment of the present invention. The device according to 1a and 1b is used to make lenses ( 20 ) with TIR prisms for vehicles according to 2 manufacture. The TIR prisms may have two or more angled facets. In this application, by way of example only, TIR prisms having two angled facets or facets and three angled facets or facets are shown. Corner cube TIR prisms are most commonly used because they have the most commonly used reflective properties.

In contrast to the publication US 2008/0088926 , which is now assigned to the present applicant U.S. Patent 7,722,196 where only TIR corner cubes are shown, the present application discloses TIR prisms having two and more than three angled facets.

In the publication US 2008/0088926 , which is now assigned to the present applicant U.S. Patent 7,722,196 The TIR corner cubes are completely separated from each other and made using a single entry for each TIR corner cube. This inlet can be in a cold or hot runner injection mold.

In the present application, TIR prisms having two and more than three angled facets are disclosed which are joined and form clusters of TIR prisms having various shapes, sizes, orientations, and numbers of facets. The TIR prisms can also be connected by optical elements which are a facet or crystal surface.

1a shows a first casting station, the an injection mold ( 3 ) with two cast plates ( 7 ) and ( 5 ) to a first injection cavity ( 16 ), a first molten plastic material or resin through a casting inlet ( 11 ). The cavity ( 16 ) is used to form a substrate or support element ( 21 ) of the lens ( 20 ) using a direct inlet or cold or hot runners (not shown).

After the carrier element ( 21 ) in the mold ( 3 ) is cooled, the carrier element ( 21 ) in one of the mold plates ( 5 ) or ( 7 ) is held to one in 1b transferred second casting station, which is used to accumulations ( 22a and 22b ) of TIR prisms ( 24 and 28 ) and connector elements ( 26 ) pour using a second pourable material and thus complete the casting process.

The second casting station ( 2 ) is in 1b shown. An injection manifold ( 4 ) delivers a second molten plastic material to a plurality of hot runner nozzles ( 6 ). The nozzles ( 6 ) can be thermally inlet-controlled or valve inlet-controlled. A second mold ( 13 ), the two cast plates ( 10 ) and ( 12 ) is used to form a plurality of casting cavities ( 18 ) and ( 19 ) to build. The carrier element ( 21 ) is still in the first injection cavity ( 16 ) and remains in the second molding station during the injection of the second material. The casting cavities ( 18 ) are used to form a flow path of the second molten material so that the second molten material has injection cavities ( 19 ), which have a prism-like shape. The casting cavities ( 19 ) are used to collect accumulations ( 22a ) and ( 22b ) of TIR prisms ( 24 ) and ( 28 ), while the casting cavities ( 18 ) can be used to connect the network of connector elements ( 26 ) and ( 27 ) to build. Using the present invention, a single inlet ( 8th ) or a nozzle ( 6 ) are used to cast a plurality of TIR reflectors that are spaced apart from each other and form clusters of TIR prisms, these clusters being formed by the connector elements (FIGS. 26 ) and ( 27 ) are connected. This means that fewer inlets and fewer nozzles are used to simultaneously pour TIR prisms of equal or different sizes using the connector elements as a flow path, as well as for reasons of optical design.

3a -B show further modifications of the lens 20 with other shapes and sizes of accumulations of TIR prisms and connector elements. In 3a For example, there are three TIR corner cube prisms joined by single-facet and facet optic elements, respectively, made of the same molten material. The TIR corner cube prisms have the same size and shape but different orientations.

4a -B show other modifications of the lens 20 with other shapes and sizes of accumulations of TIR prisms and connector elements. In 3a respectively. 4a There are seven TIR corner cube prisms joined by two-facet TIR optic prisms (elements) all made of the same molten material simultaneously. The TIR corner cube prisms have different sizes and the same or different orientations. The two facet prisms also play a useful role in the reflection, which is different from that of the TIR three facet cube. The two-facet or prism bonding prisms have different shapes 4a - 4b on.

In 5a For example, the automobile lens is shown with the accumulation of TIR prisms from the front, with ten accumulations of TIR prisms. Each assembly has in combination TIR prisms of the corner cube (three facets or facets) connected by prisms with two facets or facets.

5b shows the path DD of a single accumulation, where in 5a and 5c the accumulation of 5b shown in cross section. As in 5c 3, an inlet shown as a tapered channel on a three-platen injection liner is shown to illustrate how during a injection cycle a first material is injected through this inlet to fill casting cavities that are all TIR corner cubes in a cluster connected by cavities defining the two-facet prisms that connect the TIR corner cubes.

5d and 5e show a view and a cross section through the two accumulations of TIR prisms of 5a , As in 5e is shown, each collection of TIR prisms of 5a poured by injecting molten material through separate inlets, that is, one inlet per collection for pouring all TIR prisms of a pool in a single pass.

In a second injection step, after the TIR accumulation material is cooled, the TIR accumulations are held in the core or cavity and the casting plate is moved by sliding or turning to a next injection mold around the base or carrier lens that holds all TIR prisms in the form of TIR prism clusters.

In accordance with the present invention, by joining the TIR prisms to molten material forming connectors, the TIR prisms forming an aggregate can be injected with a single cold or hot runner nozzle or inlet. This not only reduces the number of nozzles compared to the prior art document US 2008/0088926 , which is now assigned to the present applicant U.S. Patent 7,722,196 It also provides a lens with TIR prisms having various appearances, configurations, and optical reflection patterns, which is a combination of three and two facet TIR prisms and TIR prism cube prisms and single facet or prismatic prisms. Crystal surface elements that connect the TIR corner cube represents.

in the 6 and 7 Another lens with accumulated TIR prisms is shown. In 7b For example, a single hot runner nozzle and associated runner are shown casting a collection of five TIR corner cubes connected by four two-facet prisms.

According to the invention, the TIR accumulations can be cast using red or transparent plastic resin, with a carrier cast in a second pass, which is transparent or red in each case. In addition, both the carrier of the lens and the TIR prisms can be injected in two successive passes of the same material, for example red or transparent.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 4874654 [0002]
• US 4935184 [0002]
• US 5045268 [0002]
• US 5413743 [0002]
• US 5882553 [0002]
• EP 0783948 [0002]
• US 3363875 [0004]
• US 5657169 [0004]
• US 514718 [0004]
• US 5759468 [0004]
• US 6171095 [0004]
• US 6257860 [0004]
• US 6540202 [0004]
• US 2007/170608 [0004]
• US 2008/0088926 [0004, 0005, 0021, 0022, 0033]
• US 7722196 [0005, 0021, 0022, 0033]

Claims (8)

Injection molded multi-color lens for vehicles, comprising: A substantially planar support injection molded using a first castable resin having a set of first chemical and optical properties, the support having two opposing surfaces having no optical power; A plurality of accumulations of TIR reflector prisms injection molded using a second castable resin having an amount of second chemical and optical properties, each aggregate including at least two TIR reflector prisms; A network of visible connectors injection molded using the second castable resin, the connectors providing a continuous connection between at least two adjacent TIR reflector prisms, the TIR reflector prisms and connectors both on one of the opposite and opposite surfaces of the planar support are injection molded. A vehicular injection molded multicolor backlight lens according to claim 1, wherein said planar support has a radius of curvature. A vehicular injection molded multicolor backlight lens according to claim 1, wherein the planar carrier has an optical power. The injection molded multicolor backlight lens for vehicles according to claim 1, wherein the first resin is transparent or clear with no added color. A vehicular injection molded multicolor backlight lens according to claim 1, wherein said second resin is red and almost red at daylight external illumination conditions. A vehicular injection molded multicolor backlight lens according to claim 1, wherein the connector has a minimum length that allows the two adjacent TIR reflectors to substantially contact one another. A vehicular injection molded multicolor backlight lens according to claim 1, wherein the TIR reflectors have a height H and the connectors have a height h where H> h. An injection molding apparatus for forming a two-material lens including accumulations of TIR reflectors, comprising; A primary injection molding cavity for casting a lens support member using a first material; A secondary injection mold having a plurality of prismatic casting cavities for casting a plurality of TIR prisms forming an aggregate of TIR prisms, the secondary mold further including a network of casting cavities communicating with at least two adjacent prismatic casting cavities; form visible connector elements, wherein these connector elements connect at least two adjacent TIR prisms, where the TIR prisms and the connector elements.

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