DE102021206781A1 - Squeegee blade with cross-linked base and sliding body - Google Patents

Abstract

The present invention relates to a method for producing a wiper blade rubber (10), in particular for a windscreen wiper, in which a first material (11*) for a base body (11) and a second material (12*) for at least one sliding body (12) of the Squeegee rubbers (10) are extruded and/or injected and/or cast together to form a base body/sliding body strand (100), with the at least one sliding body (12) covering part of the surface of the base body (11) which is required for the wiping contact of the Squeegee (10) is determined. The first material (11*) and the second material (12*) each comprise at least one crosslinkable polymer. In order to provide a wiper rubber in a simple, inexpensive and environmentally friendly manner, the wiping quality of which can be maintained over a long service life, the second material (12*) comprises at least one material-crosslinking crosslinking agent for crosslinking at least one crosslinkable polymer of the second material (12*) and at least one crosslinkable polymer of the first material (11*) and/or the first material (11*) comprises at least one materials-crosslinking crosslinking agent for crosslinking at least one crosslinkable polymer of the first material (11*) and at least one crosslinkable polymer of the second material (12*). In addition, the invention relates to a correspondingly manufactured wiper blade rubber.

Description

The present invention relates to a method for producing a wiper blade rubber and a wiper blade rubber produced accordingly.

State of the art

At present, wiper rubbers, for example for wiper blades of windshield wipers, are usually initially extruded as a double profile strand and then vulcanized. In order to ensure the adhesion of a friction-reducing anti-friction coating, the double strip is usually first halogenated or activated by plasma and then spray-coated with the solvent-based anti-friction coating. After the anti-friction coating has solidified, for example after drying and/or curing, the double profile strand is cut through in the middle. Such conventional production processes thus comprise at least five process steps (extrusion, vulcanization, halogenation/activation, coating, solidification, cutting).

The publication DE 10 2016 213 862 A1 relates to another method for producing wiper rubbers for wiper blades of windshield wipers.

Disclosure of Invention

The present invention relates to a method for producing a wiper blade rubber, in particular for a wiper blade, for example for a windshield wiper, for example for a vehicle, in which a first material for a base body and a second material for at least one sliding body of the wiper blade rubber together form a base body -Sliding body strand extruded and/or injected and/or cast, in particular extruded. The at least one sliding body covers part of the surface of the base body which is intended for the wiping contact of the wiper rubber.

In particular, the first material and the second material each include at least one crosslinkable polymer.

The second material comprises in particular at least one material-crosslinking crosslinking agent for crosslinking at least one crosslinkable polymer of the second material and at least one crosslinkable polymer of the first material and/or the first material comprises at least one material-crosslinking crosslinking agent for crosslinking at least one crosslinkable polymer of the first material and at least one crosslinkable polymer of the second material.

In the case of a squeegee manufactured in this way, the at least one sliding body can advantageously assume the function of a sliding coating. Because the at least one sliding body is extruded and/or injected and/or cast together with the base body, at least two process steps, namely halogenation/activation and solidification For example, drying and/or curing of the anti-friction coating can be saved. In particular, by means of the method, the at least one sliding body can advantageously be applied directly, i.e. without halogenation, which is harmful to the environment, and without the use of additional organic solvents, in contrast to conventional production processes for the production of wiper rubbers with a bonded coating , As a result of which the method can be carried out more simply, more cost-effectively and, in particular, in a more environmentally friendly manner.

Simply by the fact that the first material for the base body and the second material for the at least one sliding body are extruded and/or injected and/or cast together to form the base body-sliding body strand, a - compared to manufacturing methods in which a already vulcanized base body is coated with anti-friction varnish - improved adhesion between the base body and the at least one sliding body serving as anti-friction coating can be achieved.

In that the second material comprises at least one materials-crosslinking crosslinking agent, which is designed both for crosslinking at least one crosslinkable polymer of the second material and for crosslinking at least one crosslinkable polymer of the first material, and/or in that the first material has at least one materials-crosslinking crosslinking agent which is designed both for crosslinking at least one crosslinkable polymer of the first material and for crosslinking at least one crosslinkable polymer of the second material, crosslinking chemical bonds, in particular covalent bonds, between the first material and the second material can advantageously be formed by the at least one material crosslinking agent Material are formed, whereby a strong chemical bond between the base body and the at least one sliding body can be achieved, which is significantly stronger than a purely physical Ha ventilation, which can have a beneficial effect on maintaining the wiping quality of the squeegee over a long service life.

Overall, the method can be used to produce a squeegee rubber in a simple, cost-effective and environmentally friendly manner, the wiping quality of which can be maintained over a long service life.

The at least one sliding body can be extruded and/or injected and/or cast in the form of two sliding strips, for example. For example, the two sliding strips can be formed on two opposite sides of the base body.

The base body can, for example, comprise at least one wiper lip section, in particular which is intended for the wiping contact of the wiper rubber, at least one tilting web section and at least one fastening section. The at least one sliding body can be formed, for example, on the surface of the wiper lip section, in particular on the tip of the wiper lip section. For example, the at least one sliding body can be designed as two sliding strips on two opposite sides of the wiper lip section, in particular the tip of the wiper lip section, and/or in particular at least one wiping edge, in particular two wiping edges, can be formed on the surface of the wiper lip section, in particular the tip of the wiper lip section. The at least one sliding body can thus advantageously be formed at the functionally important points.

Insofar as the base body-sliding body strand is extruded and/or injected and/or cast as a single profile strand, the base body can, for example, comprise a wiper lip section, a tilting web section and a fastening section.

If the base body-sliding body strand is extruded and/or injected and/or cast as a double profile strand, the base body can have, for example, two wiper lip sections, two tilting web sections and two fastening sections. In this case, the two wiper lip sections can in particular be connected to one another on the one hand and, on the other hand, each be connected to a fastening section via a tilting web section.

Within the scope of one embodiment, the first material and the second material comprise at least one material-crosslinking crosslinking agent from the same class of crosslinking agent.

A class of crosslinking agent can be understood in particular as meaning a class or group of crosslinking agents whose crosslinking is based on a similar crosslinking mechanism. Examples of crosslinking agent classes are, for example, the peroxide crosslinking agent class and/or the sulfur crosslinking agent class and/or the isocyanate crosslinking agent class.

In this way, the chemical connection between the base body and the at least one sliding body can advantageously be further optimized.

The first material and the second material can in principle, in particular independently of one another, comprise one polymer or two or three or more polymers, for example a crosslinkable polymer or two or three or more crosslinkable polymers. For example, the first material and the second material, in particular independently of one another, can be one, in particular crosslinkable, polymer from one polymer class or a mixture of two or three or more, in particular crosslinkable, polymers from the same or different, in particular different, polymer classes, for example example a blend of ethylene propylene diene terpolymer and natural rubber or a blend of polychloroprene and natural rubber.

A polymer class can be understood in particular as meaning a class or group of polymers which are produced from the same monomer or from the same monomers. Examples of polymer classes are, for example, the class of ethylene-propylene-diene terpolymers (EPDM) and/or the class of polychloroprenes (CR) and/or the class of polyisoprenes and/or the class of natural rubbers (NR).

Within the scope of a further embodiment, the first material and the second material comprise at least one crosslinkable polymer from the same polymer class. In this way, the chemical connection between the base body and the at least one sliding body can advantageously be further optimized.

In another embodiment, the first material and the second material each include at least one peroxide crosslinkable polymer and at least one peroxide crosslinking agent. In this way, the chemical connection between the base body and the at least one sliding body can advantageously be further optimized in the case of peroxide-crosslinkable polymers, such as ethylene-propylene-diene terpolymers (EPDM).

Within the scope of another, alternative or additional embodiment, the first material and the second material each comprise at least a sulfur crosslinkable polymer and at least one sulfur crosslinking agent. In this way, the chemical connection between the base body and the at least one sliding body can advantageously be further optimized in the case of sulfur-crosslinkable polymers, such as polychloroprene (CR) and/or polyisoprene and/or natural rubber (NR).

A crosslinking agent can in particular comprise at least one crosslinking agent component. Optionally, crosslinking agents may comprise two or more, optionally even three or four or more, crosslinking agent components.

A peroxide crosslinking agent can in particular comprise at least one peroxide. For example, the at least one peroxide can be dicumyl peroxide [CAS 80-43-3] and/or di-(2-tert-butyl-peroxyisopropyl)-benzene [CAS 25155-25-3] and/or tert-butylcumyl peroxide [CAS 3457-61-2] and/or 2,5-dimethyl-2,5-di(tert-butylperoxy)hexane [78-63-7] and/or di-tert-butyl peroxide [110-05 -4] and/or 2,5-dimethyl-2,5-di(tert-butylperoxy)hexyne-3 [CAS 1068-27-5] and/or butyl-4,4-di-(tert-butylperoxy )-valerate [CAS 995-33-5] and/or 1,1,di-(tert-butylperoxy)-3,3,5-trimethylcyclohexane [CAS 6731-36-8] and/or tert-butyl peroxybenzoate [CAS 614-45-9] include or be.

In particular, a sulfur crosslinking agent may comprise at least one sulfur donor. For example, the at least one sulfur donor may comprise or be caprolactam disulfide and/or elemental sulfur. Furthermore, a sulfur crosslinking agent can, for example, comprise at least one accelerator. The at least one accelerator can be, for example, a dithiocarbamate and/or a thiuram and/or a thiazole and/or a thiazolidine, for example 3-methylthiazolidine-thione-2 [CAS 1908-87-8]), and/or a thiazole sulfenamide and/or comprise or be a guanidine. In addition, in particular, an activator, for example zinc oxide, can be added to the sulfur crosslinking agent.

In a further embodiment, the at least one material-crosslinking crosslinking agent of the first material and the at least one material-crosslinking crosslinking agent of the second material comprise at least one identical crosslinking agent component. In this way, the chemical connection between the base body and the at least one sliding body can advantageously be further optimized.

In a further embodiment, the at least one materials-crosslinking crosslinking agent of the first material and the at least one materials-crosslinking crosslinking agent of the second material comprise at least one identical peroxide and/or at least one identical sulfur donor and/or at least one identical accelerator. In this way, the chemical connection between the base body and the at least one sliding body can advantageously be further optimized.

Within the scope of a further embodiment, the second material crosslinks more strongly than the first material. In this way, the wiping quality of the wiper rubber can advantageously be optimized. In this case, the base body can in particular be equipped with greater elasticity for the wiping movement. The at least one sliding body can in particular be equipped with greater hardness for the wiping and sliding function.

In a further embodiment, the second material comprises a higher proportion of crosslinkable functional groups, for example double bonds, and/or a higher concentration of at least one crosslinking agent component, in particular a higher peroxide concentration and/or a higher accelerator concentration and/or a higher sulfur donor concentration than the first material. So can advantageously - especially when using crosslinkable polymers from the same polymer class in the first and second material, such as ethylene-propylene-diene terpolymer (EPDM) in the first and second material or polychloroprene (CR) in the first and second material of polyisoprene, in particular natural rubber (NR), in the first and second material - greater crosslinking and thus greater hardness of the second material and less crosslinking and thus greater elasticity of the first material can be achieved.

In a further embodiment, the first material and the second material each comprise at least one peroxide-crosslinkable polymer from the class of ethylene-propylene-diene terpolymers and at least one peroxide crosslinking agent. In particular, the second material can have a higher proportion of crosslinkable functional groups, for example double bonds, for example a higher proportion of diene of the ethylene-propylene-diene terpolymer and/or a, in particular higher, proportion of at least one additional double bond-containing compound, for example polybutadiene and/or polyisoprene and/or ethylene glycol dimethacrylate, and/or a higher peroxide concentration than the first material. Thus, advantageously, stronger crosslinking and thus higher hardness of the second material and a lower crosslinking tion and thus higher elasticity of the first material can be achieved.

For example, the first material may contain, based on its total polymer mass weight, ≥90% to ≤95% by weight of ethylene-propylene-diene terpolymer, ≥3% to ≤5% by weight of at least one compound having additional double bonds, for example to polybutadiene and/or polyisoprene and/or ethylene glycol dimethacrylate, and ≧1% by weight to ≦5% by weight of peroxide. The second material can, for example, based on its total polymer mass weight, ≥ 65 wt .-% to ≤ 85 wt .-% of ethylene-propylene-diene terpolymer, ≥ 10 wt .-% to ≤ 20 wt .-% of at least one compound having additional double bonds, for example to polybutadiene and/or polyisoprene and/or ethylene glycol dimethacrylate, and ≧5% by weight to ≦15% by weight of peroxide.

Within the scope of a further, alternative or additional embodiment, the first material and the second material each comprise at least one sulfur-crosslinkable polymer from the polychloroprene class and at least one sulfur-crosslinking agent. The second material can have a higher concentration of accelerator than the first material. In this way, it is advantageously possible to achieve greater crosslinking and thus greater hardness of the second material and less crosslinking and thus greater elasticity of the first material.

Within the scope of a further, alternative or additional embodiment, the first material and the second material each comprise at least one sulfur crosslinkable polymer from the class of polyisoprenes and/or natural rubbers, and at least one sulfur crosslinking agent. In this case, the second material can in particular have a higher sulfur donor concentration and/or a higher accelerator concentration than the first material. In this way, advantageously, greater crosslinking and thus greater hardness of the second material and less crosslinking and thus greater elasticity of the first material can be achieved.

In a further embodiment, the second material is pasty. The pasty form has the advantage that solid lubricants contained in the second material can be ground much smaller than when used in suspended form. As a result of the smaller grinding, improvements in the wiping quality of the wiper rubber and the abrasion resistance of the sliding body and thus the service life of the wiper rubber can in turn be achieved.

Within the scope of a further embodiment, the second material also comprises at least one solid lubricant, in particular graphite and/or polytetrafluoroethylene (PTFE) and/or polyethylene (PE) and/or molybdenum sulfide (MoS ₂ ). The method can be particularly advantageous for incorporating solid lubricants into the sliding body layer, since this avoids the suspension or dispersing of polymers and solid lubricants in solvents, which expands the selection and quantity of polymers that can be used.

In a further embodiment, the strand of base body and sliding body is solidified, for example in a salt bath or in a hot-air continuous oven, in particular with the formation of crosslinking chemical bonds between the first material and the second material. In this case, the first material can in particular be vulcanized and the second material can be cured. Joint solidification of the first and second material means that at least one method step, for example solidification of the bonded coating layer, can advantageously be omitted.

Within the scope of a further embodiment, the solidified base body-sliding body strand is cut at least once, in particular transversely to the direction of the strand, to form the wiper blade rubber. If the base body-sliding body strand is designed in the form of a single profile strand, one cut, in particular transverse to the direction of the strand, per wiper rubber may be sufficient. Insofar as the base body-sliding body strand is in the form of a double profile strand, the double profile strand can, however, be cut in particular by an axial cut, in particular between the two wiper lip sections, and a cut transverse to the direction of the strand, to form, in particular two, wiper rubbers.

With regard to further technical features and advantages of the method according to the invention, explicit reference is hereby made to the explanations in connection with the wiper rubber according to the invention as well as to the figures and the description of the figures.

Furthermore, the invention relates to a wiper rubber, in particular for a wiper blade, for example for a windscreen wiper, for example for a vehicle, which is produced by a method according to the invention.

A wiper rubber produced according to the invention can be detected, for example, by means of a light micrograph in cross section and electron micrographs in cross section with additional EDX analysis.

With regard to further technical features and advantages of the wiper rubber according to the invention, explicit reference is made to the explanations in connection with the method according to the invention as well as to the figures and the description of the figures.

character list

• 1 einen schematischen Querschnitt zur Veranschaulichung einer Ausführungsform eines erfindungsgemäßen Herstellungsverfahrens; und
• 2a,b schematische Querschnitt durch ein Extrusionswerkzeug zur Durchführung der in 1 gezeigten Ausführungsform.

Further advantages and advantageous configurations of the objects according to the invention are illustrated by the drawings and explained in the following description. It should be noted that the drawings are for descriptive purposes only and are not intended to limit the invention in any way. Show it

• 1 a schematic cross section to illustrate an embodiment of a manufacturing method according to the invention; and
• 2a,b schematic cross section through an extrusion die for carrying out the in 1 embodiment shown.

1 shows that in the illustrated embodiment of a method according to the invention for producing a wiper blade rubber 10, in particular for a windshield wiper, a first material 11* for a base body 11 and a second material 12* for at least one sliding body 12 of the wiper blade rubber 10 together to form a base body sliding body -Strand 100 is extruded and/or injected and/or cast in the form of a double profile strand. The base body 11 has two wiper lip sections A, A', two tilting web sections B, B' and two fastening sections C, C', the two wiper lip sections A, A' being connected to one another on the one hand and on the other hand via a tilting web section B, B' are connected to a fastening section C,C'. The at least one sliding body 12 covers part of the surface of the base body 11 which is intended for the wiping contact of the wiper rubber 10 . In particular, the at least one sliding body 12 is designed as two sliding strips on two opposite sides on the surface of the wiper lip sections A, A′ of the base body 11 . The at least one sliding body 12 can thus advantageously be formed at the functionally important points.

The first material 11* and the second material 12* each comprise at least one crosslinkable polymer. The second material 12* can in particular comprise at least one material-crosslinking crosslinking agent, which is designed both for crosslinking at least one crosslinkable polymer of the second material 12* and for crosslinking at least one crosslinkable polymer of the first material 11*. Alternatively or additionally, the first material 11* can comprise at least one material-crosslinking crosslinking agent, which is designed both for crosslinking at least one crosslinkable polymer of the first material 11* and for crosslinking at least one crosslinkable polymer of the second material 12*. In particular, the first material 11* and the second material 12* can include at least one material-crosslinking crosslinking agent from the same crosslinking agent class. For example, the at least one material-crosslinking crosslinking agent of the first material 11* and the at least one material-crosslinking crosslinking agent of the second material 12* can be at least one of the same crosslinking agent component, for example at least one of the same peroxide and/or at least one of the same sulfur donor and/or at least one of the same accelerator , include. In addition, the first material 11* and the second material 12* can also comprise at least one crosslinkable polymer from the same polymer class.

In particular, the second material 12* can be more crosslinking than the first material 11* and can comprise at least one solid lubricant, for example graphite, polytetrafluoroethylene, polyethylene and/or molybdenum sulfide.

For example, the first material 11* and the second material 12* may each comprise at least one peroxide crosslinkable polymer, for example from the class of ethylene-propylene-diene terpolymers, and at least one peroxide crosslinking agent. To achieve greater crosslinking of the second material 12*, the second material 12* can, for example, have a higher proportion of crosslinkable functional groups, in particular double bonds, and/or a higher concentration of at least one crosslinking agent component, in particular a higher peroxide concentration, than the include first material 11*,

In other examples, the first material 11* and the second material 12* can each comprise at least one sulfur crosslinkable polymer, for example from the polychloroprene class and/or from the polyisoprene class, in particular natural rubber, and at least one sulfur crosslinking agent. To achieve greater crosslinking of the second material 12*, the second material 12* can, for example, have a higher concentration of at least one crosslinking agent component, in particular a higher accelerator concentration and/or a higher sulfur donor concentration, than the first material 11* .

the inside 1 The base body-sliding body strand 100 shown can be solidified (not shown), for example in a salt bath or in a hot-air continuous oven, in particular with the formation of crosslinking chemical bonds between the first material 11* and the second material 12*. The hardened base body-sliding body strand 100 can then, for example immediately after hardening, for example in a salt bath, be cut at the point indicated by the dashed line axially and transversely to the direction of the strand to form wiper rubbers 10 (not shown).

the 2a and 2 B illustrate an embodiment of an extrusion tool W, in the form of an extrusion nozzle, for carrying out the in 1 illustrated embodiment of the manufacturing method according to the invention. 2a shows a cross section through a first nozzle section of the extrusion tip nozzle W, in which the base body is formed. 2 B shows a further cross section through a second nozzle section of the extrusion injection nozzle W, in which the at least one sliding body is co-extruded and/or co-injected and/or co-cast onto the base body. The second nozzle section can in particular follow the first nozzle section directly, for example without a gap.

Claims (14)

Method for producing a wiper blade element (10), in particular for a windscreen wiper, in which a first material (11*) for a base body (11) and a second material (12*) for at least one sliding body (12) of the wiper blade element (10) are used together are extruded and/or injected and/or cast to form a base body/sliding body strand (100), the at least one sliding body (12) covering part of the surface of the base body (11) which is intended for the wiping contact of the wiper rubber (10). is, wherein the first material (11*) and the second material (12*) each comprise at least one crosslinkable polymer, wherein the second material (12*) comprises at least one materials-crosslinking crosslinking agent for crosslinking at least one crosslinkable polymer of the second material (12*) and at least one crosslinkable polymer of the first material (11*), and/or wherein the first material (11*) at least one materials-crosslinking crosslinking agent for crosslinking at least one crosslinkable polymer of the first material (11*) and at least one crosslinkable polymer of the second material (12*). procedure after claim 1 , wherein the first material (11*) and the second material (12*) comprise at least one materials-crosslinking crosslinking agent from the same crosslinking agent class. procedure after claim 1 or 2 , wherein the first material (11*) and the second material (12*) comprise at least one crosslinkable polymer from the same polymer class. Procedure according to one of Claims 1 until 3 , wherein the first material (11*) and the second material (12*) each comprise at least one peroxide crosslinkable polymer and at least one peroxide crosslinking agent, and/or wherein the first material (11*) and the second material (12*) ) each comprise at least one sulfur crosslinkable polymer and at least one sulfur crosslinker. Procedure according to one of Claims 1 until 4 , wherein the at least one materials-crosslinking crosslinking agent of the first material (11*) and the at least one materials-crosslinking crosslinking agent of the second material (12*) comprise at least one identical crosslinking agent component. Procedure according to one of Claims 1 until 5 , wherein the at least one materials-crosslinking crosslinking agent of the first material (11*) and the at least one materials-crosslinking crosslinking agent of the second material (11*) comprise at least one same peroxide and/or at least one same sulfur donor and/or at least one same accelerator. Procedure according to one of Claims 1 until 6 , wherein the second material (12*) is more crosslinked than the first material (11*). Procedure according to one of Claims 1 until 7 , wherein the second material (12*) has a higher proportion of crosslinkable functional groups, in particular double bonds, and/or a higher concentration of at least one crosslinking agent component, in particular a higher peroxide concentration and/or a higher accelerator concentration and/or a higher sulfur donor concentration than the first material (11*). Procedure according to one of Claims 1 until 8th , wherein the first material (11*) and the second material (12*) each comprise at least one peroxide crosslinkable polymer from the class of ethylene-propylene-diene terpolymers and at least one peroxide crosslinking agent, wherein the second material (12*) a higher proportion of crosslinkable functional groups, in particular double bonds, in particular a higher proportion of diene of ethylene-propylene-diene terpolymer and/or an, in particular higher, proportion of at least one additional compound having double bonds, and/or a higher peroxide concentration than the first material (11*), and/or wherein the first material ( 11*) and the second material (12*) each comprise at least one sulfur crosslinkable polymer from the polychloroprene class and at least one sulfur crosslinking agent, the second material (12*) having a higher accelerator concentration than the first material (11 *) comprises, and / or wherein the first material (11 *) and the second material (12 *) each comprise at least sulfur-crosslinkable polymer from the class of polyisoprenes and / or natural rubbers, and at least one sulfur crosslinking agent, wherein the second Material (12*) comprises a higher sulfur donor concentration and/or a higher accelerator concentration than the first material (11*). Procedure according to one of Claims 1 until 9 , wherein the second material (12*) is pasty. Procedure according to one of Claims 1 until 10 , wherein the second material (12*) further comprises at least one solid lubricant, in particular graphite and/or polytetrafluoroethylene and/or polyethylene and/or molybdenum sulfide. Procedure according to one of Claims 1 until 11 , wherein the base body-sliding body strand (100), in particular in a salt bath or in a hot-air continuous furnace, in particular with the formation of crosslinking chemical bonds between the first material (11*) and the second material (12*), is solidified. Procedure according to one of Claims 1 until 12 , wherein the solidified base body-sliding body strand (100) is cut at least once, in particular transversely to the strand direction, forming the wiper rubber (10), in particular wherein the base body-sliding body strand (100) is formed in the form of a double profile and the double profile strand is cut axially and transversely to the strand direction into wiper rubbers. Wiper rubber (10), in particular for a wiper blade, in particular for a windshield wiper, in particular for a vehicle, produced by a method according to one of Claims 1 until 13 .

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