KR100902868B1 - A magnetic rubber composition for hub bearing encoder - Google Patents

Abstract

The present invention discloses a magnetic rubber composition for a hub bearing encoder. In a magnetic rubber composition for a hub bearing encoder, which is located in a hub bearing of a vehicle and comprises a polymer, a filler, and a workability improving agent, the magnetic rubber composition for a hub bearing encoder according to an embodiment of the present invention comprises: a filler made of anisotropic ferrite; And 1 phr to 50 phr of zirconium (Zr: zirconium) or titanium (Ti: titanium) for 100 phr of polymer.

Description

Magnetic rubber composition for hub bearing encoders

The present invention relates to a magnetic rubber composition for a hub bearing encoder, and more particularly, to a magnetic rubber composition for a hub bearing encoder disposed in an encoder created in a vehicle bearing.

A general encoder is a device for detecting displacement, rotation direction and angle.

An encoder is also used in a vehicle. An encoder is installed in a bearing device to detect a rotation speed or a rotation direction of a wheel.

1 is a view showing a general bearing and encoder, Figure 2 is a front view of a part of the magnetic rubber shown in FIG.

1 and 2, the encoder 200 is schematically illustrated. The encoder 200 includes a magnetic rubber 210 and a rotation detector 220.

The magnetic rubber 210 is coupled to one side of the sealing member 100 disposed in the bearing device (not shown), and has magnetic poles different from each other at regular intervals.

The rotation detector 220 is disposed at a position adjacent to the magnetic rubber 210 and fixed to a frame, not shown.

The operation of the encoder 200 will be described below. When a part of the bearing rotates together with the wheel not shown, the magnetic rubber 210 also rotates, and the rotation detector 220 detects a magnetic field change caused by the rotation of the magnetic rubber 210 with a sensor and detects the change. Calculate the signal. Here, in order for the rotation detector to detect the magnetic field change of the magnetic rubber 210 with the sensor, the magnetic force of the sealing member must be strong, but accurate sensing can be performed.

Conventional magnetic rubber compositions for encoders use isotropic ferrite as a filler. Isotropic ferrite is formed by melting a raw material and forming it as it is.

Therefore, the rubber composition made of isotropic ferrite has a weak magnetic force is a problem that the rotation detector is difficult to measure the accurate magnetic field change. In addition, the rubber composition made of isotropic ferrite has a problem in that the dimensional precision during processing does not satisfy the exact pitch error desired by the manufacturer.

As an alternative to this, anisotropic ferrite can be used as the filler used in the magnetic rubber composition for the hub bearing encoder. Anisotropic ferrite has the advantage of excellent dimensional accuracy during processing. However, when the anisotropic ferrite is mixed with the rubber composition, the viscosity of the rubber composition becomes very high, so that the rubber composition cannot be mixed using a kneader for rubber raw materials such as kneader, banbury, and intermixer. There is a problem. Accordingly, in manufacturing a magnetic rubber composition for a hub bearing encoder, a manufacturer cannot use a kneader and needs to be mixed separately so that there is a problem in that mass production cannot be performed and manufacturing cost increases.

An object of the present invention is to provide a magnetic rubber composition for a hub bearing encoder having strong magnetic force, excellent dimensional accuracy during processing, and capable of mass production.

Magnetic rubber composition for hub bearing encoder according to a preferred embodiment of the present invention is a filler consisting of anisotropic ferrite consisting of 300 phr to 1300 phr for 100 phr polymer, and zirconium (Zr: 1 phr to 50 phr for 100 phr polymer) zirconium) or titanium (Ti: titanium) is made of a processability enhancer.

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Magnetic rubber composition for a hub bearing encoder according to an embodiment of the present invention is anisotropic ferrite is mixed there is an effect that the magnetic force is increased than the conventional magnetic rubber composition for hub bearing encoder.

In addition, the magnetic rubber composition for the hub bearing encoder according to an embodiment of the present invention is excellent in the dimensional accuracy of the rubber composition produced during the rolling (Rolling) process because the anisotropic ferrite is mixed compared to the rubber composition to which isotropic ferrite is added There is an effect of showing a stable short pitch error and cumulative pitch error.

In addition, the magnetic rubber composition for the hub bearing encoder according to an embodiment of the present invention has a low viscosity due to the mixing of the anisotropic ferrite and the workability improver has the effect that can be produced inexpensively by mass production using a general trainer.

Hereinafter, a magnetic rubber composition for a hub bearing encoder according to a preferred embodiment of the present invention will be described in detail.

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Magnetic rubber composition for hub bearing encoder according to a preferred embodiment of the present invention is a filler and It comprises a workability enhancer.

Fillers are intended to improve the adhesion of the polymer while improving processability and reinforcement. A brief description of the polymer is as follows. The polymer may be made of synthetic rubber containing common acrylonitrile (21-41%). Such synthetic rubbers are mainly used in rubber compositions requiring strong oil resistance and abrasion resistance due to their high oil resistance and wear resistance.

In the present invention, anisotropic ferrite is used as the filler. Anisotropic ferrite is a ferromagnetic material of which additives are synthesized at a high temperature. The anisotropic ferrite is superior in isotropic ferrite (isotropic), has excellent magnetic properties, relatively high temperature stability, and is composed of particles arranged up, down, or in a predetermined direction. In addition, the anisotropic ferrite exhibits a stable short pitch error and cumulative pitch error compared to the rubber composition to which isotropic ferrite is added because of excellent dimensional accuracy of the rubber composition prepared during rolling.
On the other hand, the anisotropic ferrite may be made of 300 phr to 1300 phr with respect to 100 phr of the polymer. When the rubber composition contains less than 300 phr of anisotropic ferrite, the magnetic composition is weak and cannot be used as a magnetic rubber to be mounted on a bearing of a vehicle. When the rubber composition contains 1300 phr or more of anisotropic ferrite, the rubber composition has a viscosity. It becomes excessively high, making it difficult to mix using a kneader.

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The workability improving agent is to lower the viscosity of the rubber composition. In the present invention, zirconium or titanium is used as a workability improving agent. Zirconium (Zr: zirconium) is a silver-white or gray-white shiny metal and belongs to the hexagonal system. Titanium (Ti: titanium) is a silver-white metal that is malleable and ductile and is annealed by heating.

When the zirconium or titanium is added to the rubber composition in powder form, the zigconium or titanium added in processing the rubber composition is elongated by stress and heat, thereby lowering the viscosity of the rubber.

Such zirconium or titanium is preferably mixed in a ratio of 1 phr to 50 phr relative to 100 phr of the polymer. When zirconium or titanium is mixed at a ratio of 1 phr to 50 phr with respect to 100 phr of the polymer, when it is discharged from a kneader such as a kneader, it not only comes out as a powder state but also improves workability and improves dispersibility to increase magnetic flux density. The short pitch and cumulative pitch error become stable.
Zirconium or titanium mixed ratio polymer If less than 1 phr for 100 phr is discharged from the kneader, such as kneader, there is no effect of improving the workability, and when more than 50 phr dispersibility worsens, the magnetic flux density is lowered, short pitch and cumulative pitch error is unstable.

The magnetic rubber composition for a hub bearing encoder according to another embodiment of the present invention is added to the workability enhancers such as zirconium and titanium to lower the viscosity can be used to prepare the rubber composition using a trainer. Accordingly, the mass production of the rubber composition is easy, there is an effect that can lower the manufacturing cost.

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Meanwhile, an anti-aging agent, a crosslinking aid, a crosslinking agent and a plasticizer for preparing a general rubber composition may be further added to the rubber composition as described above.

Antioxidants serve to prevent aging of organic polymeric materials. Antioxidants act to stop the chain reaction of automatic aging by oxygen, a major factor in aging.

The cross-linking agent functions to cross-link the monomers constituting the rubber composition. The crosslinking aid is for increasing the crosslinking density of the rubber composition while preventing side chain reaction. Sulfur may be used as such a crosslinking agent. Here, the sulfur is preferably made of 0.1 phr to 20 phr relative to 100 phr of the polymer. Plasticizers serve to soften the rubber composition.

The magnetic rubber composition for the hub bearing encoder according to the present invention as described above is stronger than the magnetic rubber composition for a hub bearing encoder, and the kneading workability can be more clearly understood by the following Table 1 and Table 2. .

Table 1 shows a comparison of the materials constituting the Examples and Comparative Examples used in the experiment.

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The magnetic rubber composition for a hub bearing encoder according to the present embodiment includes: a filler made of anisotropic ferrite and the processability of any one of 1 phr to 50 phr of zirconium (Zr: zirconium) or titanium (Ti: titanium) with respect to 100 phr of the polymer. It is made by including an enhancer.

In contrast, the magnetic rubber composition for the hub bearing encoder of Comparative Example 1 has the same weight ratio as the anti-aging agent, the crosslinking aid, the crosslinking agent, and the plasticizer of the first embodiment, but differs in that the filler is made of an isotropic plate.

In the magnetic rubber composition for the hub bearing encoder of Comparative Example 2, the weight ratio of the anti-aging agent, the crosslinking aid, the crosslinking agent, and the plasticizer of the present Example 1 is the same, but the filler is different from the anisotropic plate.

Ingredients (parts by weight) Comparative Example 1 Comparative Example 2 Example Polymer Solid State NBR ¹ 100 100 100 Liquid NBR ² - - -  Filler Isotropic Ferrite phr - - - wt% 10 to 40 - - Anisotropic ³ Ferrite phr - 300-1300 300-1300 wt% - 70-93 70-93 Anti aging agents 3C ⁴ 3 3 3 Crosslinking aid ZnO ⁵ 3 3 3 Stearic acid ⁶ One One One  Crosslinking agent Sulfur ⁷ 0.1 to 20 0.1 to 20 0.1 to 20 TMTD ⁸ 3 3 3 CBS ⁹ 2 2 2 Plasticizer TP-95 ¹⁰ 7 7 7 Machinability Enhancer Zr ¹¹ or Ti ¹² - - 1 to 50 wt%: Weight ratio of ferrite content to total rubber composition 1. Solid NBR: NBR in solid state with acrylonitrile content of 21 to 41% 2. Liquid NBR: Liquid state with acrylonitrile content of 21 to 41% NBR 3. Anisotropic Ferrite: Mechanically Oriented Anisotropic Ferrite 4. 3C: N-Phenyl-N`-iso-propyl-p-phenylenediamine 5. ZnO : Zinc oxide 6. Stearic Acid: Stearic acid 7. Sulfur: Sulfur 8. TMTD: Tetramethyl-Thiuram Disulfide 9. CBS: N-cyclohexyl-2-benzothiazole sulfenamide (N-Cyclohexyl-2-benzothiazole sulfenamide) 10.TP-95: Adipic acid Ether Ester system 11.Zr: Zr powder 12.Ti: Ti powder

Table 2 shows the results of the magnetic rubber composition for the hub bearing encoder according to the embodiment of the present invention and the comparative examples 1 and 2 after the magnetic density measurement and the kneading workability test.

Magnetic density measurement was a magnetic force density was determined by arbitrarily setting the air gap between one rubber composition and another composition with a general magnetometer.

The kneading workability test is defined as not mixing in a kneader, such as kneader, in a kneader such as a kneader, but not in a kneading state for rolling, but not in the kneading machine and being discharged as a powder.

First, the magnetic force density of the magnetic rubber composition for a hub bearing encoder according to the embodiment of the present invention is 1.8 mT or more at 3.0 mm of air gap.

However, the magnetic force density of the magnetic rubber composition for encoder according to Comparative Example 1 is 1.1 mT or more at Air Gap 3.0 mm suitable for use as the magnetic rubber for encoder mounted on the bearing of the vehicle, but the test result of the rubber composition of Comparative Example 1 It is not described because it is lower than the magnetic density tested in the rubber composition of the examples.

The magnetic density of the magnetic rubber composition for the hub bearing encoder according to Comparative Example 2 was sufficient to be used as the magnetic rubber for the encoder mounted on the bearing of the vehicle at Air Gao 3.0 mm, but it was discharged in the powder state in the kneading workability test. Will be excluded from comparison. That is, in the magnetic density measurement test, it can be seen that the rubber composition of the example is much superior to the magnetic composition of the rubber composition of Comparative Example 1.

In addition, in the kneading workability test, it is generally discharged in a lump state after the end of the open mill (rubber blender) operation that is continuously performed after the kneader operation, but the rubber composition of Comparative Example 2 is a result of the powder discharged after the kneader operation. Therefore, it can be seen that the rubber composition of the embodiment of the present invention can be discharged in a lump state from the kneader to improve workability and productivity in the open mill.

Exam name Comparative Example 1 Comparative Example 2 Example  Magnetic density Air Gap 1.0mm Significantly lower 31.9 31.8 Air Gap 2.0mm Significantly lower 7.7 7.8 Air Gap 3.0mm Significantly lower 1.9 1.8 Kneading workability Kneader Lump Powder Lump Open mill Lump Lump Lump

1 is a view illustrating a general bearing and encoder.

2 is a front view of a part of the magnetic rubber shown in FIG.

<Brief description of the major symbols in the drawings>

100. Sealing member 200. Encoder

210. Magnetic rubber 220. Rotation detector

Claims (5)

delete delete delete A magnetic rubber composition for a hub bearing encoder, which is located in a hub bearing of a vehicle, comprising a polymer, a filler, and a processability enhancer, The polymer consists of a solid NBR (NBR), The filler is composed of anisotropic ferrite consisting of 300 phr to 1300 phr per 100 phr of the polymer, The workability improving agent is a magnetic rubber composition for a hub bearing encoder, characterized in that any one of zirconium (Zr: zirconium) or titanium (Ti: titanium) consisting of 1 phr to 50 phr with respect to 100 phr of the polymer. The method of claim 4, wherein Magnetic rubber composition for a hub bearing encoder, characterized in that it further comprises a cross-linking agent comprising 0.1 phr to 20 phr sulfur relative to 100 phr of the polymer.

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