JP2016098915A - Disc brake device for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disc brake device for a vehicle capable of suppressing breakage of a coating film on a part receiving stress from another component in a caliper body while suppressing increase of man-hours in implementing coating processing onto a metallic part of the caliper body.SOLUTION: A rust-proofing coating film 20 is disposed on a metallic part of a caliper body 12 configuring a disc brake device for a vehicle. The coating film 20 is composed of one layer obtained by binding at least one of zinc and zinc alloy and aluminum by a binder. A thickness of the coating film 20 is 30 μm or less.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a vehicle disc brake device including a caliper body provided with a rust-proof coating.

  Conventionally, for example, a device disclosed in Patent Document 1 has been proposed as this type of vehicle disc brake device. In this apparatus, a coating layer by powder coating and a film layer for rust prevention are laminated on the surface of the caliper body. Thereby, generation | occurrence | production of the rust on the caliper body surface is suppressed, aiming at chromium free-ization.

JP 2008-39046 A

  By the way, in said caliper body, the coating film is comprised by laminating | stacking a some layer. Therefore, although the occurrence of rust on the caliper body surface can be suppressed, the man-hours required for the coating process on the caliper body are increased because a plurality of layers are required.

Further, the coating film formed by laminating a plurality of layers as described above tends to be thick. For example, the film thickness is about 100 μm.
Here, in the caliper body, a portion that receives stress from other parts such as a bolt is referred to as a “contact portion”, and a coating film is provided on the contact portion. In this case, if the coating film provided at the contact portion is thick, the coating film may be damaged at the contact portion due to stress from other components. And when the fragments generated by such coating film breakage enter the cylinder hole of the caliper body during maintenance or filling of brake fluid, a slight gap is created between the piston and the piston seal, The brake fluid in the cylinder hole may leak to the outside through this gap. Therefore, when a thick coating film is provided on the caliper body, it is necessary to mask the contact portion so that the coating film is not provided on the contact portion. As a result, the man-hour required for the coating process is further increased. In addition, when performing masking in this way, the man-hour will increase, so that the area | region to which masking is performed is large.

  An object of the present invention is to provide a vehicle capable of suppressing breakage of the coating film at a portion that receives stress from other parts in the caliper body while suppressing an increase in man-hours when coating the metal portion of the caliper body. Disc brake device for use

  A vehicle disc brake device for solving the above-described problems is premised on a device in which a metal portion of a caliper body is provided with a rust-proof coating film. In this vehicle disc brake device, the coating film is composed of one layer in which at least one of zinc and a zinc alloy and aluminum are bound by a binder. And the film thickness of such a coating film is 30 micrometers or less.

  According to the above configuration, the coating film is applied by providing the coating film composed of one layer in which at least one of zinc and zinc alloy and aluminum are bound by the binder on the metal part of the caliper body. It is possible to suppress the occurrence of rust on the part. Further, such a coating film is composed of one layer. Therefore, compared with the case where a coating film is formed by laminating a plurality of layers, the number of steps required for the coating process can be reduced.

  Moreover, in the said structure, the film thickness of such a coating film is 30 micrometers or less. For this reason, even if a coating film is provided on the contact part that receives stress from other parts in the metal part of the caliper body, the film thickness of the coating film is relatively thin. Even if it is added, the coating film at the contact portion is not easily damaged. Therefore, when the coating film is provided on the metal portion of the caliper body, there are no areas that require masking, or there are fewer areas that require masking. Thereby, the trouble at the time of providing a coating film in the metal part of a caliper body is simplified.

  Therefore, it is possible to suppress damage to the coating film at a portion of the caliper body that receives stress from other parts while suppressing an increase in the number of man-hours when coating the metal portion of the caliper body.

  By the way, if the coating film is too thin, the metal part of the caliper body may be rusted due to deterioration of the coating film caused by continuing to use the vehicle disc brake device. Therefore, the thickness of the coating film provided on the metal part of the caliper body is preferably 10 μm or more. According to this configuration, it is possible to suppress the occurrence of rust on the metal portion of the caliper body resulting from the continued use of the vehicle disc brake device.

  In addition, when the surface roughness RZ of the coating film is too large, the adhesion between the caliper body contact portion and other parts in contact with the contact portion tends to decrease. As a result, liquid leakage from between the inlet hose mounting section and the inlet hose, which is the inlet of the brake fluid into the caliper body, and abnormal noise caused by large vibration between the caliper body and the pad There is a risk of occurrence. Therefore, the surface roughness RZ of the coating film provided on the metal portion of the caliper body is preferably 40 μm or less. According to this configuration, it is possible to suppress a decrease in the degree of adhesion between the contact portion of the caliper body and other components that are in contact with the contact portion. Therefore, it is possible to suppress liquid leakage from the caliper body and generation of abnormal noise between the caliper body and the pad.

  Furthermore, it is preferable that the coating film provided on the metal part of the caliper body contains a colorant. According to this configuration, the caliper body can be colored by one layer as well as rust prevention. That is, the design of the caliper body can be improved while reducing the thickness of the coating film provided on the metal portion of the caliper body.

  In the above-described vehicle disc brake device, a rust-proof coating film may be provided on a metal component other than the caliper body among components constituting the vehicle disc brake device. In this case, the coating film is preferably composed of one layer in which at least one of zinc and a zinc alloy and aluminum are bound by a binder.

  According to the said structure, a rust-proof coating film can be provided also to metal parts other than a caliper body with the same coating material as the coating material used for the coating process to the metal part of a caliper body.

A sectional view showing a schematic structure of one embodiment of a disk brake device for vehicles. The top view which shows the caliper body which comprises the disk brake device for vehicles of the embodiment. The schematic diagram which shows the coating film provided in the caliper body. The top view which shows the out pad which comprises the disk brake device for vehicles. The top view which shows the piston which comprises the disk brake device for vehicles. The top view which shows the slide pin which comprises the disk brake device for vehicles. The top view which shows the plug which comprises the disk brake device for vehicles. The top view which shows the volt | bolt which comprises the disk brake device for vehicles.

Hereinafter, an embodiment of a vehicle disc brake device will be described with reference to FIGS.
As shown in FIG. 1, the vehicle disc brake device 11 of the present embodiment includes a metal caliper body 12 supported by a vehicle body, and a disc rotor 13 that rotates integrally with a wheel. The caliper body 12 is provided with a cylinder hole 121 opened to the disk rotor 13 side, and brake fluid is supplied into the cylinder hole 121 in accordance with a brake operation by the driver or driving of the brake actuator. . In the cylinder hole 121, the piston 14 slides in a direction toward and away from the disk rotor 13.

  Further, an outer pad 15 and an inner pad 16 are provided on both sides of the disc rotor 13. The outer pad 15 is an example of a metal part other than the caliper body 12 among the parts constituting the vehicle disc brake device. The outer pad 15 is supported by the caliper body 12 and supports the inner pad 16. When the brake fluid pressure in the cylinder hole 121 is increased and the piston 14 is slid in the direction approaching the disk rotor 13, the pair of inner pads 16 are pressed against the disk rotor 13. Thereby, a braking force is applied to the wheels.

  By the way, the disk brake device 11 for vehicles is provided in the vehicle suspension, and water may adhere when driving | running | working. Therefore, since the caliper body 12 shown in FIG. 2 is a metal part, the surface of the caliper body 12 is subjected to a chromium-free rust-proof coating treatment.

  FIG. 3 shows a schematic configuration of the coating film 20 provided on the caliper body 12. As shown in FIG. 3, the coating film 20 is composed of one layer in which a zinc powder 21, an aluminum powder 22, and a colorant 23 composed of a pigment or the like are bound by a binder 24. . In this coating film 20, the zinc powder 21 and the aluminum powder 22 are folded and firmly bonded by the binder 24.

  In addition, it is preferable that the compounding quantity of the metal powder containing zinc and aluminum is 20-60 mass%. This is because when the amount of the metal powder is too large, the strength of the film is lowered, and when the amount of the metal powder is too small, the rust prevention performance is lowered. Instead of the zinc powder 21, a zinc alloy powder such as Zn—Ni may be used, or both zinc and zinc alloy powders may be used. Metal flakes (zinc flakes and aluminum flakes) may be used instead of metal powder.

  The binder 24 is a binder mainly composed of a chelate-form organic titanate compound. And it is preferable that the compounding quantity of an organic titanate is 1-15 mass%. This is because when the amount of the organic titanate compound is too large, the rust prevention performance of the film is lowered, and when the amount of the organic titanate compound is too small, the strength of the film is lowered. Note that the binder 24 may include an organic silicon compound in addition to the organic titanate compound.

Here, an example of the coating process for the caliper body 12 will be described.
First, a coating agent is prepared. This coating agent is a water-soluble solvent containing the above metal powder, a colorant, a binder component (a chelate organic titanate compound), an organic solvent such as ethylene glycol, and the like. Then, this coating agent is applied to the surface of the caliper body 12. Examples of the application method include a method in which the caliper body 12 is immersed in a storage tank in which the coating agent is stored, and a method in which the coating agent is sprayed on the surface of the caliper body 12.

  Then, the caliper body 12 to which the coating agent adheres is subjected to heat treatment, and the caliper body 12 after the heat treatment is dried. Thereby, the caliper body 12 is provided with a coating film 20 containing zinc powder and aluminum powder, a colorant, and an organic titanate compound forming a chelate. At this time, the organic titanate compound firmly binds a metal powder such as zinc and aluminum and constitutes a titanium oxide-based coating film 20 firmly bonded to the surface of the caliper body 12.

The conditions of the coating film 20 thus provided on the caliper body 12 include the following conditions (1) and (2).
Condition (1) The thickness of the coating film 20 is 10 μm or more and 40 μm or less.

  That is, when a water resistance test based on JIS 5600-6-2 is performed, rusting may occur in the caliper body 12 when the thickness of the coating film 20 is less than 10 μm. On the other hand, when the thickness of the coating film 20 was 10 μm or more, the caliper body 12 did not rust even when the water resistance test was performed. Therefore, from the viewpoint of water resistance, it is preferable that the thinnest part of the coating film 20 has a thickness of 10 μm or more.

  Further, when assembling other parts such as the outer pad 15 to the caliper body 12, bolts and nuts may be used. From other parts such as bolts and nuts, stress is applied to a contact portion of the caliper body 12 with the other parts. At this time, if the coating film 20 provided at the contact portion is too thick, the coating film 20 may be damaged by the stress. From this point of view, the coating film 20 preferably has a thickness of 40 μm or less.

  Incidentally, a foreign object such as a stone may hit the caliper body 12 while the vehicle is running. Therefore, an impact resistance test based on SAEJ400 was performed. The film thickness of the coating film 20 of the caliper body 12 subjected to such a test was about 20 μm. As a result of this test, peeling of the coating film 20 by 5 mm or more did not occur. That is, in the caliper body 12 provided with the coating film 20 that satisfies the condition (1), it can be said that the coating film 20 is less likely to be peeled off due to the collision of foreign matters such as stones.

  Further, as a vehicle provided with the vehicle disc brake device 11, a vehicle equipped with an engine using gasoline as fuel can be cited. In such a vehicle, gasoline may adhere to the caliper body 12 during refueling. Therefore, a test for gasoline resistance in accordance with JIS0202 was carried out to examine changes in the coating film 20. The film thickness of the coating film 20 of the caliper body 12 subjected to such a test was about 20 μm. As a result of this test, the caliper body 12 was not swollen, peeled off, or cracked in appearance, and further, wrinkles, gloss, significant change in color, and significant softening of the coating film 20 were not observed. That is, in the caliper body 12 provided with the coating film 20 that satisfies the condition (1), it can be said that a problem caused by the adhesion of gasoline does not occur.

  In addition, there is a possibility that brake fluid adheres to the caliper body 12. Therefore, a test for anti-brake property according to JIS0202 was carried out, and changes in the coating film 20 were examined. The film thickness of the coating film 20 of the caliper body 12 subjected to such a test was about 20 μm. As a result of this test, as in the case of the gasoline resistance test, the caliper body 12 was not swollen, peeled or cracked in appearance, and further wrinkled, glossy, markedly changed in color, and the coating film 20 There was no significant softening. That is, it can be said that the caliper body 12 provided with the coating film 20 satisfying the condition (1) does not cause a problem due to the adhesion of the brake fluid.

  Condition (2) The surface roughness RZ of the coating film 20 is 40 μm or less. Note that “RZ” is the maximum height, which is the difference in height between the highest peak and the lowest valley in the roughness curve excluding surface waviness.

  If the surface roughness RZ of the coating film 20 is too large, the degree of adhesion between the caliper body 12 and other parts in contact with the caliper body 12 will be low, and the following problems may occur. That is, because the brake fluid is supplied to the caliper body 12, there is no seal between the caliper body 12 and the piston 14 (see FIG. 1) and between the brake fluid supply / discharge pipe and the caliper body 12. A member will be provided. Then, the coating film 20 is also provided on the contact portion of the caliper body 12 with the seal member. If the surface roughness RZ of the coating film 20 is too large, the contact portion of the caliper body 12 and the seal member are separated. A slight gap is formed between them, and brake fluid may leak through the gap.

  Further, the coating film 20 is also provided on the caliper body 12 where the outer pad 15 is connected. Even in this case, if the surface roughness RZ of the coating film 20 is too large, vibration is generated when the reaction force generated by pressing the inner pad 16 against the disk rotor 13 is transmitted between the outer pad 15 and the caliper body 12. This may cause abnormal noise (so-called squeal) due to vibration.

  In this respect, when the surface roughness RZ is set to 40 μm or less, the degree of close contact between the caliper body 12 and other parts in contact with the caliper body 12 is unlikely to be lowered. As a result, leakage of brake fluid and occurrence of abnormal noise are less likely to occur.

As described above, according to the present embodiment, the following effects can be obtained.
(1) In this embodiment, by providing the caliper body 12 with a coating film 20 composed of one layer in which zinc and aluminum powders are bound together by a binder 24, The occurrence of rust can be suppressed. Such a coating film 20 is composed of one layer. Therefore, compared with the case where a coating film is formed by laminating a plurality of layers, the number of steps required for the coating process can be reduced.

  Moreover, the film thickness of the coating film 20 is 30 μm or less. Therefore, even if the coating film 20 is provided on the contact portion that is a portion that receives stress from other parts in the caliper body 12, the coating film 20 is relatively thin, so that the stress from the other parts is applied to the contact portion. Even if it is added, the coating film 20 at the contact portion is not easily damaged. Therefore, when the coating film 20 is provided on the caliper body 12, there are no regions that require masking, or there are fewer regions that require masking. Thereby, the trouble at the time of providing the coating film 20 on the caliper body 12 is simplified.

  Therefore, it is possible to suppress damage to the coating film 20 at a portion of the caliper body 12 that receives stress from other components while suppressing an increase in the number of man-hours when coating the metal portion of the caliper body 12.

  (2) The thickness of the coating film 20 provided on the caliper body 12 is 10 μm or more. Therefore, the generation of rust on the metal part of the caliper body 12 can be suppressed.

  (3) Furthermore, the surface roughness RZ of the coating film 20 is 40 μm or less. Therefore, leakage of brake fluid from between the caliper body 12 and the seal member can be suppressed, and generation of abnormal noise from between the caliper body 12 and the outer pad 15 during vehicle braking can be suppressed.

  (4) The coating film 20 also contains a colorant. That is, since the rust-proof coating film and the colored layer are not separately provided, the design of the caliper body 12 can be enhanced while the coating film 20 is thinned.

The above embodiment may be changed to another embodiment as described below.
The coating film 20 of the caliper body 12 may not contain a colorant.
-Although the coating is given with respect to the whole caliper body 12, it is not restricted to this, It is not necessary to coat a part of caliper body 12. FIG. For example, the wall surface of the cylinder hole 121 to which the brake fluid is supplied is not coated even with a conventional caliper body. This is because it has been confirmed that rust does not occur on the wall surface of the cylinder hole 121 without applying a rust-proof coating.

  Therefore, it is not necessary to coat the wall surface of the cylinder hole 121 with which the piston 14 can come into contact. In this case, when the caliper body 12 is coated, the wall surface of the cylinder hole 121 is masked. However, since a coating is applied to the contact portion of the caliper body 12 with the seal member, it is not necessary to mask the contact portion. Therefore, the same effect as the above (1) can be obtained.

  Of the components constituting the vehicle disc brake device 11, other metal components other than the caliper body 12 may be provided with a coating film having the same composition as the coating film 20 provided on the caliper body 12. Good. As the metal parts other than the caliper body 12, the outer pad 15 shown in FIG. 4, the piston 14 shown in FIG. 5, the slide pin 31 shown in FIG. 6, the plug 32 shown in FIG. 7, the bolt 33 shown in FIG. Can be mentioned.

  -As a caliper body, not only one constituted by one part but also one constituted by combining a plurality of parts is known. In a caliper body constituted by such a plurality of parts, a coating film having the same composition as that of the coating film 20 may be provided on a metal part among the parts constituting the body. On the other hand, it is preferable not to apply coating to non-metal parts among the parts constituting the caliper body.

  The binder may contain a chelate compound other than the organic titanate compound as a main component as long as at least one of zinc and a zinc alloy and aluminum can be bound.

Next, the technical idea that can be grasped from the above embodiment and another embodiment will be added below.
(A) The binder preferably contains a chelate compound.

  DESCRIPTION OF SYMBOLS 11 ... Vehicle disc brake apparatus, 12 ... Caliper body, 14 ... Piston which is an example of metal parts, 15 ... Outer pad which is an example of metal parts, 20 ... Coating film, 31 ... Slide which is an example of metal parts Pins, 32... Plugs that are examples of metal parts, 33... Bolts that are examples of metal parts.

Claims (5)

In the vehicle disc brake device in which a rust-proof coating film is provided on the metal part of the caliper body,
The coating film is composed of one layer in which at least one of zinc and a zinc alloy and aluminum are bound by a binder,
The vehicle disc brake device, wherein the coating film has a thickness of 30 μm or less. The vehicle disc brake device according to claim 1, wherein the coating film has a thickness of 10 μm or more. The disk brake device for vehicles according to claim 1 or 2 whose surface roughness RZ of said coating film is 40 micrometers or less. The vehicle disc brake device according to any one of claims 1 to 3, wherein the coating film includes a colorant. Of the parts constituting the vehicle disc brake device, a metal part other than the caliper body is provided with a rust-proof coating film, the coating film comprising at least one of zinc and a zinc alloy, and aluminum. The vehicular disc brake device according to any one of claims 1 to 4, wherein the vehicular disc brake device is formed of a single layer bound by a binder.