JP2018141534A - Disc brake device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the stability of pressing against a brake pad.SOLUTION: A piston cap 6 which transmits a pressing force of a piston 3 to a brake pad 4 is disposed at an opening 31 of the piston 3 of the invention. The piston cap 6 includes: an annular flange part 61 disposed between the opening 31 and the brake pad 4; multiple insertion parts 62 which are inserted into the piston 3 and fix the flange part 61 to the piston 3 while pressing an inner peripheral surface of the piston 3; and connection parts 63, each of which is formed at an inner periphery portion 61a of the flange part 61 and connects the flange part 61 with the insertion part 62. When a radial direction of the piston 3 is referred to as a piston radial direction, an outer peripheral edge 611 of the flange part 61 is positioned at the outer side of an outer peripheral edge 3a of the piston 3 when viewed in the piston radial direction. A penetration groove 64 is formed at an outer portion of each connection part 63 of the flange part 61 when viewed in the piston radial direction.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a disc brake device used in a vehicle.

  The disc brake device includes a caliper and a disc rotor, and a piston that presses the brake pad toward the disc rotor is incorporated in the caliper. This piston may be provided with a piston cap. For example, Japanese Patent Application Laid-Open No. 2011-163435 describes a piston cap that is disposed in an opening of a piston body via an intermediate sleeve. As a result, the frictional heat generated during braking is suppressed from accumulating in the piston body, the temperature rise of the brake fluid is suppressed, and the occurrence of the vapor lock phenomenon is suppressed.

JP 2011-163435 A

  However, in the conventional piston cap, since the claw portion on the inner peripheral side of the piston cap is press-fitted into the opening of the piston body and fixed, the inner peripheral portion of the piston cap is more than the outer peripheral portion due to the stress received from the claw portion. There is a risk of protruding toward the disc rotor. As a result, the outer diameter of the contact surface between the piston cap and the brake pad is reduced, the outer diameter of the pressing surface with respect to the brake pad is also reduced, and the distribution of the pressing surface with respect to the brake pad is biased. There is room for improvement. The stable pressing of the brake pad contributes to suppression of brake squeal.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a disc brake device that can improve the stability of pressing against a brake pad.

  The present invention is a disc brake device in which at least one of a pair of brake pads is pressed by a piston having an opening formed on the brake pad side and abuts against a disc rotor, and the opening includes the piston A piston cap that transmits the pressing force to the brake pad is disposed, and the piston cap is inserted between the opening and the brake pad, and the piston is inserted into the piston. A plurality of insertion portions that fix the flange portion to the piston in a state where the inner peripheral surface is pressed, and a connection portion that is formed in an inner peripheral portion of the flange portion and connects the flange portion and the insertion portion. When the radial direction of the piston is the piston radial direction, the outer peripheral edge of the flange is positioned on the outer side of the piston radial direction with respect to the outer peripheral edge of the piston. The said portion of the piston radially outside of the serial connections, through groove is formed.

  According to the present invention, since the through groove is formed in the connection portion, the stress received by the connection portion from the insertion portion press-fitted into the piston is distributed to the outside of the piston radial direction, and the warpage of the flange portion is suppressed. can do. In addition, since the outer peripheral edge of the flange is positioned on the outer side in the piston radial direction than the outer peripheral edge of the piston, the outer shape (for example, the outer diameter) of the pressing surface of the flange with respect to the brake pad can be increased. Distribution unevenness can be suppressed. That is, according to the present invention, it is possible to improve the stability of the pressing of the piston cap against the brake pad.

It is sectional drawing which shows the disc brake apparatus of 1st embodiment. It is a side view which shows the piston and piston cap of 1st embodiment. It is a side view which shows the state before the assembly | attachment of the piston and piston cap of 1st embodiment. It is a perspective view which shows the state before the assembly | attachment of the piston and piston cap of 1st embodiment. It is a front view which shows the piston cap of 1st embodiment. It is a side view which shows the state before the assembly | attachment of the piston and piston cap of 2nd embodiment. It is a front view which shows the piston cap of the deformation | transformation aspect of this embodiment. It is a front view which shows the piston cap of the deformation | transformation aspect of this embodiment.

  Hereinafter, the disc brake device of this embodiment will be described with reference to the drawings, taking a piston-facing disc brake device for a vehicle as an example. As shown in FIG. 1, the disc brake device A according to the first embodiment includes a disc rotor 1, a caliper 2, a plurality of pistons 3, a pair of brake pads 4, a shim 5, and a plurality of piston caps 6. It is equipped with. The disk rotor 1 is a disk member that is assembled to an axle hub (not shown) and rotates integrally with a wheel. In the description, the radial direction of the disk rotor 1 is referred to as “rotor radial direction”, the circumferential direction of the disk rotor 1 is referred to as “rotor circumferential direction”, and the axial direction of the disk rotor 1 is referred to as “rotor axial direction”. Each figure used for explanation is a conceptual diagram, and the shape of each part may not necessarily be exact.

  The caliper 2, the plurality of pistons 3, the pair of brake pads 4, the shim 5, and the plurality of piston caps 6 constitute a unit (caliper assembly) that generates a braking force against the rotation of the disk rotor 1. The caliper 2 is a member that is fixed to a vehicle support (not shown), and functions as a housing that holds the piston 3 and the brake pad 4 movably. The caliper 2 is disposed so as to straddle a part of the outer peripheral portion of the disk rotor 1.

  The caliper 2 includes an inner housing portion 21, an outer housing portion 22, and a connecting portion 23. The inner housing portion 21 and the outer housing portion 22 are disposed to face each other with the disc rotor 1 interposed therebetween. The inner housing portion 21 is disposed on the inner side in the rotor axial direction of the disk rotor 1. A plurality of cylinders 211 are formed in the inner housing portion 21 corresponding to the plurality of pistons 3. The outer housing portion 22 is disposed on the outer side in the rotor axial direction of the disk rotor 1. A plurality of cylinders 221 are formed in the outer housing portion 22 corresponding to the plurality of pistons 3. The connecting portion 23 is a portion that connects the inner housing portion 21 and the outer housing portion 22 on the outer side in the rotor radial direction. Although not shown, a leaf spring that urges the brake pad 4 inward in the rotor radial direction is provided in the vicinity of the connecting portion 23 of the caliper 2.

  The piston 3 is a pressing member that is assembled to the caliper 2 and presses the brake pad 4 toward the disc rotor 1. The piston 3 is driven by fluid (brake fluid) flowing into and out of the cylinders 211 and 221 in response to a brake operation. Two pistons 3 are provided in the inner housing portion 21, and two pistons 3 are provided at positions facing the outer housing portion 22.

  As shown in FIGS. 1 to 3, the piston 3 is a bottomed cylindrical member having an opening on the brake pad 4 side. In other words, the piston 3 has a cylindrical opening 31 on the brake pad 4 side, and the end of the cylinders 211 and 221 disposed on the bottom side (hereinafter also referred to as “cylinder bottom side”) has a disk shape. It is a member constituting the bottom surface portion 32. In other words, the piston 3 includes a cylindrical opening 31 that is an end on the brake pad 4 side, a cylindrical main body 30 that extends coaxially from the opening 31 to the cylinder bottom surface, and a cylinder bottom surface side of the main body 30. And a disk-shaped bottom surface portion 32 for closing the end portion of the disk.

  The pair of brake pads 4 are arranged so as to sandwich the disk rotor 1 and are incorporated in the caliper 2 so as to be movable in the rotor axial direction. The brake pad 4 is movable with respect to the caliper 2 by a predetermined distance in the circumferential direction of the rotor (from the initial position until it contacts the torque receiving surface of the caliper 2). The pair of brake pads 4 includes a brake pad 4 disposed on the inner housing portion 21 side and a brake pad 4 disposed on the outer housing portion 22 side. Since the brake pad 4, shim 5, and piston cap 6 disposed in the inner housing portion 21 and the outer housing portion 22 have the same configuration, only one brake pad 4, shim 5, and piston cap 6 will be described.

  The brake pad 4 includes a friction material 41 that slides against the disk rotor 1 to generate a friction force, and a metal back plate 42 that supports the back surface of the friction material 41. The friction material 41 of the first embodiment is formed so that the longitudinal direction is the rotor circumferential direction as a whole. The friction material 41 may be called lining in the market. The back plate 42 is a plate-like member in which the friction material 41 is fixed to the surface on the disk rotor 1 side and the shim 5 is disposed on the surface on the piston 3 side. The shim 5 is a metal plate-like member for suppressing noise. The shim 5 is disposed between the brake pad 4 and the piston cap 6.

  The piston cap 6 is a cap member disposed in the opening 31 in order to transmit the pressing force of the piston 3 to the brake pad 4. As shown in FIGS. 1 to 5, the piston cap 6 includes a flange portion 61, a plurality of insertion portions 62, a plurality of connection portions 63, and a plurality of through grooves 64. The flange 61 is an annular member disposed between the opening 31 of the piston 3 and the brake pad 4. In the first embodiment, since the shim 5 is disposed between the brake pad 4 and the piston 3, the flange portion 61 is disposed between the opening 31 and the shim 5. When the piston 3 is driven, the flange 61 presses the brake pad 4 through the shim 5. Hereinafter, in the description, the radial direction of the piston 3 is referred to as “piston radial direction”, the axial direction of the piston 3 is referred to as “piston axial direction”, and the circumferential direction of the piston 3 is referred to as “piston circumferential direction”.

  The collar part 61 of 1st embodiment is formed in the annular | circular shape. The outer peripheral edge 611 of the flange 61 is located on the outer side in the piston radial direction from the outer peripheral edge 3a of the piston 3 (the outermost peripheral surface, here, the outer peripheral surface of the main body 30), and the inner peripheral edge 612 of the flange 61 is open. It is located on the inner side in the piston radial direction than the outer peripheral edge 31 a of the portion 31. Since the flange 61 is annular, it can be said that the outer diameter of the flange 61 is larger than the outer diameter of the piston 3 (the maximum outer diameter, here the outer diameter of the main body 30). Further, it can be said that the inner diameter of the flange 61 is smaller than the outer diameter of the opening 31. The area of the end surface (end surface in the piston axial direction) of the flange portion 61 is based on the maximum value of the area of the axially orthogonal cross section of the piston 3 excluding the bottom surface portion 32 (the cross section obtained by cutting the piston 3 along the plane orthogonal to the piston axial direction). Is also big. In the present embodiment, since the central axis of the flange 61 and the central axis of the piston 3 coincide, the piston radial direction corresponds to the radial direction of the flange 61, and the piston axial direction corresponds to the axial direction of the flange 61. The piston circumferential direction corresponds to the circumferential direction of the flange 61.

  The insertion portion 62 is a portion that is inserted into the piston 3, and is a portion that fixes the flange portion 61 to the piston 3 in a state where the inner peripheral surface of the piston 3 is pressed. The insertion portion 62 protrudes from the inner peripheral edge 612 of the flange portion 61 to the cylinder bottom surface side (side away from the disk rotor 1) via the connection portion 63. A plurality of insertion portions 62 are formed in the collar portion 61. In the present embodiment, the plurality of insertion portions 62 are configured by two pairs of insertion portions 62 (that is, four insertion portions 62) when the two insertion portions 62 arranged opposite to each other are defined as a pair of insertion portions 62. . The four insertion portions 62 of the present embodiment are formed at equal intervals on the inner peripheral edge 612 of the flange portion 61.

  The insertion part 62 is formed in a curved shape (here, S-shaped). The insertion portion 62 has an abutting portion 621 that abuts on the inner peripheral surface of the piston 3 on the outer peripheral side. Before the insertion, the distance between the two contact portions 621 facing each other is larger than the inner diameter of the piston 3. Therefore, when the insertion portion 62 is inserted into the piston 3, the insertion portion 62 presses the inner peripheral surface of the piston 3, and is deformed inward (in the piston radial direction) by the reaction force. That is, the insertion portion 62 is press-fitted into the piston 3 in the assembled state. The piston cap 6 is press-fitted and fixed to the piston 3 by inserting the insertion portion 62 into the opening 31.

  The connection part 63 is formed in the inner peripheral part 61 a (here, the inner peripheral edge 612) of the collar part 61, and is a part that connects the collar part 61 and the insertion part 62. That is, the piston cap 6 includes a plurality of connection portions 63 (four here) corresponding to the plurality of insertion portions 62. The connecting portion 63 projects inward in the piston radial direction from the inner peripheral edge of the flange portion 61. Further, on the inner peripheral edge 612 of the flange portion 61, concave portions 63a that are recessed outward in the piston radial direction are formed on both sides of the connecting portion 63 in the circumferential direction of the piston. The outer edge of the recess 63a in the piston radial direction is formed in a convex arc shape. Due to the recess 63a, the insertion part 62 and the connection part 63 are easily deformed (stress is easily dispersed).

  The through groove 64 is a groove (hole) formed in a portion of the flange portion 61 on the outer side in the piston radial direction of the connection portion 63 and penetrating the flange portion 61 in the piston axial direction. The piston cap 6 includes a plurality of through grooves 64 (here, four) corresponding to the plurality of connection portions 63. The through groove 64 of the present embodiment is arranged in the circumferential direction of the piston so as to face the connecting portion 63 and the concave portion 63a (two concave portions 63a corresponding to the connecting portion 63) located on both sides of the connecting portion 63 in the piston radial direction. Stretched. And the piston circumferential direction one end part of the penetration groove 64 is located in the piston circumferential direction one side rather than the piston circumferential direction one end part of the concave part 63a on the piston circumferential one side, and the piston circumferential direction other end part of the penetration groove 64 is It is located in the piston circumferential direction other side rather than the piston circumferential direction other end part of the recessed part 63a of the piston circumferential other side. As described above, the through groove 64 is provided on the outer side in the piston radial direction of the connecting portion 63 so as to cover the connecting portion 63 and the two concave portions 63a corresponding thereto.

  The through groove 64 is formed in a shape curved in a convex arc shape on the outer side in the piston radial direction. The through groove 64 of the first embodiment is curved so as to follow a circle having the same center as the center of the flange 61 (here, a point on the central axis of the piston 3). The through groove 64 is formed so as to be close to the outer end of the recess 63a in the piston radial direction. In a state where the piston cap 6 is assembled to the piston 3, the end surface of the flange portion 61 on the brake pad 4 side is flat.

  In the non-braking state, the flange portion 61 is in a state of being close to the shim 5 (or the brake pad 4 when there is no shim 5). When the braking control is started, the piston cap 6 moves to the brake pad 4 side together with the piston 3, and the flange portion 61 comes into contact with the shim 5. At this time, if the inner peripheral part 61 a of the flange part 61 swells toward the brake pad 4, the inner peripheral part 61 a first contacts the shim 5, and the outer peripheral part 61 b of the flange part 61 does not contact the shim 5. The piston 3 and the piston cap 6 tend to press the shim 5 and the brake pad 4 as they are. In a state where only the inner peripheral part 61a of the flange 61 is in contact, the pressing area of the piston cap 6 against the shim 5 is not sufficiently secured, and there is room for improvement in terms of improving the stability of pressing.

  Here, according to the first embodiment, the stress received by the connection portion 63 due to the deformation of the insertion portion 62 is transmitted to the through groove 64, so that the stress is dispersed in the circumferential direction of the piston, and transmission to the outside in the piston radial direction is suppressed. . The through groove 64 plays a role of converting the stress transmission direction from the outside in the piston radial direction to the piston circumferential direction. Thereby, the stress which the outer peripheral part 61b of the collar part 61 receives reduces, and generation | occurrence | production of the curvature which the inner peripheral part 61a of the collar part 61 protrudes to the brake pad 4 side can be suppressed. In this embodiment, since the collar part 61 can be brought close to a flat shape, a contact area (pressing area) aimed at the shim 5 can be secured. Further, since the outer peripheral edge 611 of the flange 61 is located on the outer side in the piston radial direction than the outer peripheral edge 3a of the piston 3, that is, the outer diameter of the flange 61 is larger than the outer diameter of the piston 3 (main body 30). Therefore, the outer diameter of the pressing surface to the brake pad 4 is increased. Thereby, the bias of the distribution of the pressing surface in the whole brake pad 4 can be suppressed, and the pressing surface can be widely distributed with respect to the brake pad 4. Moreover, according to 1st embodiment, on the structure of the collar part 61, a contact area becomes larger than the structure which applies the piston 3 to the shim 5 as it is.

  As described above, according to the present embodiment, the outer diameter of the pressing surface is larger than the outer diameter of the piston 3 and the warpage of the inner peripheral portion 61a of the flange portion 61 is suppressed. The outer diameter of the contact surface increases, and the contact area (pressing area) can also be increased. Thereby, the stability of the press with respect to the brake pad 4 can be improved. Since the brake pad 4 is pressed toward the disc rotor 1 as stably as possible, the occurrence of brake squeal is suppressed.

  Furthermore, in this embodiment, since the through groove 64 extends in the piston circumferential direction so as to oppose the connecting portion 63 and the recessed portion 63a in the piston radial direction, the piston radial outside of the stress received by the connecting portion 63 and the recessed portion 63a. Can be effectively suppressed.

<Second embodiment>
The piston cap 6 of the second embodiment is different from the first embodiment in the shape of the flange portion 61. Therefore, a different part is demonstrated. In the description of the second embodiment, the description of the first embodiment and the drawings can be referred to as appropriate.

  As shown in FIG. 6, the flange portion 61 of the second embodiment is curved so that the outer peripheral edge 611 is positioned closer to the brake pad 4 than the inner peripheral edge 612 in a state where the piston cap 6 is assembled to the piston 3. ing. That is, at the time of manufacturing, that is, before assembling (before press-fitting), the flange portion 61 is positioned on the piston 3 side (side away from the brake pad 4) as it goes from the outer peripheral edge 611 to the inner peripheral edge 612 (toward the center). Furthermore, it is formed in a convex arc shape. In the assembled state, the through groove 64 suppresses the warp of the flange portion 61 (swelling of the inner peripheral portion 61 a), and the outer peripheral edge 611 is disposed closer to the brake pad 4 than the inner peripheral edge 612. It can be said that the flange portion 61 has a tapered surface shape in which the outer peripheral edge 611 is positioned closer to the brake pad 4 than the inner peripheral edge 612 before and after assembly. In FIG. 6, the curvature of the flange 61 is exaggerated, but the protruding width in the piston axial direction of the outer peripheral edge 611 with respect to the inner peripheral edge 612 in the embodiment is less than 1 mm (for example, 0.1 mm to 0.5 mm). is there.

  According to the second embodiment, when the braking control is started, the piston cap 6 and the piston 3 move toward the brake pad 4, and the outer peripheral edge 611 of the flange 61 first contacts the shim 5. Further, when the piston 3 further moves to the brake pad 4 side, the inner peripheral portion 61a of the flange 61 corresponding to the opening 31 is pressed to the brake pad 4 side, and the flange 61 is deformed while the flange 61 is deformed. Gradually contacts the shim 5 from the outer peripheral edge 611 toward the inner peripheral part 61a. Alternatively, the shim 5 and the brake pad 4 are pressed at the outer peripheral portion 61 b including the outer peripheral edge 611. In other words, the outer peripheral edge 611 of the flange 61 first contacts the shim 5, so that the distribution of the pressing surface of the flange 61 on the shim 5 can be reliably expanded, and the contact area can be increased with high accuracy. Can do. According to the second embodiment, it is possible to improve the stability of pressing of the flange portion 61 and suppress brake noise.

  In addition, in order to make the shape of the collar part 61 of an assembly state close to flat shape (aiming to become flat), you may form the shape of the collar part 61 before an assembly in the above convex arc shape. Moreover, the collar part 61 may be formed so that the outer peripheral part 61b is located closer to the brake pad 4 than the inner peripheral part 61a (for example, the inner peripheral edge) in the assembled state. For example, if the outer peripheral portion 61b is 1/2 of the difference obtained by subtracting the inner diameter from the outer diameter of the flange 61 (in other words, 1/2 of the extension length in the piston radial direction), A set of points whose separation distance from the outer peripheral edge 611 of the flange 61 is ½ of the total length may be defined as a boundary and defined as a region outside the boundary in the piston radial direction. Moreover, you may define the area | region inside the piston radial direction of the said boundary among the collar parts 61 as the internal peripheral part 61a.

(Other)
The present invention is not limited to the above embodiment. For example, as shown in FIG. 7, the through groove 64 may be formed with a minimum circumferential length that covers the connection portion 63 and the recess 63a. Further, as shown in FIG. 8, the through groove 64 may be larger than the piston circumferential width of the connecting portion 63 and the concave portion 63a and may be linear as in the first embodiment. That is, in the configuration in which the through groove 64 extends in the circumferential direction of the piston, the shape of the through groove 64 is curved in a convex arc shape outward in the piston radial direction (see FIGS. 5 and 7), and on the end surface of the flange portion 61. Those extending in the circumferential direction of the piston at one point (see FIG. 8) are included. Moreover, the through-groove 64 should just be formed in the piston radial direction outer side of the connection part 63 at least. Even with this configuration, the stress received by the connecting portion 63 is dispersed and is not easily transmitted to the outside in the piston radial direction, and the warpage of the flange portion 61 is suppressed.

  Here, the piston cap having no through groove 64 in the configuration of FIG. 5 and the piston cap 6 of FIGS. 5, 7, and 8, which are different only in the shape of the through groove 64, are assembled to the same piston 3. The amount of warpage (the amount of swelling of the inner peripheral edge 612) was measured. According to this measurement, the amount of warpage was small in the order of the configuration of FIG. 8, the configuration of FIG. 5, the configuration of FIG. 7, and the configuration without the through groove 64. That is, in suppressing the amount of warpage, the through groove 64 preferably covers the recess 63a, and more preferably has a structure longer than the distance between the two recesses 63a as shown in FIGS. Moreover, you may apply the shape of these through-grooves 64 to the structure of 2nd embodiment.

  Further, the through groove 64 may be configured by a plurality of circular through holes continuously arranged in the circumferential direction of the piston. Further, the type of the disc brake device A (caliper 2) may be a facing type or a floating type. The through groove 64 can be rephrased as a notch or a slit. Further, it is sufficient that two or more insertion portions 62 are formed. For example, two insertion portions 62 may be arranged to face each other, or three insertion portions 62 may be arranged at equal intervals in the piston circumferential direction. good. Moreover, the shape of the collar part 61 should just be cyclic | annular (as long as the through-hole is formed in the center site | part), and an external shape is not restricted circular shape, For example, elliptical shape, polygonal shape, or the brake pad 4 or shim The shape according to the shape of 5 may be sufficient. However, from the viewpoint of applying the pressing force evenly to the brake pad 4, the outer shape of the flange portion 61 is preferably circular (that is, the flange portion 61 is annular). Further, the width of the through groove 64 in the piston radial direction may be set according to the size of the flange portion. In addition, the flange portion 61 may be formed such that a portion other than the inner peripheral edge 612 of the flange portion 61 is positioned closer to the brake pad 4 than the inner peripheral edge 612 in the assembled state. Further, the shim 5 may not be provided, and in this case, the flange portion 61 is in direct contact with the brake pad 4. The brake pad 4 and the shim 5 can be said to be pressed members.

  Further, the inner peripheral edge 612 of the flange 61 may be located on the outer side in the piston radial direction than the outer peripheral edge 31a of the opening 31. That is, in this case, the entire flange portion 61 is located on the outer side in the piston radial direction from the outer peripheral edge of the opening 31. Also by this, the distribution of the pressing surface with respect to the brake pad 4 can be expanded.

DESCRIPTION OF SYMBOLS 1 ... Disc rotor, 2 ... Caliper, 3 ... Piston, 31 ... Opening part, 4 ... Brake pad, 5 ... Shim, 6 ... Piston cap, 61 ... Gutter part, 61a ... Inner peripheral part, 61b ... Outer peripheral part, 62 ... Insertion part 63 ... Connection part 63a ... Recess, 64 ... Through groove, A ... Disc brake device.

Claims (4)

A disc brake device that presses at least one of a pair of brake pads with a piston having an opening formed on the brake pad side to contact the disc rotor,
A piston cap that transmits the pressing force of the piston to the brake pad is disposed in the opening,
The piston cap fixes an annular flange disposed between the opening and the brake pad and the flange in a state of being inserted into the piston and pressing an inner peripheral surface of the piston. A plurality of insertion portions, and a connection portion that is formed on an inner peripheral portion of the flange portion and connects the flange portion and the insertion portion,
When the radial direction of the piston is the piston radial direction,
The outer peripheral edge of the flange is located on the outer side in the piston radial direction than the outer peripheral edge of the piston,
A disc brake device in which a through groove is formed in a portion of the flange portion on the outer side in the piston radial direction of the connecting portion. When the circumferential direction of the piston is the piston circumferential direction,
On the inner peripheral edge of the flange portion, concave portions recessed outward in the piston radial direction are formed on both sides of the piston in the circumferential direction of the connection portion,
2. The disc brake device according to claim 1, wherein the through groove extends in the piston circumferential direction so as to face the connecting portion and the concave portion located on both sides of the connecting portion in the piston radial direction.   The disc brake device according to claim 1, wherein an outer peripheral portion of the flange portion is positioned closer to the brake pad than the inner peripheral portion.   The disc brake device according to any one of claims 1 to 3, wherein an inner peripheral edge of the flange portion is located on an outer side in the piston radial direction than an outer peripheral edge of the opening.

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