Patent Application
20160199904
The present invention relates to a mold used in a caliper casting device, a caliper casting device, a method for manufacturing a caliper, and a caliper.
A caliper used in a disc brake of an automobile is generally manufactured by casting. In this casting, generally, a so-called core is placed in a metal mold (die), and, for example, a molten aluminum alloy (molten metal) is poured into a cavity that is a space formed between the mold and the core (for example, Patent document 1).
A shrinkage cavity (pore) needs to be considered in casting the caliper. The molten metal shrinks when solidifying in the cavity, and is thus reduced in volume. For example, it is said that solidification shrinkage of about 7% of a volume occurs for an aluminum alloy. Thus, a shrinkage cavity due to shrinkage in a solidification process of the molten metal may be formed in the caliper obtained as a cast. As such, the product with such a shrinkage cavity may affect quality of a casting product.
The present invention is achieved in view of the above described problem, and has an object to provide a technique capable of preventing generation of a shrinkage cavity in solidification of molten metal poured into a casting mold in casting a caliper.
To achieve the object, in the present invention, a gate portion (a pouring gate portion or a sprue) through which molten metal is poured is made of a material having lower thermal conductivity than a material for a body portion of a mold (die).
More specifically, the present invention provides a mold used in a caliper casting device for casting a caliper for a brake, including: a body portion of the mold; and a gate portion that is made of a material having lower thermal conductivity than a material for the body portion of the mold, and through which molten metal is poured.
In the present invention, the gate portion through which molten metal is poured is made of the material having lower thermal conductivity than the material for the body portion of the mold, thereby reducing a cooling speed of molten metal around the gate portion as compared to a conventional example. This can prevent generation of a shrinkage cavity due to shrinkage that easily occurs in a solidification process of molten metal.
The gate portion may be connected to an inside of a body of the mold so as to constitute a part of the body portion of the mold for forming the caliper after casting. This can particularly prevent generation of a shrinkage cavity around the gate portion in the caliper.
The gate portion may be connected to the inside of the body of the mold and be in contact with a surface of the caliper so as to constitute a part of the body portion of the mold for forming the caliper after casting. This can particularly prevent generation of a shrinkage cavity in an area in contact with the gate portion in the caliper. A position in which the gate portion is provided is not particularly limited, but the gate portion may be provided in a position in which generation of a shrinkage cavity is desired to be further prevented. Also, a size of the gate portion is not particularly limited, but the size of the gate portion is preferably increased when a size of the caliper is large so as to effectively prevent generation of a shrinkage cavity.
In the case where the mold is made of alloy tool steel, and the gate portion is made of stainless steel, the gate portion may have thermal conductivity one third of that of the body portion of the mold. This can more effectively prevent generation of a shrinkage cavity. The ratio of the thermal conductivity described above is an example, and may be changed depending on the material for the mold and the material for the gate portion.
An inner surface of the gate portion may be coated with a heat insulating paint. This can prevent a temperature reduction of molten metal. This can further reduce a cooling speed of the molten metal around the gate portion.
The present invention may be specified as a caliper manufactured by the caliper casting device described above.
The body portion of the mold may be made of an alloy containing iron, and the gate portion may be made of stainless. The gate portion may be made of a material having lower thermal conductivity, for example, ceramic or a titanium alloy. This can more effectively prevent generation of a shrinkage cavity.
The present invention may be specified as a caliper casting device. Specifically, the present invention provides a caliper casting device including the mold described above, and a core placed in the mold.
The mold according to the present invention may be applied to a caliper casting device as described below. For example, the caliper casting device may be a caliper casting device for casting a caliper for a disc brake including a cylinder into which a piston is fitted, and a rotor housing surface that defines a space for housing a disc rotor, including: a mold; and a core placed in the mold, wherein the mold has a rotor housing surface forming portion that forms a part of the rotor housing surface after casting, and the core is positioned and held in the rotor housing surface forming portion during casting, and forms a part of the rotor housing surface together with the rotor housing surface forming portion after casting.
According to the caliper casting device described above, the rotor housing surface of the caliper may be formed by the core, and also the rotor housing surface forming portion that is formed as a part of the mold having higher thermal conductivity than the core. Specifically, casting with the core being positioned and held by the rotor housing surface forming portion of the mold can increase a cooling speed of molten metal in an area for forming the cylinder or the rotor housing surface of the caliper, and accelerate timing for solidification, as compared to a conventional example. This can prevent generation of a shrinkage cavity in the cylinder or the rotor housing surface of the caliper obtained by casting. Also, with the caliper casting device described above, during casting, the core is positioned and held in the rotor housing surface forming portion of the mold, thereby increasing accuracy of an assembling position of the core to the mold. Specifically, according to the present invention, the caliper casting device can be provided that can favorably prevent generation of a shrinkage cavity in solidification of molten metal poured into the casting mold, and increase accuracy of an assembling position of the core to the mold, in casting the caliper.
In the caliper casting device according to the present invention, a positioning groove that positions and holds the core may be formed in the rotor housing surface forming portion, the core may include a cylinder forming portion that forms the cylinder after casting, and a core print portion coupled to the cylinder forming portion, and the core print portion may have a fitted portion that can be fitted in the positioning groove and forms the rotor housing surface together with the rotor housing surface forming portion after casting. As such, the positioning groove for positioning and holding the core is provided in the rotor housing surface forming portion that is formed as a part of the mold, and the fitted portion included in the core print portion of the core is fitted in the positioning groove, thereby further increasing assembling accuracy of the core. In the caliper casting device according to the present invention, in pouring the molten metal into the mold, the fitted portion of the core may be fitted in the positioning groove provided in the rotor housing surface forming portion. Thus, for example, in a state where the mold is preheated and expanded in a process before the molten metal is poured into the mold (previous process), the fitted portion of the core may be fitted in the positioning groove in the mold. In the present invention, the rotor housing surface forming portion preferably has higher thermal conductivity than the core. Thus, a cooling speed of the molten metal in the area for forming the cylinder or the rotor housing surface of the caliper after casting can be more favorably adjusted.
The positioning groove may include a first groove, and a second groove intersecting the first groove, and the fitted portion may be fitted in the first groove and the second groove. The fitted portion formed in the core print portion of the core is thus fitted in the first groove and the second groove intersecting each other, and thus the positioning groove including the first groove and the second groove functions as a guide for placing the core. This can facilitate centering in assembling the core, and further increase accuracy of an assembling position. The shape formed by the first groove and the second groove perpendicular to each other may include both a cross shape and a T shape. Specifically, the positioning groove may include at least the first groove and the second groove, and the positioning groove may be formed with other grooves being added. Thus, the positioning groove may have a cross shape, a T shape, also an H shape, a # shape, or the like. The positioning groove may have a shape other than these exemplified shapes. The first groove and the second groove may be linear grooves and perpendicular to each other.
The core print portion may further include a stopper portion that is provided at an end of the fitted portion and is wider than the positioning groove, and the stopper portion may have a stepped surface that abuts against a side surface intersecting the positioning groove in the rotor housing surface forming portion when the fitted portion is fitted in the positioning groove. With such a configuration, the positioning accuracy of the core in placing the core in the mold can be further increased. Also, displacement of the core from a normal position due to a flow of the poured molten metal when the molten metal is poured into the mold can be favorably prevented.
The core may have a plurality of the cylinder forming portions, and each of the cylinder forming portions may be coupled by the core print portion.
The present invention may be specified as a method for casting a caliper. Specifically, the present invention provides a method for casting a caliper for a brake, including casting a caliper in such a manner that a gate portion of a caliper casting device for casting the caliper is made of a material having lower thermal conductivity than a material for a body portion of a mold used in the caliper casting device.
Also, the present invention may be specified as a caliper. Specifically, the present invention is a caliper produced by the method for casting a caliper described above.
According to the present invention, generation of a shrinkage cavity in solidification of molten metal poured into a casting mold can be prevented in casting a caliper.
Now, embodiments of a mold used in a caliper casting device and a caliper for a disc brake will be exemplarily described in detail with reference to the drawings. Dimensions, materials, shapes, and relative arrangement of components described in the embodiments are not intended to limit the technical scope of the invention to them unless otherwise stated.
The lower mold 100 includes a lower mold side gate forming portion 21a having a U shape on sectional view that forms a part of the gate (pouring gate or sprue)21. The lower mold side gate forming portion 21a and an upper mold side gate forming portion 21b of a U shape on sectional view described later are combined to form the gate 21 having a rectangular space therein. Either the lower mold side gate forming portion 21a or the upper mold side gate forming portion 21b may have a flat plate shape. In this embodiment, a sectional area (a section perpendicular to a flow direction of a molten aluminum alloy (molten metal)) of the gate 21 gradually decreases toward the mold, in other words, a width of the gate 21 gradually decreases, but the sectional area of the gate 21 (the width of the gate 21) may be constant. Through the gate 21, a molten aluminum alloy (molten metal) is poured into a cavity 250 that is a space existing (formed) between an inside of the mold and an outside of the core 200 (pouring). The gate 21 (the lower mold side gate forming portion 21a) is formed separably from the lower mold 100 of the mold, and reaches the cavity 250 so as to constitute a part of the lower mold 100. In Embodiment 1, in the gate 21, a substitution region 21a1 that constitutes a part of the lower mold 100 has a rectangular shape on plan view. Thus, the mold receives the gate 21, and a substituted region constituted by the substitution region 21a1 is shaped according to the shape of the substitution region 21a1 in the gate 21.
In this embodiment, the lower mold side gate forming portions 21a are provided in two areas on a long side of the lower mold 100, but the number and positions thereof may be changed. Further, the lower mold 100 includes a lower mold side feeder head forming portion 22a that forms one side of a feeder head 22. The feeder head 22 is a space for supplying molten metal when shrinkage occurs with a temperature reduction and solidification of molten metal casted into the cavity 250, and storing molten metal for preventing a so-called shrinkage cavity. A further feeder head may be provided on an opposite side of the feeder head 22.
As illustrated in
The gate 21 (the lower mold side gate forming portion 21a and the upper mold side gate forming portion 21b) is made of stainless steel. Specifically, the gate 21 is made of a material different from a material for the lower mold 100 and the upper mold 101 of the metal mold. Thermal conductivity of stainless steel used for the gate 21 is 17 W/mK, and smaller than thermal conductivity of alloy tool steel such as S50C (for example, thermal conductivity of S50C is about 54 W/mK), thereby reducing a cooling speed of molten metal around the gate 21. This can prevent generation of a shrinkage cavity due to shrinkage that easily occurs in a solidification process of the molten metal. When the gate 21 has high thermal conductivity, the molten metal has low fluidity, and thus it is necessary to increase the size of the gate 21 and force the molten metal into the gate 21 with the gravity of the molten metal. Thus, conventionally, the size of the gate 21 has to be increased. On the other hand, in Embodiment 1, the gate 21 has low thermal conductivity, and a state of the molten metal having high fluidity can be maintained longer than in the conventional example. Thus, even a small amount of molten metal is distributed in the mold, and the size of the gate 21 can be reduced as compared to the conventional example. The gate 21 may be made of ceramic, a titanium alloy, or the like rather than stainless steel. Thermal conductivity of ceramic is 0.03 W/mK, and thermal conductivity of a titanium alloy is 22 W/mK. An inner surface of the gate 21 may be coated with a heat insulating paint. An example of the heat insulating paint is a ceramic heat insulating paint.
The gate 21 and the mold may be connected by a securing member such as a bolt in view of workability of removing from the mold or replacement. The gate 21 and the mold may have holes that receive a shaft of the bolt. A position of the hole is not particularly limited. A head of the bolt may be located on the gate or on the mold. When the head of the bolt is located on the gate, for example, the hole may be provided in a flange in contact with a side surface of the mold of the gate 21 to secure the gate 21 to the mold. When the head of the bolt is located on the mold, the hole may be provided from a back surface of the mold to the gate 21 to secure the gate 21 to the mold.
From the above, in the caliper casting mold according to Embodiment 1 or Variant 1, the gate 21 through which the molten metal is poured is made of a material having lower thermal conductivity than the mold, thereby reducing a cooling speed of molten metal around the gate 21 as compared to the conventional example. This can prevent generation of a shrinkage cavity due to shrinkage that easily occurs in a solidification process of the molten metal.
The gate 21 and the feeder head 22 in Embodiment 1 can be also applied to a caliper casting device according to Embodiment 2 or variants described below.
First, with reference to
Between the first body portion 2 and the second body portion 3, a housing portion 6 is formed that is a space in which the disc rotor described above and a pair of brake pads (not illustrated) are housed (placed). The housing portion 6 is defined by the rotor housing surface 7. The rotor housing surface 7 is formed as inner wall surfaces of the first body portion 2, the second body portion 3, and the coupling portion 4. Other basic structures of the caliper 1 are the same as in a conventional caliper made of an aluminum alloy, and thus detailed descriptions thereof will be omitted.
The caliper 1 described above is casted by a caliper casting device (hereinafter simply referred to as “casting device”) 10 illustrated in
The mold 20 is constituted by a lower mold 40 and an upper mold 50. The core 30 is assembled to (placed in) the lower mold 40, and then the lower mold 40 and the upper mold 50 are coupled using a fastener or the like. Thus, assembling of the casting device 10 is completed, moving to a gate process of gate the molten metal through the gate 21. The lower mold 40 is a mold for mainly forming a vertically lower portion of the caliper 1 after casting, and the upper mold 50 is a mold for mainly forming a vertically upper portion of the caliper 1.
Next, detailed structures of the mold 20 (the lower mold 40 and the upper mold 50) and the core 30 will be described. The mold 20 may be made of, for example, alloy tool steel such as FC250, S50C, S55C, or SKD61, but not limited to them. The lower mold 40 and the upper mold 50 have joint surfaces 41, 51 placed on each other in coupling. The joint surface 41 of the lower mold 40 has two positioning pins 42. The joint surface 51 of the upper mold 50 has an insertion hole 52 into which the positioning pin 42 can be inserted. When the lower mold 40 and the upper mold 50 are coupled to assemble the casting device 10, the positioning pin 42 is inserted into the insertion hole 52, thereby allowing the lower mold 40 and the upper mold 50 to be placed in prescribed plane positions. In this embodiment, two positioning pins 42 and two insertion holes 52 are provided in the lower mold 40 and the upper mold 50, respectively, but the number thereof may be changed.
As illustrated in
In the lower mold 40, on opposite sides of the rotor housing surface forming portion 44, second rotor housing surface forming portions 46 protrude from the inner surface of the lower mold 40 away from the rotor housing surface forming portion 44. The second rotor housing surface forming portion 46 is a mold for forming a rotor housing surface 7 in an area closer to a circumferential end of the caliper 1 after casting.
Next, the core 30 will be described. The core 30 is a sand mold placed in the lower mold 40. The core 30 is placed in the mold 20 as a portion for forming a hollow portion such as the cylinder 5 of the caliper 1. In this embodiment, the core 30 is a shell core manufactured by shell molding of heating and curing silica sand (resin sand) mixed with thermosetting synthetic resin.
The core 30 includes a cylinder forming portion 31 for forming the cylinder 5 after casting, a core print portion 32 coupled to the cylinder forming portion 31, an oil passage forming portion 33, or the like. The caliper 1 is a six-pot opposed-piston caliper in which three cylinders 5 are arranged in each of the first body portion 2 and the second body portion 3, and the cylinders 5 in the first body portion 2 and the second body portion 3 are placed to face each other. Thus, the core 30 also includes a total of six cylinder forming portions 31.
The six cylinder forming portions 31 are denoted by reference numerals 31a to 31f. As illustrated in
The core print portion 32 includes a first beam 34 that couples the cylinder forming portion 31b and the cylinder forming portion 31e, and a second beam 35 perpendicular to the first beam 34. The first beam 34 has the same width as the first positioning groove 45a. The second beam 35 includes a fitted portion 35a to be fitted in the second positioning groove 45b described above, and a pair of stopper portions 35b provided at the opposite ends of the fitted portion 35a. The stopper portion 35b has a larger width than the fitted portion 35a of the second beam 35, and a stepped surface 36 (see
Next, a relationship between the core print portion 32 and the positioning groove 45 will be described. As described above, the first beam 34 and the second beam 35 in the core print portion 32 are perpendicular to each other, and thus the first beam 34 and the second beam 35 constitute a cross beam of a cross shape. The first beam 34 and the second beam 35 are collectively referred to as a cross beam 39 below.
In this embodiment, the first beam 34 and the first positioning groove 45a have the same width, and the fitted portion 35a of the second beam 35 and the second positioning groove 45b have the same width. Thus, the first beam 34 in the cross beam 39 can be fitted in the first positioning groove 45a, and the fitted portion 35a of the second beam 35 in the cross beam 39 can be fitted in the second positioning groove 45b. In this embodiment, in assembling the core 30 to the lower mold 40, the cross beam 39 of the core 30 is fitted in the positioning groove 45 provided in the rotor housing surface forming portion 44, thereby allowing easy and accurate positioning of the core 30. In this embodiment, the cross beam 39 fitted in the positioning groove 45 in placing the core 30 in the lower mold 40 corresponds to a fitted portion in the present invention. With the cross beam 39 (the first beam 34 and the second beam 35) of the core 30 being fitted in the positioning groove 45 (the first positioning groove 45a and the second positioning groove 45b), an upper surface of the cross beam 39 forms the rotor housing surface 7 of the caliper 1 together with the rotor housing surface forming portion 44 after casting.
In this embodiment, the case has been described in which the first beam 34 and the first positioning groove 45a have the same width, and the fitted portion 35a of the second beam 35 and the second positioning groove 45b have the same width, but not limited to this. For example, the first beam 34 may have a slightly smaller width than the first positioning groove 45a, and the fitted portion 35a of the second beam 35 may have a slightly smaller width than the second positioning groove 45b. In placing the core 30 in the lower mold 40, the lower mold 40 may be preheated and thus thermally expanded to increase the widths of the first positioning groove 45a and the second positioning groove 45b as compared to the widths at normal temperature, and then the first beam 34 and the fitted portion 35a of the second beam 35 may be fitted in the first positioning groove 45a and the second positioning groove 45b.
Next, the upper mold 50 will be described. As illustrated in
The casting device 10 described above is completed in such a manner that the core 30 is assembled to (placed in) the lower mold 40, and then the upper mold 50 is assembled to the lower mold 40. Then, a pouring process is performed of pouring a molten aluminum alloy (molten metal) into the cavity 60 formed in the mold 20. Specifically, in a manufacturing method for manufacturing a caliper for a disc brake according to this embodiment, the cross beam 39 (fitted portion) of the core 30 is fitted in the positioning groove 45 (the first positioning groove 45a and the second positioning groove 45b) formed in the rotor housing surface forming portion 44 to place the core 30 in the mold 20, and then the pouring process is performed of pouring a molten aluminum alloy into the mold 20 in which the core 30 is placed. The cavity 60 is a space formed between the lower mold 40 and the upper mold 50 and the core 30.
In the casting device 10 according to this embodiment, the rotor housing surface 7 after casting is formed by the core print portion 32 of the core 30 and the rotor housing surface forming portion 44 (the mold blocks 44a to 44d) constituted by the mold. Thermal conductivity of silica sand for forming the core 30 is generally about 0.38 W/mK, and remarkably smaller than that of the mold (for example, thermal conductivity of S50C is about 54 W/mK). In a conventional caliper casting mold in
In the casting device 10 according to this embodiment, the rotor housing surface 7 of the caliper 1 is formed by the core 30, and also by the rotor housing surface forming portion 44 (the mold blocks 44a to 44d) formed by the mold having larger thermal conductivity than the core 30. This can increase a cooling speed of molten metal in an area for forming the cylinder 5 or the rotor housing surface 7 of the caliper 1, and accelerate timing for solidification as compared to the conventional example. This can prevent the molten metal in the area for forming the cylinder 5 or the rotor housing surface 7 of the caliper 1 from solidifying excessively later than other areas. Thus, generation of a shrinkage cavity in the cylinder 5 or the rotor housing surface 7 of the caliper 1 obtained by casting can be prevented. It is considered that the solidification timing of the molten metal around the core 30 is later than that of the molten metal in other areas, but the core 30 of this embodiment may have a smaller volume than a conventional core 200. Thus, molten metal can be supplied from a feeder head when the molten metal around the core 30 solidifies, thereby sufficiently preventing a shrinkage cavity.
The solidification timing of the molten metal in the area for forming the cylinder 5 and the rotor housing surface 7 of the caliper 1 can be controlled to desired timing by adjusting an area ratio of the core print portion 32 that constitutes the core 30 having low thermal conductivity and the rotor housing surface forming portion 44 (the mold blocks 44a to 44d) of the mold having remarkably higher thermal conductivity than the core 30 (the core print portion 32). Specifically, designing the core 30 having a high heat retaining property and the mold having a high cooling capability in a balanced manner can favorably prevent defects in the caliper 1 obtained by casting.
Further, in the casting device 10, when the core 30 is placed in the lower mold 40, the cross beam 39 included in the core print portion 32 is fitted in the positioning groove 45 in the rotor housing surface forming portion 44 formed in the lower mold 40. Thus, unlike the conventional example, a so-called box-like core 200 (base 210) is not placed in the mold, and thus placement position accuracy of the core 30 can be increased as compared to the conventional example. In particular, in this embodiment, the positioning groove 45 is formed as a cross groove, and the cross beam 39 is fitted in the cross groove without clearance. Thus, the positioning groove 45 also functions as a guide for placing the core 30. This can facilitate centering in assembling the core 30, and further increase accuracy of an assembling position. Also, the first positioning groove 45a and the second positioning groove 45b that constitute the positioning groove 45 are formed linearly and perpendicularly to each other, thereby increasing machinability of the lower mold 40 (mold). Specifically, machining accuracy of the lower mold 40 (mold) can be increased, and thus accuracy of an assembling position of the core 30 to the lower mold 40 can be also increased, thereby increasing dimension accuracy of a casting product. Also, as described above, the first positioning groove 45a and the second positioning groove 45b in the rotor housing surface forming portion 44 of the lower mold 40 are formed perpendicularly to each other, and thus the first beam 34 and the second beam 35 of the core 30 to be fitted in the first positioning groove 45a and the second positioning groove 45b are also formed perpendicularly to each other. This allows the core 30 to be formed bilaterally symmetrically and increases accuracy in molding the core 30. The first positioning groove 45a and the second positioning groove 45b (the first beam 34 and the second beam 35 of the core 30) formed in the rotor housing surface forming portion 44 of the lower mold 40 are not necessarily perpendicular to each other, but may intersect each other in order to increase placement position accuracy of the core 30 as compared to the conventional example.
Further, in the core 30 of this embodiment, the stopper portions 35b are provided at the opposite ends of the fitted portion 35a of the second beam 35 that constitutes the cross beam 39. Thus, when the fitted portion 35a of the second beam 35 is fitted in the second positioning groove 45b, the stepped surface 36 of the stopper portion 35b can abut against the side surface perpendicular to the second positioning groove 45b in the rotor housing surface forming portion 44 provided in the lower mold 40. This can further increase positioning accuracy of the core 30. Also, displacement of the core 30 from a normal position due to a flow of the molten metal poured into the cavity 60 in the pouring process can be favorably prevented. The side surface of the rotor housing surface forming portion 44 against which the stepped surface 36 of the stopper portion 35b abuts when the core 30 is assembled to the lower mold 40 is not necessarily perpendicular to the second positioning groove 45b of the rotor housing surface forming portion 44, but may intersect the second positioning groove 45b in order to expect an effect of increasing positioning accuracy of the core 30.
From the above, according to the casting device 10 of this embodiment, a technique can be provided capable of favorably preventing generation of a shrinkage cavity in solidification of molten metal poured into the casting device 10, and increasing accuracy of an assembling position of the core 30 to the mold 20 (the lower mold 40 in this embodiment), in casting the caliper 1. Also, as illustrated in
The embodiment described above is an example for illustrating the present invention, and various changes may be made without departing from the gist of the present invention. For example, in this embodiment, the casting device for casting an aluminum caliper has been described as an example, but not limited to this. The present invention may be applied to general caliper casting devices of a gravity casting type. Also, in this embodiment, the six-pot opposed-piston caliper has been described as an example, but the number of pistons is not particularly limited.
For example,
The core 30A includes a cylinder forming portion 31′ for forming a cylinder 5 after casting, a core print portion 32A coupled to the cylinder forming portion 31′, an oil passage forming portion 33, or the like. The core 30A of this variant is different in including four cylinder forming portions 31′ from the core 30 described above including the six cylinder forming portions 31. The core print portion 32A is coupled to the cylinder forming portions 31′.
The four cylinder forming portions 31′ are denoted by reference numerals 31′a to 31′d. As illustrated in
The core print portion 32A includes a first coupling beam 321 that couples the cylinder forming portion 31′a and the cylinder forming portion 31′c facing the cylinder forming portion 31′a, and a second coupling beam 322 that couples the cylinder forming portion 31′b and the cylinder forming portion 31′d facing the cylinder forming portion 31′b. The first coupling beam 321 and the second coupling beam 322 are placed in parallel with each other. The core print portion 32A couples intermediate portions of the first coupling beam 321 and the second coupling beam 322, and has a third coupling beam 323 placed perpendicularly to the first coupling beam 321 and the second coupling beam 322.
The third coupling beam 323 includes a fitted portion 323a to be fitted in a positioning groove provided in the lower mold 40A described below, and a pair of stopper portions 323b provided at opposite ends of the fitted portion 323a. The stopper portion 323b is a member corresponding to the stopper portion 35b described above. The stopper portion 323b has a larger width than the fitted portion 323a, and a stepped surface 324 (see
A rotor housing surface forming portion 44′ that forms a part of the rotor housing surface 7 after casting protrudes from an inner surface of the lower mold 40A. An I-shaped positioning groove 45′ is provided in the rotor housing surface forming portion 44′. In this variant, a depth of the positioning groove 45′ is the same as a height of the rotor housing surface forming portion 44′, and the rotor housing surface forming portion 44′ is divided into two mold blocks 44′a, 44′b with the positioning groove 45′ therebetween. The rotor housing surface forming portion 44′ constituted by the mold blocks 44′a, 44′b is a mold for forming a rotor housing surface of an area corresponding to an area around a circumferential center of the caliper after casting.
Next, a relationship between the core print portion 32A and the positioning groove 45′ will be described. As described above, the fitted portion 323a of the core print portion 32A has the same width as the positioning groove 45′, and the fitted portion 323a is fitted in the positioning groove 45′. The fitted portion 323a has the same length as the positioning groove 45′ (in other words, the widths of the mold blocks 44′a, 44′b), and the core 30A to be assembled to the lower mold 40A is positioned with the stepped surface 324 formed in the boundary between the fitted portion 323a and the stopper portions 323b provided at the opposite ends of the fitted portion 323a abutting against side surfaces of the mold blocks 44′a, 44′b.
In this variant, the fitted portion 323a of the core print portion 32A of the core 30A is fitted in the positioning groove 45′ provided in the rotor housing surface forming portion 44′ in assembling the core 30A to the lower mold 40A, thereby allowing easy and accurate positioning of the core 30A. The caliper casting device, and the core and the mold used in the caliper casting device according to the present invention may be applied to a caliper for a disc brake with a one-way (first type) piston.
In the embodiments described above, the six-pot core 30 and the four-pot core 30A have been described as examples, but the application of the present invention is not limited to them.
The caliper casting mold according to Embodiment 1 was used to conduct a confirmation test of a state of generation of a shrinkage cavity. In this test, a state of generation of a shrinkage cavity was confirmed in the case where the gate 21 was made of S50C like the mold, the case where the gate 21 was made of SUS having thermal conductivity about one third of that of the mold, and the case where the gate 21 was made of ceramic having thermal conductivity of about one two-hundredth of that of the mold. As illustrated in
As illustrated in
| Number | Date | Country | Kind |
|---|---|---|---|
| 2013-196063 | Sep 2013 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2014/001479 | 3/14/2014 | WO | 00 |
